NZ791498A

NZ791498A - Compositions and methods for regulating homeostasis of chondrocytes, extracellular matrix, articular cartilage, and phenotype of arthritis

Info

Publication number: NZ791498A
Application number: NZ791498A
Authority: NZ
Inventors: Mei Hong; Teresa Horm; Qi Jia; Ping Jiao; Neal Alexandria O; Mesfin Yimam
Original assignee: Unigen Inc
Priority date: 2020-02-06
Filing date: 2021-02-07
Publication date: 2022-08-26

Abstract

Medicinal plant extracts and their bioactives from Alpinia, Magnolia, Kochia and Piper/Pepper are disclosed herein in combination or alone in regulating homeostasis of chondrocytes, extracellular matrix, articular cartilage, and phenotype of arthritis that lead to enhanced anabolic functions of chondrocytes, increased renewal/rebuilding/regeneration of extracellular matrix and articular cartilage, and improved phenotype of osteoarthritis and rheumatoid arthritis. drocytes, increased renewal/rebuilding/regeneration of extracellular matrix and articular cartilage, and improved phenotype of osteoarthritis and rheumatoid arthritis.

Description

COMPOSITIONS AND METHODS FOR REGULATING HOMEOSTASIS OF CHONDROCYTES, EXTRACELLULAR MATRIX, ARTICULAR CARTILAGE, AND YPE OF ARTHRITIS CROSS-REFERENCE TO RELATED APPLICATIONS This application is a onal application of New Zealand Application No. , filed on 29 July 2022, and is related to International Patent Application No. , filed on 7 July 2021 and claims priority United States Utility Application Serial No.: 17/169490 filed on February 7, 2021 and to United States Provisional Patent Application Serial No.: 92 filed on February 6, 2020 both of which are incorporated herein by reference in its entirety.

BACKGROUND Osteoarthritis (OA) is a actorial disease that affects the entire joint structure and is characterized by cartilage ction and loss, degeneration of soft tissues, localized bone hypertrophy including subchondral thickening and hyte ion, varying degrees of synovitis, and thickening of the joint capsule (Loeser, 2013).

Over the years, ss has been made to address the symptoms, especially pain pathways, but not key detrimental s driving the development and progression of OA (Wenham and Conaghan, 2013). The compilation of evidence from augmented sources suggests that osteoarthritis is no longer considered as a “wear and tear” degenerative disease anticipated to happen as a consequence of aging or no longer considered to be a “noninflammatory” form of arthritis. Using a modern imaging technology such as MRI, for example, synovial membrane inflammation has been shown to be correlated with high prevalence to the severity and progression of OA and was ed to be the y cause of pain (Pickering et al., 2005; Roemer et al., 2011). Immunological changes such as infiltration of B cells in the synovium and activation of T cells have also been reported to take part in not only the pathogenesis of rheumatoid arthritis (RA) but also the pathogenesis of OA (Qin et al., 2007; Sakkas and Platsoucas, 2007).

Substantial reports have shown the elusive nature to specifically single out an etiology for OA which indicates the intertwined existence of multiple factors involving mechanical Finlayson Reference No.: 838-1423 molecular events in the initiation and progression of the disease. It is cumbersome to pinpoint exactly when and where the e originated as patients often seek help after signiﬁcant structural damage that has already occurred; nevertheless, it believed that the strong correlation among synovitis, cartilage, and meniscus degradation has been described as part of a vicious circle uating OA (Roemer el al., 2013). gh cartilage destruction is the main event in deﬁning osteoarthritis, the degradation of type II collagen is the fundamental incident that is believed to be the irreversible progression of osteoarthritis disease in association with inﬂammation. Progressive degradation of articular age is the hallmark of OA. Articular cartilage is an avascular, non-innervated tissue ed of a dense extracellular matrix (ECM) with a sparse distribution of highly specialized cells called chondrocytes. Chondrocytes originate from mesenchymal stem cells and tute about 2% of the total volume of articular cartilage (Alford and Cole, 2005). Chondrocytes are metabolically active cells that play a pivotal role in the development, maintenance, and repair of the ECM which is mainly composed of type II collagen and aggrecan. Collagen is the most nt structural macromolecule in ECM where type II collagen represents 90% - 95% of the en in the tissue and forms ﬁbers intertwined with proteoglycan aggregates. Proteoglycans are heavily glycosylated protein monomers representing the second-largest group of olecules in the ECM and account for up to 10% - 15%. Proteoglycans consist of a protein core with one or more linear aminoglycan (GAG) chain ntly attached. These structures provide the visco-elasticity property and resistance to compression forces to the articular cartilage.

Homeostasis and ity of ellular matrix (ECM) is fundamental for proper function of lar cartilage to maintain a healthy joint. Several mechanical, biochemical, and micro-environmental factors can regulate the metabolic activity of chondrocytes within the ECM of lar cartilage. Accordingly, different anabolic signals perceived by the chondrocyte will lead to the production, organization, and maintenance of the integrity of cartilage ECM. Abnormal and catabolic signals due to increased production of matrix metalloproteinases (MlVlPs) and proteoglycanases by chondrocytes in the affected structures of the joint can shift the homeostasis of ECM to the catabolic side and lead to the degradation of the ECM. This is the main characteristic of both osteo- and rheumatoid tis. Pro-inﬂammatory cytokines, such as INF- 0t, lL-lB, and IL-6 are known to play important roles in cartilage matrix degradation in articular Finlayson Reference No.: 838-1423 cartilage through a cascade of catabolic events that lead to stimulation of aggrecanase and matrix metalloproteinase (MMP) secretion (Kapoor el al, 2011). Besides the disruption of cartilage matrix homeostasis and integrity, these collective lic mediators decrease the response and sensitivity of chondrocytes to the surrounding anabolic signals, further shifting the balance more towards catabolic cartilage degradation than anabolic rebuilding and l of ECM and cartilage. As a result, l compositions with the capacity of reversing the direction from catabolic to anabolic processes could act as disease-modifying agents and have ial effects, such as modifying, slowing down, or reversing the progression of arthritis.

Present-day management of 0A is inadequate due to the lack of primary therapies proven to be effective in hindering disease cause and progression. The current pharmaceutical approach, which focuses mainly on curtailing the symptoms of disease, , associated pain, will only mask the actual etiology but not balance the catabolic-anabolic homeostasis, leading to irreversible damage to the cartilage integrity and joint structure. While intra-articular injection of corticosteroids, hyaluronic acid, and oral or topical nonsteroidal anti-inﬂammatory drugs (NTHEs) have most frequently been used to relieve pain and stiffness in OA patients, glucosamine and oitin have also shown d, but measurable, outcome on pain and improved function in more severe stages of 0A. In fact, previously, glucosamine sulfate and chondroitin sulfate were recommended by the rthritis Research Society International ) as possible ural modifying agents in hip and knee OA (Jordan el al., 2003, Zhang el al., 2007). However, the recently hed OARSI ines downgraded these agents to “uncertain” as a symptom reliever or “not appropriate” as a disease-modifying agent when used for all OA patients.

Similarly, oral, and transdermal opioid llers were graded as “uncertain” for managing OA (Zhang er al., 2008, 2010). On the other hand, topical NTHEs are recommended as appropriate for all patients with knee-only OA and were found to be safer and better tolerated compared to oral NTHEs (McAlindon el al., 2014). These periodic s in recommendations ofuse by the expert panel clearly deﬁne the uncertainty of current nonpharmacological and pharmacological modalities oftherapy for CA management. Intensifying the complicated situation, many distressed patients compromise their safety by inclining more s substandard and unregulated t s, hoping to lessen the catastrophic outcome of the disease and to improve their quality of life. As a result, there still is an unmet need for evidence-based safe and efﬁcacious alternatives from natural sources.

Finlayson Reference No.: 838-1423 Rheumatoid arthritis (RA) is a chronic, inﬂammatory, autoimmune e that primarily affects the joints (Smolen el al, 2018). Although RA is a systemic disease and a variety of immunological events occur outside the joint at mucosal surfaces and primary lymphoid tissues, the synovium is a central player. The disease is characterized by inﬁltration of the synovial ne of joints with cellular and humoral immunity cells such as T cells, B cells, and monocytes. This s is preceded by neovascularization ation of endothelial cells leading to growth of new blood vessels) which is considered as a hallmark ofRA synovitis. ion of synovial ﬁbroblast-like and macrophage-like cells in the synovial membrane leads to a hyperplastic synovial lining layer. This expanded al membrane, often termed “pannus,” invades the periarticular bone at the cartilage-bone junction and leads to bony erosions and cartilage degradation.

In the pathogenesis of RA, cytokine networks integrate pro-inﬂammatory and tissue- damaging cellular activities in tis. Proinﬂammatory cytokines, primarily TNF-d, and IL-6, are known to induce molecules such as receptor activator of nuclear factor KB ligand (RANKL), prostaglandins (PGE2), matrix metalloproteinases (MMP-l3, MMP-3, MMP-9, MMP-1) and aggrecanases in RA. These factors mediate the signs and ms of RA. TNF-d, and 1L-6 also stimulate generation of osteoclasts within the synovial membrane and promote bone damage.

These molecular and cellular events result in the clinical disease expression manifested as pain, swelling (typically accompanied by g stiffness and tenderness), ity, and degradation of cartilage and bone. Damage to cartilage and bone due to synovial invasion into adjacent articular structures is one of the cardinal signs of RA (Smolen er al., 2018).

Like 0A, the goals of ent for RA are to reduce joint ation and pain, maximize joint function, and prevent joint destruction and deformity. Through the years, better understanding of the pathogenesis of RA (through recognition of key cells and cytokines) has led to dramatic improvements and the development of targeted disease-modifying antirheumatic drugs. In particular, rheumatologists have learned how to use the immunosuppressant rexate optimally, and this drug has become the therapeutic anchor for managing RA r and van der Heij de, 2009). Well aligned with this understanding, besides histological ﬁndings in improvements ofjoint structure maintenance and protection of the subchondral bone, itions disclosed in this disclosure produced comparable outcomes to methotrexate in symptomatic relief, and Finlayson Reference No.: 838-1423 reduction of key inﬂammatory nes (TNF-d and IL6) and matrix degrading enzymes (WP- 13 and MMP-3) when tested in collagen-induced arthritis (CIA). This model is most frequently used as a disease model for testing efﬁcacy of pharmaceutical and euticals in RA and/or the pathogenesis of RA (Cho el al., 2007). These ﬁndings suggest the natural compositions disclosed in the t application are suitable for the management ofRA in addition to OA.

Herein, we document multiple natural extracts and their combined compositions that statistically and signiﬁcantly reduced catabolic biomarkers for cartilage turnover - such as uCTX- 11 (primary marker for cartilage degradation) by down ting catabolic cytokines (such as TNF-OL, IL-lB, and IL-6) and extracellular matrix degrading enzymes (MTVIP3, 9, and 13) in animals treated with those itions. These ﬁndings were also substantiated by ting homeostasis of chondrocytes where the gene expression of catabolic pathways was signiﬁcantly down regulated for matrix degrading enzymes (metalloproteinase and aggrecanase) such as MlVlPl3, MMP3 and ADAMTS4 after oral treatment. These phenomena are key tors of the current invented composition’s activities in minimizing the catabolic processes of the phenotype of arthritis.

To date, there is no tory-approved disease-modifying drug for CA that could be applicable for regeneration of cartilage. In perspective, dietary supplements with le known mechanisms of actions could assist in the cartilage repairing process. In the current sure, the proprietary compositions consisting of, but not limited to, individual a, Pepper, Magnolia and Kochia extracts, and/or at various combinations of 2 to 3 of those extracts with examples of, but not limited to AlpiniazPepper (AP) and AlpiniazMagnoliazKochia (AMK), resulted in cted faster and improved cartilage repairing activity with synergy as reﬂected in the animal weight bearing data and histopathological observation of the age repairing parameters in diseased animal models. The levels of cartilage synthesis markers, such as type IIA procollagen amino terminal propeptide (PIIANP) and the growth factor TGF-Bl, were found signiﬁcantly higher in rats treated with individual extracts of Alpinia, Pepper, Magnolia and Kochia and also by those itions of AMK and AP when compared to vehicle-treated disease models. These compositions have also shown signiﬁcant cartilage protection activity in the collagen-induced rat arthritis model and anti-pain and anti-inﬂammatory activity in the eenan-induced rat paw edema model. The merits of combining these extracts to yield, but not limited to, AP or AMK Finlayson Reference No.: 838-1423 composition were also evaluated using the Colby's equation (Colby, 1967) and unexpected synergy was found for combined compositions. These wide array of activities demonstrated by individual Alpinia, Pepper, Magnolia and Kochia extracts and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to, AP and AMK, could be attributed to the diverse nature of actives present in the compositions. The compiled data dictate that individual Alpinia, Pepper, Magnolia and Kochia extracts and/or at various combinations of 2 to 3 of those extracts with es, but not limited to, AP and AMK compositions provide symptom relief, anti-catabolic joint cartilage protection and ic joint cartilage repair - triple function, which could be a holistic approach as a disease-modifying agent for osteoarthritis.

In the present sure, data depicted in this patent details the novelty of the individual Alpinia, Pepper, Magnolia and Kochia extracts and/or at various combinations of 2 to 3 of those extracts with es, but not limited to AlpiniazPepper (AP) and AlpiniazMagnoliazKochia (AMK) compositions to address the unmet need for regulating homeostasis of chondrocytes, the extracellular , articular cartilage, and the phenotype of arthritis. Administered at the exampled combination ratios, individual Alpinia, Pepper, Magnolia and Kochia extracts, and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to, AP and AMK, reversed the course of OA towards normal or anabolic homeostasis balance by inducing cartilage sis and by inhibiting ECM degradation. We believe that natural itions like individual Alpinia, Pepper, Magnolia and Kochia extracts and/or at various combinations of 2 to 3 of those ts with examples, but not limited to AP and AMK, compositions possess unique capacities in stimulating anabolic gene expression and inhibiting catabolic activities which establish those compositions as red choices for OA/RA disease-modifying agents from natural sources.

Enteral and parenteral routs of drug administration are among the commonly used methods of drug delivery for patients suffering from musculoskeletal pain. However, the commonly prescribed or over the r ain medications such as selective and non-selective non- steroidal anti-inﬂammatory drugs are known to cause gastrointestinal, vascular, and renal side s (Harirforoosh el al., 2013). Older patients who actually often ence chronic pain are at greater risk of side effects from these routes of intervention (Stanos and Galluzzi). These e events could be averted by employing NTHEs by a topical application route. ng anti-pain products directly to the affected area, such as in cases of muscular strain, sprains, Finlayson Reference No.: 838-1423 osteoarthritis, rheumatoid arthritis and other spectrums of musculoskeletal conditions, could result in a high concentration of active compounds at the intended target areas, yielding fast and robust pain relief while minimizing systemic exposure (Rodriguez-Merchan, 2018, Argoff, 2013).

Nevertheless, there still is an unmet need for topically applicable medications or alternatives with improved efﬁcacy for musculoskeletal disorders. We believe that l products with diverse chemical es and mechanisms of action could help to bridge the gap for topical alternatives.

In the work on contemplated ments, we screened and evaluated our plant library for topical analgesics and hypothesized their potentially enhanced pain relief ty as a result of standardized formulations and improved skin penetration. Part of the discovery processes of novel, topically effective ain formulations have been documented in the conceptualization of contemplated embodiments sed .

Depending on the initial stimuli, pain could be nociceptive, atory, or neuropathic.

It has been hypothesized that these medicinal plants could cause suppression in pain sensitivity by directly interfering with the peripheral primary afferent sensory neurons at the receptor level or ctly by acting through the many pathways of pain transduction, transmission, modulation, and perception. Bradykinin and prostaglandins are among the classic inﬂammation mediators known to cause pain sensitivity in inﬂammation.

Finlayson Reference No.: 838-1423 SUMMARY OF THE SUBJECT MATTER Medicinal plant extracts and their bioactives from Alpinia, Magnolia, Kochia and Piper/Pepper are sed herein in combination or alone in regulating homeostasis of chondrocytes, extracellular matrix, articular cartilage, and phenotype of arthritis that lead to enhanced ic functions of chondrocytes, sed renewal/rebuilding/regeneration of extracellular matrix and lar cartilage, and improved phenotype of osteoarthritis and rheumatoid arthritis. The shifting of balance at a cellular and tissue level not only preserved/protected/improved/renewed structural integrity of extracellular matrix and articular cartilage, but also protected/improved/enhanced joint/bone structure and joint function, observed as reduced joint inﬂammation, joint pain, joint stiffness, decreased cartilage degradation, improved mobility, range of motion, ﬂexibility, joint physical function, or any ation thereof.

The anti-catabolic and pro-anabolic activities of individual extracts of Alpinia, Pepper, Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with es, but not limited to Alpim'a.'Plper/Pepper (AP) and Alpim'asMagnoliarKochia (AMK) were demonstrated at molecular and cellular levels, including gene expression, protein expression, and protein function ion, at tissue levels with biomarker-guided tissue protection, at diseased animal models, with not only symptom relief, but by anabolic and catabolic biomarker changes and improvements of athological images and scores.

The methods of use of the disclosed individual extracts of Alpinia, Pepper, ia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to Alpim'a.'Plper/Pepper (AP) and Alpim'asMagnoliarKochia (AMK) include, but are not limited to, maintaining cartilage homeostasis, extracellular matrix integrity, and joint cartilage, minimizing cartilage ation, protecting joint space from narrowing, and promoting healthy joints by protecting cartilage integrity, balancing ic and catabolic processes, diminishing the actions of s and ammatory cytokines that affect joint health, ing joint movement and/or function, alleviating joint pain, alleviating joint stiffness, improving joint range of motion and/or ﬂexibility, promoting mobility, managing and/or treating osteoarthritis and/or rheumatoid arthritis, ting osteoarthritis and/or rheumatoid arthritis, or ing the progression of osteoarthritis and/or rheumatoid arthritis or the like.

Finlayson nce No.: 838-1423 Speciﬁcally, a composition for joint health is disclosed that comprises a ation of an Alpim'a extract enriched for one or more phenylpropanoids, a Magnolia extract enriched for one or more bisphenolic lignans, and a Kochia extract enriched for one or more penoid saponins.

In additional embodiments, a composition for joint health is disclosed that comprises a combination of an Alpinia extract enriched for one or more phenylpropanoids, and a Piper extract enriched for one or more alkaloids.

In yet additional embodiments, a composition for joint health is disclosed that comprises an Alpinia extract enriched for one or more phenylpropanoids.

Finlayson Reference No.: 838-1423 BRIEF DESCRIPTION OF THE S Figure 1 shows individual extracts of Alpinia, Piper/Pepper, Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to AlpiniazPiper/Pepper (AP) and AlpiniazMagnoliazKochia (AMK), reverses OA progression by inducing cartilage homeostasis.

Figure 2 shows a HPLC chromatogram nia ethanol extract at 254 nm.

Figure 3 shows images of a drill site of OCD rats after 6 weeks of treatment g signiﬁcant differences in healing progress from ent oral treatment groups.

Figure 4 shows Safranin O stain of the subchondral bone of OCD rats at the drill site. The black circle indicates the drill site for representative animal histopathology .

Figure 5 shows histopathology images (HE a-d and Safranin O e-f) from ankle joint ofCIA induced rats treated with AMK and MTX. A and e - normal control, b and f - CIA+ vehicle, c and g — CIA+MTX, d and h — CIA+ AMK.

Figure 6 shows HE and Safranin O staining histology for CIA rats d with AP (HE stains (40x): a= normal control + Vehicle, b=CIA + Vehicle, c=CIA + Methotrexate, d= CIA + AP, Safranin O stain (40x): e= normal control + vehicle, f=CIA + Vehicle, g=CIA + Methotrexate, h= CIA + AP, C = cartilage, SB = subchondral bone, 1 = inﬂammation) Finlayson Reference No.: 838-1423 DETAILED DESCRIPTION Osteoarthritis (0A) is a multifactorial disease ily noted by cartilage degradation that causes signiﬁcant morbidity, joint pain, ess, and limited ty. Present-day management of 0A is inadequate due to the lack of principal therapies proven to be effective in hindering disease progression wherein a symptomatic therapy-focused approach, such as the use of nonsteroidal anti-inﬂammatory drugs, masks the actual etiology leading to irreversible cartilage depletion and joint structural damage. Here we present the discovery of novel natural extracts and compositions designated as examples of, but not limited to, Alpinia, Piper/Pepper, Magnolia and Kochia extracts and at various ations which resulted in unexpected faster and improved cartilage renewal and repairing ty with synergy. These activities derived from dual Alpinia, Piper/Pepper, Magnolia and Kochia extracts and/or at s combinations of 2 to 3 of those extracts with es, but not limited to AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK) are demonstrated in the examples 2, 9, l3, l7, and 18 in the current subject matter and reﬂected by inhibition of the release of glycosaminoglycan (GAG) from rabbit cartilage explants stimulated by a catabolic cytokine, interleukin-1, in the animal weight bearing data from the osteochondral model (OCD) (examples 25 to 3 l) and in the athological observation of cartilage tion, repairing and renewal parameters in collagen-induced arthritis (CIA) (examples 40 to 58), monoiodoacetate-induced arthritis (MIA) (examples 59 to 63) and OCD (examples 25 to 31) diseased animal models for regulating homeostasis of chondrocytes, extracellular matrix, articular cartilage, and phenotype of arthritis.

Specifically, a ition for joint health is disclosed that comprises a combination of an Alpinia extract ed for one or more phenylpropanoids, a Magnolia extract enriched for one or more bisphenolic s, and a Kochia extract enriched for one or more triterpenoid saponins.

Contemplated compositions are developed such that the Alpinia extract, or Magnolia extract or Kochia extract in the composition are in a range of 1% - 98% by weight of each extract with the optimized weight ratio of Alpinia:Magnolia:Kochia (AMK) at 2:4:3 (22.2%:44.4%:33.3%) or 4:3:3 0%:30%) or 5:4:4 (38.4%:30.8%:30.8%).

In additional embodiments, a composition for joint health is disclosed that ses a combination of an Alpinia extract enriched for one or more phenylpropanoids, and a Piper t enriched for one or more alkaloids.

Finlayson Reference No.: 23 In yet additional embodiments, a composition for joint health is disclosed that comprises an Alpinia extract enriched for one or more propanoids.

While chondrocytes respond to a variety of stimuli, including growth factors, they have limited potential for replication, a factor that contributes to the limited intrinsic healing capacity of age in response to injury. Chondrocytes regulate cartilage homeostasis by ining a te balance between ic (regenerative) and catabolic (degradative) activities. These cells represent only 1-2% of the total matrix volume. They are lar and unable to divide in adulthood, causing a very limited ability for cartilage self-repair and low turnover rate. They y acquire their nutrition and oxygen primarily through diffusion from the synovial ﬂuid and subchondral bone. Chondrocytes maintain the homeostasis of articular cartilage matrix by modulating the balance between the synthesis and degradation of various articular ents.

This process is controlled by the relative levels of cytokines and growth factors in the nding tissues, such as cartilage and/or synovial ﬂuid and/or synovial membrane. Chondrocytes can maintain the integrity of ellular matrix (ECM) by synthesis of macromolecules such as type II collagen and aggrecans and they can also produce proteins involved in the degradation ofECM such as MMPs and anases. As chondrocytes are very responsive and ive to changes to their micro-environment, natural extracts and compositions that stimulate the chondrocytes directly or indirectly to produce -forming components and inhibit the secretion of proinﬂammatory cytokines and matrix degrading s could change the homeostasis of the ECM and the ype of arthritis. In the current subject matter, we have documented data in the examples ntiating the cartilage rebuilding and renewal capacity of individual Alpinia, Pepper, Magnolia and Kochia extracts and/or at various combinations of 2 to 3 of those extracts with examples of, but not limited to, compositions AlpiniazPiper/Pepper (AP) and AlpiniazMagnoliazKochia (AMK) in OCD model in addition to their cartilage protection and symptom relief ties in the CIA, MIA and carrageenan models outweighing the degradation process to maintain homeostasis.

During chondrogenesis, mesenchymal stem cell (MSC) condensation and subsequent chondrocyte differentiation are the initial steps in cartilage formation. These processes are driven by several growth and transcription factors at different stages of cartilage development. Among these factors, SOX9, a key transcription factor for chondrogenesis, is involved in the condensation phase of MSCs, stimulating the expression of cartilage-speciﬁc markers and inhibiting terminal Finlayson Reference No.: 838-1423 differentiation of chondrocytes. Similarly, the TGF-B family of genes is widely expressed in chondrocytes and is a constituent class of growth factors involved in the process of ogenesis. Of all the s expressed during the early stages of chondrogenesis, TGF-Bl is one of the most important factors that induces the differentiation ofMSCs into chondrocytes. This factor also stimulates the proliferation of ocytes, increases the production of ECM, and it inhibits endochondral ossiﬁcation. In this ic phase of age development (stimulated by SOX9 and TGF-Bl), mature chondrocytes will produce cartilage matrix rich in proteoglycan and type II collagen fibers encoded by ACAN and COL2Al genes, respectively. As a result, external factors that upregulate the expression of the transcription or growth factors help induce the anabolic process of cartilage development to in the surplus ofECM. In fact, in our discovery process of natural compositions derived from dual Alpinia, Pepper, Magnolia and Kochia extracts and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to azPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK) found upregulation of SOX 9, TGF-Bl, ACAN and COL2Al genes in ex vivo, and in vitro models in stimulated human chondrocytes demonstrated in current subject matter examples 21, 22, 23 and 24. These ﬁndings of regulating homeostasis of chondrocytes, extracellular , articular cartilage, and phenotype of arthritis were later reinforced by in vivo results from CIA, MIA and OCD models demonstrated in the current t matter. The levels of cartilage collagen synthesis markers, such as type IIA lagen amino terminal propeptide (PIIANP) (Examples 40, 48, 56 and 58) and the growth factor TGF-Bl (example 31), were found signiﬁcantly higher in rats treated with individual extracts of Alpinia, Pepper, Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to azPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK) when compared to e-treated disease animals. These phenomena such as upregulation of anabolic gene markers which are directly involved in cartilage synthesis and renewal address, in part, the activities of the disclosed compositions.

To the best of our knowledge, this is the ﬁrst time that the disclosed medicinal plants have been evaluated in the given ratio for their ability to retain and d cartilage in the osteochondral defect (OCD) model, resulting in ble outcomes. This model has a direct implication in assessing interventions for their cartilage renewal and rebuilding function. Cartilage synthesis and hence disease-modifying activity of individual extracts of Alpinia, Pepper, Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to, Finlayson nce No.: 838-1423 AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK), were demonstrated using the osteochondral defect (OCD) model in rats as illustrated in the examples 25, 26, 27, 28, 29, 30 and 31. The model utilizes stimulation of the bone marrow in the ing process by taking advantage of the body’s own healing potential. This technique enhances the chondral resurfacing by providing a suitable nment for new tissue ion. At the time of model induction, the exposed weight-bearing surface of the femur subchondral bone plate was drilled with a precision drill bit until fat droplets and blood came out of the microfractured hole in the knee. This provided an optimal environment for the body’s own mesenchymal stem cells from the bone marrow to differentiate into appropriate articular cartilage-like cells that in turn produced the extracellular matrix which eventually matured into stable repaired tissue. The cartilage repair activity of individual extracts of Alpinia, , Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK) were evaluated using this model administered orally at different dosages and time periods, such as 200 day for 8 weeks. As a means of assessing the repair progress, the distribution of weight-bearing n the right and left legs of rats were measured using the incapacitance tester. At necropsy, serum for biomarkers and the left knees for histopathology were collected. Images of the left knee focused on the drilling site were taken for all the s before ﬁxing them with formalin. Fixed tissues were sed and analyzed by an independent and certiﬁed pathologist.

OCD s exhibited limping on the ed legs which showed progressive improvement through the course of the study for all the groups. These changes in the open ﬁeld observation of the use of their affected legs were also reﬂected in the incapacitance ements.

There was gradual improvement in the weight-bearing measurements that was signiﬁcantly improved for rats treated with AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK) compositions. After 6 weeks of daily oral treatment, rats treated with AMK and AP compositions showed 59.9% and 51.5% improvement, respectively, in the use of their affected legs to carry their body weight. This was an tion of reduced pain in the surgically drilled knee. These values seemed to match what was observed in the pictures taken at necropsy from the AMK and AP groups relative to the vehicle-treated OCD animals. These ﬁndings were also substantiated by the histopathology data, which were analyzed using the Sellers method of analysis described in the body of the patent for cartilage repair, which showed 40.4% and 40.5% accelerated healing in Finlayson Reference No.: 838-1423 animals treated with AMK and AP compared to the vehicle-treated disease model. These improvements were statistically signiﬁcant for AMK- and AP-treated OCD rats compared to the vehicle treated group. These ﬁndings reﬂect the age synthesis (anabolic) and stimulation activity of AMK and AP in vivo complementing the upregulated in vitro anabolic gene s justifying their cartilage rebuilding and renewal activities.

The cartilage protection activities of individual extracts of Alpinia, Pepper, Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to Alpinia:Piper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK), were also demonstrated in onal animal models. In the CIA and MIA induced tis models demonstrated in examples 40, 48 56 and 58, individual extracts of Alpinia, Pepper, Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to, AP and AMK produced statistically signiﬁcant ions in urinary , a primary biomarker for cartilage degradation and statistically signiﬁcant increases in a cartilage synthesis biomarker, PIIANP. Those individual ts of Alpinia, Pepper, Magnolia and Kochia and/or at various ations of 2 to 3 of those extracts with examples, but not limited to, AP and AMK also showed a statistically signiﬁcant decrease in serum catabolic biomarkers such as IL-lB, TNF-d, and IL-6 levels as well as different MlVlP enzymes which are considered as the primary catabolic pathways associated with inﬂammatory cytokines and matrix degrading enzymes. Data from these models suggest the anti- catabolic activity of these individual extracts and combined compositions.

Substantiating the in vivo observations, individual ts of Alpinia, Pepper, Magnolia and Kochia and/or at various combinations of2 to 3 e extracts with examples, but not limited to Alpinia:Piper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK), upregulated expression of articular age extracellular matrix anabolic biomarkers such as COL2Al (the gene encoding typedl collagen) and ACAN (the gene encoding the cartilage-speciﬁc proteoglycan core protein) and downregulated expression of matrix lic homeostasis biomarkers such as MMPl3, MlVIP3 and ADAMTS4 when human chondrocytes were incubated with a catabolic cytokine, 1L- 1. Articular cartilage matrix synthesis transcription factor, SOX9, and growth factor TGF-Bl le 23 and 24) were also found up regulated in timulated human chondrocytes treated with those dual extracts of Alpinia, Pepper, Magnolia and Kochia and also those examples, but not limited to, AP and AMK compositions. These s show that dual extracts of Alpinia, Pepper, Magnolia, and Kochia and also compositions of these plant extracts, not limited Finlayson Reference No.: 23 to AMK and AP, promote cartilage regeneration by increasing the levels of master regulators of cartilage synthesis, TGF-Bl and SOX9, leading to the se of cartilage components, ACAN, , and PIIANP. Conversely, the ts decreased the expression and ty of MlVlPl3, MlVlP3, ADAMTS4, and MMP9, enzymes that are responsible for the majority of direct cartilage breakdown. The net result of these activities is maintenance of remaining cartilage and initiation of cartilage synthesis to restore integrity to the architecture of the joint.

Although the initial etiology of OA/RA is under debate, homeostasis disturbances as a result of cartilage synthesis and degradation imbalance play a key role in the initiation and progression of osteoarthritis and also rheumatoid arthritis. Data ted in this disclosure showed the effect of these dual extracts of Alpinia, Pepper, Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to, AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK), in reversing the direction of arthritis progression towards normal and/or ic homeostasis by inducing cartilage synthesis (and hence, anabolic effect) and inhibiting the catabolic process of degradation and breakdown. Figure 1 shows individual extracts of Alpinia, Piper/Pepper, Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not d to AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK), reverses OA progression by inducing cartilage homeostasis.

We believe that the multifactorial complexity of pain may suggest the need for an intervention strategy that involves the ation of two or more active extracts together to elicit multiple approaches: enhanced pain relief, alleviation of cartilage breakdown, and initiation of cartilage synthesis. The in vivo studies we conducted using Alpinia, , Magnolia, and Kochia, as well as compositions not limited to AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK), demonstrated enhanced pain relief, as well as histological alleviation of cartilage breakdown. The in vitro and ex vivo studies we demonstrated in the current subject matter using the plant extracts individually and in combination showed a ion in cartilage degradation, as well as increased cartilage synthesis for several individual extracts as well as the combinations.

Notably, the individual extracts did not all display each of these ties, but compositions of the extracts augmented their individual ties, achieving unexpected efﬁcacy with synergy in these intervention ties.

In a topical treatment paradigm, there is a greater advantage in the use of penetration enhancers to increase the degree of absorption and to facilitate transdermal permeation overcoming Finlayson Reference No.: 838-1423 the stratum comeum barrier. With respect to this, we considered the use of aloe in our formulations and added aloe at 2% during the preparation for some of the extracts as indicated in the examples (Fox el al., 2015).

Known topically active NTHE drugs had been formulated at 5% Ibuprofen or 1% Diclofenac, as NTHE controls in the current evaluation. Two over the counter (OTC) actives were also obtained to make 0.5% Capsaicin or 5% Menthol as OTC positive l. Commercial OTC pain relief products, such as BENGAY®, have also been utilized as controls.

An in vivo hot plate test was ed as the testing model to evaluate the topical pain relief function of the selected natural leads against known positive NTHEs and OTC controls. A small amount of DMSO was utilized to dissolve botanical extracts or compounds at 5% concentration.

DMSO sample solutions were mixed with equal volumes of Aloe vera gel (2-4% Aloe leaf gel powder in DI water), which was applied topically to rat paws before the hot plate experiment le 64).

Pain is a multifactorial phenomenon triggered by le mechanisms. Application of these test materials could be involved in, but not d to, the initial activation and subsequent desensitization of peripheral nerve ﬁbers, competitive inhibition or activation of transient receptor potentials such as TRPVl and/or TRPAl, modulations of cannabinoid receptors (CBl and CB2 receptors), nization and /or blocking of TRPVl and TRPAl, an initial increase in release of substance-P ed by a depletion, inhibition of bradykinin activity, and inhibition of peripheral sis of inﬂammatory mediators, such as prostaglandin, bradykinin and cytokines. Hence, given the diverse nature of bioactives present in the tested medicinal plant materials, the current topical ain data depicted in this subject matter, in association with the carrageenan, the MIA, the CIA and OCD model data, could expand the use ofindividual extracts of Alpinia, Pepper, Magnolia, and Kochia and also compositions of these plant extracts, not d to AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK), by combining these plant materials in a speciﬁc ratio for enhanced pain relief activity.

In the above and following descriptions, certain speciﬁc s are set forth in order to provide a thorough understanding ofvarious embodiments ofthis disclosure. However, one skilled in the art will understand that the sure may be practiced without these details.

Finlayson Reference No.: 838-1423 In the present description, any concentration range, percentage range, ratio range, or integer range is to be understood to include the value of any integer within the recited range and, when appropriate, fractions thereof (such as one tenth and one hundredth of an integer), unless otherwise indicated. Also, any number range recited herein relating to any physical feature, such as polymer subunits, size, or thickness, are to be understood to e any integer within the recited range, unless ise indicated. As used herein, the terms "about" and "consisting essentially of" mean :: 20% of the ted range, value, or structure, unless otherwise indicated. It should be understood that the terms "a" and "an" as used herein refer to "one or more" of the enumerated components. The use of the alternative (e. g., "and/or") should be understood to mean either one, both, or any combination thereof of the alternatives. Unless the context requires otherwise, throughout the present speciﬁcation and claims, the word “comprise” and variations thereof, such as, “comprises” and “comprising,” as well as synonymous terms like “include” and “have” and variants f, are to be construed in an open, ive sense, that is, as “including, but not limited to.” Reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or teristic described in connection with the ment is included in at least one ment of the present disclosure. Thus, the appearances of the phrases “in one ment” or “in an embodiment” in various places throughout this cation are not necessarily all referring to the same ment.

The term “prodrug” is also meant to include any covalently bonded carriers, which release the active compound of this sure in vivo when such prodrug is administered to a mammalian subject. Prodrugs of a compound of this disclosure may be prepared by ing onal groups present in the compound of this disclosure in such a way that the modiﬁcations are cleaved, either in routine manipulation or in vivo, to the parent nd of this disclosure. Prodrugs include compounds of this disclosure wherein a hydroxy, amino or mercapto group is bonded to any group that, when the prodrug of the compound of this disclosure is administered to a mammalian subject, cleaves to form a free hydroxy, free amino or free mercapto group, respectively. Examples of prodrugs include acetate, formate and benzoate derivatives of alcohol or amide derivatives of amine functional groups in the compounds of this disclosure and the like.

Finlayson Reference No.: 838-1423 The term “joint” health are meant to indicate improving the health of one or multiple “joints” of hand, elbow joints, wrist joints, axillary articulations, sternoclavicular joints, vertebral articulations, temporomandibular joints, sacroiliac joints, hip joints, knee joints and articulation of foot.

“Stable compound” and “stable ure” are meant to indicate a compound that is iently robust to survive isolation to a useful degree of purity from a reaction mixture, and formulation into an eff1cacious therapeutic agent.

“Biomarker(s)” or “marker(s)” component(s) or compound(s) are meant to indicate one or multiple indigenous chemical component(s) or compound(s) in the disclosed plant(s), plant extract(s), or combined composition(s) with 2-3 plant extracts that are utilized for lling the y, tence, integrity, ity, and/or biological functions ofthe invented composition(s).

“Mammal” includes humans and both domestic animals, such as companion animals, laboratory animals or household pets (e.g., cats, dogs, swine, cattle, sheep, goats, horses, rabbits), and non-domestic animals, such as wildlife or the like. nal” or “optionally” means that the subsequently described element, component, event or circumstances may or may not occur, and that the description includes ces where the element, component, event or circumstance occur and instances in which they do not. For e, nally substituted aryl” means that the aryl l may or may not be substituted and that the description includes both substituted aryl ls and aryl radicals having no substitution.

“Pharmaceutically or eutically acceptable carrier, diluent or excipient” includes any adjuvant, carrier, excipient, glidant, sweetening agent, diluent, preservative, dye/colorant, ﬂavor er, surfactant, wetting agent, dispersing agent, suspending agent, stabilizer, isotonic agent, solvent, or emulsif1er which has been approved by the United States Food and Drug Administration as being acceptable for use in humans or domestic animals.

“Pharmaceutically or nutraceutically acceptable salt” includes both acid and base addition salts. “Pharmaceutically or nutraceutically acceptable acid addition salt” refers to those salts which retain the biological effectiveness and properties of the free bases, which are not biologically or otherwise undesirable, and which are formed with inorganic acids such as hydrochloric acid, hydrobromic acid, sulfuric acid, nitric acid, phosphoric acid and the like, and organic acids such as acetic acid, 2,2-dichloroacetic acid, adipic acid, alginic acid, ascorbic acid, aspartic acid, Finlayson Reference No.: 838-1423 benzenesulfonic acid, benzoic acid, 4-acetamidobenzoic acid, ric acid, camphor-lO- sulfonic acid, capric acid, caproic acid, caprylic acid, carbonic acid, cinnamic acid, citric acid, cyclamic acid, dodecylsulfuric acid, ethane-1,2-disulfonic acid, ethanesulfonic acid, 2- hydroxyethanesulfonic acid, formic acid, fumaric acid, galactaric acid, gentisic acid, glucoheptonic acid, gluconic acid, onic acid, glutamic acid, glutaric acid, 2-oxo-glutaric acid, ophosphoric acid, glycolic acid, hippuric acid, isobutyric acid, lactic acid, lactobionic acid, lauric acid, maleic acid, malic acid, malonic acid, mandelic acid, methanesulfonic acid, mucic acid, naphthalene-l,5-disulfonic acid, naphthalenesulfonic acid, l-hydroxynaphthoic acid, nicotinic acid, oleic acid, orotic acid, oxalic acid, palmitic acid, pamoic acid, propionic acid, pyroglutamic acid, pyruvic acid, salicylic acid, 4-aminosalicylic acid, sebacic acid, stearic acid, succinic acid, tartaric acid, anic acid, p-toluenesulfonic acid, triﬂuoroacetic acid, undecylenic acid, and the like.

“Pharmaceutically or nutraceutically acceptable base addition salt” refers to those salts which retain the biological effectiveness and properties of the free acids, which are not biologically or otherwise undesirable. These salts are prepared from on of an inorganic base or an organic base to the free acid. Salts derived from inorganic bases include the , potassium, lithium, ammonium, m, ium, iron, zinc, copper, manganese, aluminum salts and the like. In certain embodiments, the inorganic salts are ammonium, sodium, potassium, calcium, or magnesium salts. Salts derived from organic bases include salts of primary, secondary, and ry amines, tuted amines including lly occurring substituted amines, cyclic amines and basic ion exchange resins, such as ammonia, isopropylamine, trimethylamine, diethylamine, ylamine, tripropylamine, diethanolamine, lamine, deanol, thylaminoethanol, 2-diethylaminoethanol, dicyclohexylamine, lysine, arginine, histidine, procaine, hydrabamine, choline, betaine, benethamine, benzathine, ethylenediamine, glucosamine, methylglucamine, theobromine, triethanolamine, tromethamine, purines, piperazine, piperidine, N—ethylpiperidine, polyamine resins and the like. Particularly useful organic bases are isopropylamine, diethylamine, ethanolamine, hylamine, dicyclohexylamine, choline and caffeine.

Often crystallizations produce a solvate of the compound of this disclosure. As used herein, the term “solvate” refers to an aggregate that comprises one or more molecules of a compound of this disclosure with one or more molecules of t. The solvent may be water, in which case the solvate may be a hydrate. Alternatively, the solvent may be an organic solvent.

Finlayson Reference No.: 838-1423 Thus, the compounds of the t disclosure may exist as a hydrate, including a monohydrate, dihydrate, hemihydrate, sesquihydrate, trihydrate, tetrahydrate and the like, as well as the corresponding solvated forms. The compound of this sure may be true solvates, while in other cases, the compound of this disclosure may merely retain adventitious water or be a e of water plus some adventitious solvent.

A aceutical composition” or “nutraceutical composition” refers to a formulation of a compound of this disclosure and a medium generally ed in the art for the delivery of the biologically active compound to mammals, e.g., humans. For e, a ceutical composition of the present disclosure may be formulated or used as a standalone composition, or as a component in a prescription drug, an over the counter (OTC) medicine, a botanical drug, an herbal medicine, a natural medicine, a athic agent, or any other form of health care product reviewed and approved by a government agency. Exemplary nutraceutical compositions of the present disclosure may be formulated or used as a standalone composition, or as a nutritional or bioactive component in food, a functional food, a beverage, a bar, a food ﬂavor, a medical food, a y supplement, or an herbal product. A medium generally accepted in the art includes all pharmaceutically or nutraceutically acceptable rs, diluents or excipients therefor.

As used herein, "enriched for" refers to a plant extract or other preparation having at least a two-fold up to about a 1000-fold increase of one or more active compounds as compared to the amount of one or more active nds found in the weight of the plant material or other source before extraction or other preparation. In certain embodiments, the weight of the plant material or other source before extraction or other preparation may be dry , wet weight, or a combination f.

As used , "major active ingredient" or "major active component" refers to one or more active compounds found in a plant extract or other preparation or enriched for in a plant extract or other preparation, which is capable of at least one ical activity. In certain embodiments, a major active ingredient of an enriched extract will be the one or more active compounds that were enriched in that extract. Generally, one or more major active components will impart, directly or indirectly, most (i.e., greater than 50%, or 20% or 10%) of one or more measurable biological activities or effects as compared to other extract components. In certain embodiments, a major active ingredient may be a minor component by weight percentage of an extract (e.g., less than 50%, 25%, or 10% or 5% or 1% of the components contained in an extract) Finlayson Reference No.: 838-1423 but still provide most of the desired biological ty. Any composition of this disclosure containing a major active ingredient may also contain minor active ingredients that may or may not contribute to the pharmaceutical or nutraceutical activity of the enriched ition, but not to the level of major active components, and minor active components alone may not be effective in the absence of a major active ingredient.

“Effective amount” or “therapeutically effective amount” refers to that amount of a compound or composition of this disclosure which, when administered to a mammal, such as a human, is sufﬁcient to effect treatment, including any one or more of: (l) maintaining articular age homeostasis, (2) balancing chondrocytes catabolic and ic process, (3) treating or ting loss of cartilage in a mammal, (4) promoting joint health, (5) suppressing loss of cartilage in a mammal, (6) increasing joint ﬂexibility in a mammal, (7) treating or preventing joint pain in a mammal, (8) modifying inﬂammation of a joint in a mammal, and (9) increasing joint range of motion, (10) managing and/or treating osteoarthritis and/or rheumatoid arthritis, preventing osteoarthritis and/or rheumatoid tis, or ing the progression of osteoarthritis and/or rheumatoid tis in a mammal. The amount of a compound, an extract or a ition of this disclosure that constitutes a “therapeutically effective amount” will vary depending on the bioactive compound, or the biomarker for the condition being treated and its severity, the manner of administration, the duration of treatment, or the age of the subject to be treated, but can be ined routinely by one of ordinary skill in the art having regard to his own knowledge and to this disclosure. In certain embodiments, “effective ” or “therapeutically effective amount” may be demonstrated as the quantity over the body weight of a mammal (i.e., 0.005 mg/kg, 0.01 mg/kg, or 0.1 mg/kg, or 1 mg/kg, or 10 mg/kg, or 50 mg/kg, or 100 mg/kg, or 200 mg/kg, or 500 mg/kg). The human equivalent daily dosage can be extrapolated from the “effective amount” or “therapeutically effective amount” in an animal study by utilization of FDA ine in consideration the difference of total body areas and body weights of s and human.

"Dietary supplements" as used herein are a product that es, promotes, increases, manages, controls, maintains, optimizes, es, reduces, inhibits, or prevents a particular condition associated with a natural state or biological process, or a structural and functional integrity, a homeostasis of a biological function or a phenotypic condition (1'.e., are not used to diagnose, treat, mitigate, cure, or prevent disease). For example, with regard to joint health-related conditions, dietary supplements may be used to in joint cartilage, ze cartilage Finlayson Reference No.: 838-1423 degradation, promote health joints by protecting cartilage integrity, diminish the action of enzymes that affect j oint health, improve joint movement and/or function, alleviate joint pain, alleviate joint stiffness, improve joint range of motion and/or ﬂexibility, promote mobility, balance anabolic and catabolic homeostasis and/or the like. In certain embodiments, dietary supplements are a special category of food, functional food, medical food and are not a drug.

“Treating” or “treatment” as used herein refers to the treatment of the disease or condition of st in a mammal, such as a human, having the disease or ion of interest, and includes: (i) preventing the disease or condition from occurring in a mammal, in ular, when such mammal is predisposed to the condition but has not yet been diagnosed as having it, (ii) inhibiting the disease or condition, 1'. e., arresting its development, (iii) relieving or modifying the disease or condition, i.e., causing regression of the disease or condition, or (iv) ing the symptoms resulting from the disease or condition, (e. g., relieving pain, reducing ation, reducing loss of cartilage) without addressing the underlying disease or condition, (v) balancing the anabolic and lic homeostasis or changing the phenotype of the disease or condition. As used herein, the terms “disease” and “condition” may be used interchangeably or may be ent in that the particular malady or condition may not have a known causative agent (so that etiology has not yet been worked out) and it is therefore not yet recognized as a e but only as an undesirable condition or syndrome, wherein a more or less specific set of symptoms have been identified by clinicians.

As used herein, stical significance” refers to a p value of 0.050 or less when calculated using the Students t-test and indicates that it is unlikely that a particular event or result being measured has arisen by chance.

For the purposes of administration, the compounds of the present disclosure may be stered as a raw chemical or may be formulated as pharmaceutical or nutraceutical compositions. Pharmaceutical or nutraceutical itions of the present disclosure comprise a compound of structures described in this disclosure and a pharmaceutically or nutraceutically acceptable r, diluent or excipient. The nd of structures described here are present in the ition in an amount which is effective to treat a particular disease or condition of interest - that is, in an amount sufﬁcient promote chondrocyte, or ellular matrix, or cartilage homeostasis or any of the other associated indications described herein, and generally with acceptable toxicity to a patient.

Finlayson Reference No.: 838-1423 stration of the compounds or compositions of this disclosure, or their pharmaceutically or nutraceutically acceptable salts, in pure form or in an appropriate pharmaceutical or nutraceutical composition, can be carried out via any of the accepted modes of stration of agents for serving similar utilities. The pharmaceutical or nutraceutical compositions of this disclosure can be prepared by combining a compound of this disclosure with an riate pharmaceutically or nutraceutically acceptable carrier, diluent or excipient, and may be formulated into preparations in solid, semi-solid, liquid or s forms, such as tablets, capsules, powders, granules, ointments, solutions, suppositories, ions, inhalants, gels, creams, lotions, tinctures, sashay, ready to drink, masks, microspheres, and aerosols. Typical routes of administering such ceutical or nutraceutical compositions include oral, topical, transdermal, inhalation, parenteral, sublingual, buccal, rectal, vaginal, or intranasal. The term parenteral as used herein includes subcutaneous injections, intravenous, intramuscular, intrasternal injection or infusion techniques. Pharmaceutical or nutraceutical compositions of this disclosure are ated so as to allow the active ingredients contained therein to be bioavailable upon administration of the composition to a t. Compositions that will be administered to a subject or patient or a mammal take the form of one or more dosage units, where for e, a tablet may be a single dosage unit, and a container of a compound or an extract or a composition of 2-3 plant extracts of this sure in aerosol form may hold a plurality of dosage units. Actual methods of preparing such dosage forms are known, or will be apparent, to those skilled in this art, for example, see Remington: The Science and Practice of Pharmacy, 20th Edition (Philadelphia College of cy and Science, 2000). The composition to be administered will, in any event, contain a therapeutically effective amount of a compound of this disclosure, or a pharmaceutically or nutraceutically acceptable salt thereof, for treatment of a disease or condition of st in accordance with the teachings of this disclosure.

A pharmaceutical or nutraceutical composition of this disclosure may be in the form of a solid or liquid. In one aspect, the carrier(s) are particulate, so that the compositions are, for example, in tablet or in powder form. The carrier(s) may be liquid, with the compositions being, for example, oral syrup, injectable liquid or an l, which is useful in, for example, inhalatory administration. son Reference No.: 838-1423 When intended for oral administration, the pharmaceutical or nutraceutical composition is in either solid cream, suspension and gel forms are included within the forms considered herein as either solid or liquid.

As a solid composition for oral administration, the pharmaceutical or nutraceutical ition may be formulated into a powder, granule, compressed tablet, pill, capsule, g gum, sashay, wafer, bar, or like form. Such a solid composition will typically contain one or more inert ts or edible carriers. In addition, one or more of the following may be present: binders such as carboxymethylcellulose, ethyl cellulose, cyclodextrin, microcrystalline cellulose, gum tragacanth or gelatin, excipients such as starch, lactose or dextrins, disintegrating agents such as alginic acid, sodium te, el, corn starch and the like, lubricants such as magnesium stearate or Sterotex, glidants such as colloidal silicon dioxide, ning agents such as sucrose or saccharin, a ﬂavoring agent such as peppermint, methyl salicylate or orange ﬂavoring, and a coloring agent.

When the pharmaceutical or nutraceutical ition is in the form of a capsule, for example, a n capsule, it may contain, in on to materials of the above type, a liquid carrier such as polyethylene glycol or oil.

The pharmaceutical or nutraceutical composition may be in the form of a liquid, for example, an elixir, re, syrup, solution, emulsion or suspension. The liquid may be for oral administration or for delivery by injection, as two examples. When intended for oral administration, a useful composition contains, in addition to the present compounds, one or more of a sweetening agent, preservatives, dye/colorant and ﬂavor enhancer. In a composition intended to be administered by injection, one or more of a surfactant, preservative, wetting agent, dispersing agent, suspending agent, buffer, stabilizer and isotonic agent may be included.

The liquid pharmaceutical or nutraceutical compositions of this disclosure, whether they be solutions, suspensions or other like form, may include one or more of the following adjuvants: sterile diluents such as water for injection, saline on, such as physiological , Ringer’s solution, ic sodium chloride, ﬁxed oils such as synthetic mono or diglycerides which may serve as the solvent or suspending medium, polyethylene glycols, glycerin, propylene glycol or other solvents, antibacterial agents such as benzyl alcohol or methyl paraben, idants such as ascorbic acid or sodium bisulf1te, chelating agents such as ethylenediaminetetraacetic acid, buffers such as acetates, citrates or phosphates and agents for the adjustment of tonicity such as sodium Finlayson Reference No.: 838-1423 chloride or dextrose. The parenteral preparation can be enclosed in ampoules, disposable syringes or multiple dose vials made of glass or plastic. Physiological saline is a generally useful adjuvant.

An injectable pharmaceutical or nutraceutical composition is e.

A liquid pharmaceutical or nutraceutical composition of this disclosure intended for either parenteral or oral stration should contain an amount of a compound of this disclosure such that a suitable dosage will be obtained.

The pharmaceutical or nutraceutical composition of this disclosure may be intended for topical administration, in which case the carrier may suitably se a solution, on, cream, lotion, nt, or gel base. The base, for example, may comprise one or more of the following: petrolatum, lanolin, polyethylene s, bee wax, mineral oil, diluents such as water and alcohol, and ﬁers and stabilizers. Thickening agents may be present in a pharmaceutical or nutraceutical composition for topical administration. If intended for transdermal administration, the composition may include a ermal patch or iontophoresis device.

The pharmaceutical or eutical composition of this disclosure may be intended for rectal administration, in the form, for example, of a suppository, which will melt in the rectum and release the drug. The composition for rectal administration may contain an oleaginous base as a suitable nonirritating excipient. Such bases include n, cocoa butter and polyethylene glycol.

The pharmaceutical or eutical composition of this disclosure may include s materials, which modify the physical form of a solid or liquid dosage unit. For example, the composition may include materials that form a coating shell around the active ingredients. The materials that form the coating shell are typically inert, and may be selected from, for e, sugar, shellac, and other enteric coating agents. Alternatively, the active ingredients may be encased in a gelatin capsule.

The pharmaceutical or nutraceutical composition of this disclosure in solid or liquid form may e an agent that binds to the compound of this disclosure and thereby s in the delivery of the compound. Suitable agents that may act in this capacity include a monoclonal or polyclonal antibody, a protein or a liposome.

The pharmaceutical or nutraceutical composition of this disclosure in solid or liquid form may include reducing the size of a particle to, for example, improve bioavailability. The size of a powder, granule, particle, microsphere, or the like in a composition, with or without an excipient, can be macro (e.g., visible to the eye or at least 100 pm in size), micro (e.g., may range from about Finlayson Reference No.: 838-1423 100 um to about 100 nm in size), nano (e.g., may no more than 100 nm in size), and any size in between or any combination f to improve size and bulk density.

The pharmaceutical or nutraceutical composition of this disclosure may consist of dosage units that can be administered as an aerosol. The term aerosol is used to denote a variety of systems ranging from those of dal nature to s consisting of rized packages. Delivery may be by a liqueﬁed or compressed gas or by a suitable pump system that dispenses the active ingredients. Aerosols of compounds of this disclosure may be delivered in single phase, sic, or tri-phasic systems in order to deliver the active ingredient(s). Delivery of the aerosol includes the necessary container, activators, valves, subcontainers, and the like, which together may form a kit. One skilled in the art, without undue experimentation, may determine the most appropriate aerosol(s).

The ceutical or nutraceutical compositions of this disclosure may be prepared by methodology well known in the pharmaceutical or nutraceutical art. For example, a pharmaceutical or nutraceutical composition intended to be administered by ion can be prepared by combining a compound of this disclosure with sterile, led, deionized water so as to form a on. A surfactant may be added to facilitate the formation of a homogeneous solution or suspension. Surfactants are compounds that non-covalently interact with the compound of this disclosure so as to facilitate ution or homogeneous suspension of the compound in the aqueous delivery system.

The nds of this disclosure, or their pharmaceutically or eutically acceptable salts, are stered in a therapeutically effective amount, which will vary depending upon a variety of factors including the activity of the speciﬁc compound employed, the metabolic stability and length of action of the compound, the age, body weight, general health, sex, and diet of the patient, the mode and time of administration, the rate of excretion, the drug combination, the severity of the particular disorder or condition, and the t undergoing therapy.

Compounds of this disclosure, or pharmaceutically or nutraceutically acceptable derivatives thereof, may also be administered simultaneously with, prior to, or after administration of food, water and one or more other therapeutic agents. Such combination therapy includes administration of a single pharmaceutical or nutraceutical dosage formulation which contains a compound or an t or a composition with 2-3 plant extracts of this disclosure and one or more additional active agents, as well as administration of the compound or an extract or a composition Finlayson Reference No.: 23 with 2-3 plant extracts of this disclosure and each active agent in its own separate pharmaceutical or nutraceutical dosage formulation. For example, a compound or an extract or a composition with 2-3 plant extracts of this disclosure and another active agent can be administered to the patient together in a single oral dosage composition, such as a tablet or e, or each agent can be administered in separate oral dosage formulations. Where separate dosage formulations are used, the compounds of this disclosure and one or more additional active agents can be administered at ially the same time, i.e., concurrently, or at separately staggered times, i.e., sequentially, combination therapy is understood to include all these regimens.

It is understood that in the present description, combinations of sub stituents or variables of the depicted formulae are permissible only if such contributions result in stable compounds.

It will also be appreciated by those skilled in the art that in the s described herein the functional groups of ediate compounds may need to be protected by suitable protecting groups. Such functional groups include hydroxy, amino, mercapto and carboxylic acid. le protecting groups for hydroxy include trialkylsilyl or diarylalkylsilyl (for example, t- butyldimethylsilyl, t-butyldiphenylsilyl or trimethylsilyl), tetrahydropyranyl, benzyl, and the like.

Suitable protecting groups for amino, amidino and guanidino include t-butoxycarbonyl, oxycarbonyl, and the like. Suitable ting groups for mercapto e -C(O)-R” (where R” is alkyl, aryl or arylalkyl), p-methoxybenzyl, trityl and the like. Suitable protecting groups for carboxylic acid include alkyl, aryl or arylalkyl esters. Protecting groups may be added or removed in accordance with standard techniques, which are known to one skilled in the art and as described herein. The use of protecting groups is described in detail in Green, T.W. and P.G.M.

Wutz, Protective Groups in Organic Synthesis (1999), 3rd Ed, Wiley. As one of skill in the art would appreciate, the protecting group may also be a polymer resin such as a Wang resin, Rink resin or a 2-chlorotrityl-chloride resin.

It will also be appreciated by those skilled in the art, although such protected derivatives of compounds of this disclosure may not possess pharmacological activity as such, they may be administered to a mammal and thereafter metabolized in the body to form compounds of this disclosure which are cologically . Such derivatives may therefore be described as “prodrugs”. All prodrugs of nds of this sure are included within the scope of this disclosure.

Finlayson Reference No.: 838-1423 Furthermore, all compounds or extracts of this disclosure which exist in free base or acid form can be converted to their pharmaceutically or eutically acceptable salts by treatment with the riate inorganic or organic base or acid by methods known to one skilled in the art.

Salts of the compounds of this disclosure can be converted to their free base or acid form by standard techniques.

In some embodiments, compounds or extracts ofthe present disclosure can be isolated from plant s, for example, from those plants included in the Examples and elsewhere throughout the present application. Suitable plant parts for isolation of the compounds include , bark, trunk, trunk bark, stem, stem bark, twigs, tubers, root, rhizome, root bark, bark surface, young shoots, seed, fruit, androecium, gynoecium, calyx, stamen, petal, sepal, carpel (pistil), ﬂower, or any combination thereof. In some related embodiments, the compounds or extracts are isolated from plant sources and synthetically d to contain any of the d substituents. In this regard, synthetic modiﬁcation of the nd isolated from plants can be accomplished using any number of techniques which are known in the art and are well within the knowledge of one of ry skill in the art.

Kochia ia, also identiﬁed as Bassia scoparia, Bassia sieversicma, Kochia alala, Kochia Zrichophila, Kochia lrichophylla, is a large annual herb g from seeds with the common names: burning bush, ragweed, summer s, kochia and Mexican ﬁreweed. The plant is native to Asia but naturalized in many parts of North America as well. Kochia scoparia plant contains high levels of protein and is commonly used as forage for ock. The seeds could be served as food for birds and are also valuable as poultry feed. Kochia seeds are also used as food garnish in Japan called Tonburi or land caviar.

Kochiae fructus or seeds has been used as folk medicine in Asian countries to treat a y of diseases, such as skin diseases, diabetes mellitus, rheumatoid arthritis, liver disorders, and jaundice, etc. Recent studies have also reported kochia seeds with antioxidant, anti-inﬂammatory, antiparasitic, anti-cancer, antidiabetic, hypoglycemic, weight loss, anti-allergic, analgesic properties. Oleanolic acid type triterpenoid saponins were identiﬁed as the active components responsible for most of Kochia fructus efﬁcacies. Momordin Ic, originally isolated from ica cochinchinensis, is a principle constituent of Kochiae fructus and is also reported in various natural herbal medicines with antinociceptive and anti-inﬂammatory activities in hind paw Finlayson Reference No.: 838-1423 licking and formalin test in mice. Both 70% Kochiae fructus ethanol extracts and Momordin Ic showed inhibitory effects in Carrageenan-induced paw edema model in mice.

Kochia extract, as demonstrated in example 1 to 4, is a contemplated component or tuent that can be utilized as part of a target compound or composition. Kochia extract may be obtained from any le source, including Kochia scoparia, Bassia scoparia, Bassia angustifolia, Momordica cochinchinensis, Bassia dinleri, Bassia eriophora, Bassia hyssopifolia, Bassia indica, Bassia laniﬂora, Bassia lasicmtha, Bassia liltorea, Bassia muricata, Bassia odontoptera, Bassia pilosa, Bassia prostrala, Bassia salsoloides, Bassia stellaris, Bassia hcmica, Bassia Zomentosa, Bassia villosissima or a combination thereof.

HOfIOH o 0 OH HO OH Momordin Ic.

As illustrated in examples 1, 2, 3 and 4, Kochia extract may be enriched for one or more as contemplated herein. Contemplated ns ed from Kochia scoparia that are extracted with any suitable solvent, including supercritical ﬂuid of C02, water, methanol, l, alcohol, a water-mixed solvent or a combination thereof, or with supercritical ﬂuid. In contemplated embodiments, the Kochia extract comprises about 0.01% to about 99.9% ns. Contemplated saponins isolated from Kochia extract are saponin A, Bassiasaponin B, Kochioside A, Kochioside B, Kochioside C, Kochianoside I, Scoparianos A, Scoparianoside B, Scoparianoside C, Momordin Ic, Kochianoside I, Kochianoside II , Kochianoside III, Kochianoside IV, 2'—O- yranosylmomordin Ic, 2'-O-Glucopyranosylmomordin IIc, etc.

Alpinia galanga belongs to the ginger family and is used as a spice herb in southeast Asian cuisine with the common names: lengkuas, greater al and blue ginger. The plant is a perennial herb native to southeast Asia and found commonly in greater Sunda islands, Philippines, and Thailand. This plant's rhizome has been used for food with a unique pungent sensation similar to black pepper without a lingering . Alpim'a galanga as traditionally used to treat various Finlayson Reference No.: 838-1423 kinds of disease including eczema, bronchitis, otitis internal, gastritis, ulcers and cholera, appetite boosting, tonic effect, etc. Many pharmacological activities have been reported for Alpinia galanga, especially as antibacterial, antifungal, antiviral, immunomodulatory, antioxidant, antidiabetic, analgesic and many other pharmacological functions.

The main chemical constituents of Alpinia galanga are reported as ﬂavonoids, such as kaempferol, kaempferide, and volatile components including trans -p-coumaryl diacetate, di-(phydroxy-ci s-styryl) methane, eugenol e, l'-hydroxychavicol acetate, p- hydroxycinnamaldehyde, etc. Phenylpropanoids, l'-acetoxychavicol acetate gal e) and trans aryl diacetate, were ed and identiﬁed as two main active compounds of this plant in this study. l'-acetoxychavicol acetate was reported as pungent principle for Alpinia galanga and was reported to have antimicrobial and anticancer properties as well. 3* \ 1 lm A60” eioxyehav§<>3§ acetate p~eoumary§ diaeeia§e The anti-inﬂammatory and analgesic activities of the topical application ofAlpinia galanga methanolic extract were illustrated in the examples 8, 9, 10 and 11. The anti-inﬂammatory and analgesic activity of Alpinia methanol extract was also found in both Carrageenan-induced paw edema model in rats and in formalin test. One of major phenylpropanoids, l'-Acetoxychavicol acetate, and Alpinia galanga e extract have been reported effective in Incomplete Freund’s Adjuvant induced arthritis model in rats.

Alpinia extract is a contemplated component or constituent that can be utilized as part of a target compound or composition. Alpinia extract may be obtained from any le galangal source, including Alpinia a, Alpinia oﬂicinarum, Boesenbergia rotunda, Kaempferia galanga, Alpinia oxyphylla, Alpinia abundiﬂora, Alpinia acrostachya, Alpinia caerulea, Alpinia calcarala, Alpinia gera, Alpinia globosa, a javam'ca, Alpinia melanocarpa, Alpinia , a nigra, Alpinia nulcms, Alpinia peliolale, Alpinia ata, Alpinia pyramidata, Finlayson Reference No.: 838-1423 Alpinia raﬂlesicma, Alpinia speciosa, Alpinia vitlala, Alpinia zerumbet, Alpinia zingiberl'na, or a combination thereof.

Alpinia extract may be enriched for one or more as contemplated herein and as demonstrated in examples 8, 9, 10 and 11. Contemplated aromatics isolated from Alpinia extract are extracted with any suitable solvent, including supercritical ﬂuid of C02, water, methanol, ethanol, alcohol, a water-mixed solvent, organic solvent, such as , ethyl acetate, acetone, butanol, or a combination thereof, or with supercritical ﬂuid, or by water distillation of oil in the rhizomes. In contemplated embodiments, the Alpinia extract comprises about 0.01% to about 99.9% phenylpropanoid small aromatics. Contemplated aromatics isolated from a extract are l'-Acetoxyeugenol acetate, Coniferyl diacetate, 3-(4-Hydroxyphenyl)propenal, 3-(4- Hydroxyphenyl)propenol, Methyl cinnamate, FEMA 2698, 3 -(4-Methoxyphenyl)propen- l-ol, l'-Hydroxychavicol acetate, 4-Acetoxycinnamyl alcohol, 4-Acetoxycinnamyl ethyl ether, 1'- Ethoxychavicol acetate, l-(3,4-Dihydroxyphenyl)propen-l-ol, (S)-form, 3'—Me ether, 4'—Ac, l'- Acetoxychavicol acetate, l-(4-Hydroxyphenyl)—2-propen-l-ol, -form, Di-Ac, 3-(4- Hydroxyphenyl)propen-l-ol, (E)-form, Di-Ac, 4-(2-Propenyl)-l,2-benzenediol, l-O-D- yranoside, 4-(2-Propenyl)-l,2-benzenediol, 2-O-D-Glucopyranoside, Bis(4- acetoxycinnamyl) ether, Ethyl 4-feruloyl-D-glucopyranoside, nicoside, 4-(2-Propenyl)-l,2- benzenediol, l-O-[-L-Rhamnopyranosyl-D-glucopyranoside], 4-(2-Propenyl)-l,2-benzenediol, Di-O-D-glucopyranoside, 4'-O-trans-Feruloyltachioside or a combination thereof.

Piper , with common name black pepper, is a ﬂowing vine ofthe family ceae.

In this disclosure, the terms “Piper”, r”, and “Piper/Pepper” are used interchangeably to refer to ments comprising this extract or constituent. Black pepper is native to Kerala state in Southwestern India and extensively cultivated in tropical regions, such as Vietnam, India, and sia. The ground dried fruit, known as corn, has been used for its ﬂavor and as traditional medicine. Black pepper is one of the most ly used spices in the world. Piperine is the main constituent in black pepper contributing to the hot and pungent ﬂavor.

Finlayson Reference No.: 838-1423 <0 ‘\ Piperine Black peppercorns feature as remedies in Ayurveda, Siddha and Unani medicine in South Asia. They are used as an appetizer and to treat digestive system-related problems. Black pepper could be used as a remedy for sore throat to reduce throat inﬂammation. Externally, it could be applied to reduce hair loss and treat some skin ms. Many cological effects have been reported for black pepper, such as antifungal, antioxidant, ive boosting, anti-depressant and cognitive effect, sic and anti-inﬂammatory, ncer, immuno-modulatory, lipid lowering, Piper extract is a plated component or constituent that can be utilized as part of a target compound or composition. Piper extract may be obtained from any suitable source as illustrated in example 5, 6, and 7, including Piper nigrum and many other Piper spp., Periconia sp.

Piper nigrum, Piper longum, Piper amalgo, Piper aurcmiiacum, Piper chaba, Piper capense, Piper crassinervium, Piper guineense, Piper meihysiicum, Piper novae-hollcmdiae, Piper peepuloides, Piper nse, Piper puberulum, Piper relroﬁacium, Piper sinienense, Piper luberculaium, , Piper hancei, Glycine max, Pelrosimonia monandra, Meniha piperaia, ulon absimile, and Ulocladium sp or a combination thereof.

The principle active alkaloid compound, Piperine, was ively studied and reported to act as a central nervous system antidepressant and nerve stimulant, and to have idant, anti- fever, hepatoprotective, pain-relieving, anti-inﬂammatory, insecticidal and many other effects.

Piperine was also reported as a bioavailability enhancer.

Piper extract may be enriched for one or more as contemplated herein as illustrated in examples 5, 6, and 7. Contemplated alkaloids isolated from Piper extract are extracted with any suitable solvent, including supercritical ﬂuid of C02, water, methanol, ethanol, alcohol, a water- mixed solvent, organic solvent such as ethyl acetate, acetone, butanol or a combination thereof, or with supercritical ﬂuid. In contemplated ments, the Piper extract comprises about 0.01% to about 99.9% dine alkaloids. Contemplated alkaloids isolated from Piper extract are Finlayson Reference No.: 838-1423 Piperine; Piperchabamide A; Kaousine; 5-Acetoxy-5;6-dihydro(3-pheny1propanoy1)—2(1H)— pyridinone; 5,6-Dihydro-N—(3,4-dimethoxycinnamoy1)-2(1H)-pyridinone; N—[3-(3;4- Dimethoxyphenyl)propanoyl]-5;6-dihydro-2(1H)-pyridinone; Cenocladamide; 3,4- Epoxypipermethystine; 4'—O-Demethy1pip1artine; Piplaroxide; cis—Piplartine; Piplartine; 8,9- Dihydropiplartine; 3,4-Epoxy-8,9-dihydropip1artine; Cycloguineense B; ide K; Nigramide H; Nigramide J; Nigramide M; Nigramide N; Nigramide I; Nigramide L; Chabamide H; Chabamide I; Nigramide Q; Nigramide A; Nigramide C; Nigramide P; Dipiperamide C; Nigramide G; Dipiperamide A; Dipiperamide E; Pipercyclobutanamide A; Nigramide R; Nigramide B; Dipiperamide B; Dipiperamide F; Dipiperamide G; Nigramide F; Piperchabamide G; Piperarborenine A; Piplartine dimer A; 7,8'—Diepimer; 3,3'—bis(demethoxy); 1;l'-[[2;4-Bis(6- methoxy-1,3-benzodioxoly1)-1,3-cyclobutanediy1]dicarbony1]bispiperidine; Piperarborenine E; Pipercyclobutanamide B; Dipiperamide D; Nigramide S; Nigramide D; ide E; Piperarborenine D; Piperarborenine B; 2,4-Bis(2-methoxy-4;5-methylenedioxyphenyl)-1,3- cyclobutanecarboxylic acid dipiperidide; 3'—Methoxy; Piperarborenine C; Piperarboresine; Piperchabamide H; 1;1'-[[2;4-Bis(3,4;5-trimethoxypheny1)-1,3-cyclobutanediy1] dicarbonyl] bis[5;6-dihydro-2(1H)-pyridone]; 3-Pheny1propanoic acid 2,3-didehydrohydroxypiperidide; 1- (1;6-Dioxo—2;4-decadieny1)piperidine; 1-[5-(4-Hydroxyphenyl)oxo—2;4-pentadieny1] piperidine; Ilepcimide; thy1enedioxycinnamoyl piperidide; (Z)-form; 3,4-Dihydroxy(3- phenylpropanoyl)piperidinone; hydroxydecenoic acid piperidide; hydroxy decenoic acid; (2E;4S;5R)-form; Piperidide; Chavicine; Isochavicine; Isopiperine; Piperpense; Feruperine; 1-[5-(1,3-Benzodioxolyl)oxo—2-penteny1]piperidine; N—(3-Methoxy-4;5- methylenedioxycinnamoy1)piperidide; 2-Methoxy-4;5-methylenedioxycinnamoyl piperidide; 2- Hydroxy-4;5-methylenedioxycinnamic acid; (Z)-form; Me ether; piperidide; Dihydroferuperine; Tetrahydropiperine; ongumamide C; Puberullumine; 1-[7-(1,3-Benzodioxolyl)-l-oxo- 2,4;6-heptatrienyl]piperidine; 1-[7-(1,3-Benzodioxoly1)0X0-2;4-heptadienyl]piperidine; Pipersintenamide; ne; (E;E)-form; Piperx; lein A; (E)-form; Piperine S; Piperodione; 4;5-Dihydro-2'-methoxypiperine; 2,4-Hexadecadienoic acid dide; ongimine B; 11- Pheny1-2;4-undecadienoic acid piperidide; Piperlongumamide B; 1,3-Benzodioxolyl) oxo—7-octadeceny1]piperidine; Dehydropipernonaline; rine; 1-[9-(1;3-Benzodioxoly1)—1- oxo-Z;8-nonadieny1]piperidine; Piperolein B; Piperoctadecalidine; 2,4,12-Octadecatrienoic acid Finlayson Reference No.: 838-1423 piperidide, 2,4-Octadecadienoic acid piperidide, l-[l l-(l,3-Benzodioxolyl)—l-oxo-2,4,10- undecatrienyl]piperidine, Piperchabamide B, Pipereicosalidine, l-[8,9-Dihydroxy(3,4- methylenedioxyphenyl)nonenoyl]piperidine, Pipernonaline, 8,9-Dihydro, 8R*,9S*-dihydroxy, N—(2,l4-Eicosadienoyl)piperidine, 2,4-Eicosadienoic acid piperidide, l-[l3-(l,3-Benzodioxol oxo-2,4,l2-tridecatrienyl]piperidine, Pipertridecadienamide, Pipsaeedine, Pipbinineor, or a combination thereof.

Magnolia aﬁcinalis, commonly known as “houpu” in Chinese as one of the most popular traditional Chinese ne plants, with a very wide range of applications. It is a species of Magnolia that is native in China, mainly growing in Sichuan and Hubei provinces. Houpu refers to its thick bark, which can be stripped from the stems, branches, and roots. The traditional indications are to treat wind , cold damage, headache, ﬁght qi and blood impediments.

Magnolia bark has been used to treat menstrual cramps, abdominal pain, abdominal bloating and gas, nausea, and indigestion. The bark is also an ingredient in formulas used for treating coughs and asthma. Many of the formulations with Magnolia bark are used in treating lung diseases such as including cough and asthma or inal infections and spasms, relieving abdominal swelling of various causes and edema.

Bisphenolic lignans are identiﬁed as the major active ents responsible for the efﬁcacy. Magnolol and honokiol, as two main polyphenol compounds found in Magnolia bark, have been reported with s pharmacological activities and ons, such as antioxidant, anti-inﬂammatory, and antitumor (Park 2004). The anticancer studies of honokiol have been extended to several different solid tumor types such as breast, prostate, gastric, and ovarian cancer, with potential to enhance current anticancer regimens (Fried 2009). Honokiol also reduced inﬂammation and ive stress, providing beneﬁcial effects in neurological protection, and glucose regulation with great potential as therapeutic agents for inﬂammatory disease. In ular, magnolol and ol have been known to eXhibit potent antimicrobial activity against ositive and Gram-negative bacteria as well as fungi such as Propionibaclerium sp. and S. aureus showing its potential as antimicrobial agents effective against more ious and antibiotic resistant rganisms (Bopaiah 2001, Bang 2000, Syu 2004). The t of honokiol and magnolol could be varied from 1-99% in the commercialized Magnolia bark extracts.

Finlayson Reference No.: 838-1423 M a goal at 3H en mi :33 Magnolol and honokiol As demonstrated in example 13, Magnolia t is a contemplated component or constituent that can be utilized as part of a target compound or composition. Magnolia extract may be obtained from any suitable source, including Magnolia oﬁcinalis, Magnolia aie, Magnolia biondii, Magnolia coco, Magnolia denudale, Magnolia fargesii, Magnolia garreiiii, Magnolia grandiﬂora, Magnolia lienryi, Magnolia liliﬂora, Magnolia kachirachirai, ia Kobus, Magnolia obovaia, Magnoliapraecocissima, Magnoliaplerocarpa, iapyramidala, Magnolia rosiraie, Magnolia salicifolia, Magnolia siebola’ii, Magnolia soulangeana, Magnolia slellaie, ia virginiana, prod. of degradation of birch lignin, Acanihus ebracieaius, Aplosimum cens, Aralia bipinnaia, Araucaria anguslifolia, Araucaria araucana, Ariemisia absinihium, Haplophyllum aculifolium, Haplophyllum perforalum, Lirioa’endron tulipifera, Krameria cyslisoia’es, Perilla fruiescens, Lawsonia inermis Myrisiica ns (nutmeg), Parakmeria ensis (preferred genus name Magnolia), Perseajaponica, Piperfuiokadsura, Piper wigliiii, Rollinia mucosa, Sassaﬁas randaiense, Scrophularia albia’a-colchica, Siellera chamaejasme, Syringa veluiina, Syzygium , Talauma gloriensis, Virola elongate, Urbanodena’ron osum, Wikslroemia sikokiana or a combination thereof.

Magnolia extract may be enriched for one or more as contemplated herein. Contemplated lignans isolated from Magnolia extract are ted with any suitable solvent, including supercritical ﬂuid of C02, water, methanol, ethanol, alcohol, c t such as ethyl e, acetone, butanol, a water-mixed solvent or a combination thereof, or with supercritical ﬂuid. In contemplated embodiments, the Magnolia extract comprises about 0.01% to about 99.9% biphenolic lignans. Contemplated lignans isolated from Magnolia extract are magnolol, honokiol, Magnaldehyde D, Magnaldehyde D, 4'—Deoxy, roxy, 6,8-Epoxy-3,3'-ligna-7,8'-dien-4'-ol, Finlayson Reference No.: 838-1423 3,3'-Ligna-8;8'-diene-4;6'-diol; 3,3'-Ligna-8;8'—diene-4;4'-diol; 3,3'-Ligna-8;8'—diene-4;6'-diol;7'- Isomer(E-); Magnaldehyde D; 6'—Methoxy; 4'—deoxy; Magnaldehyde A; Magnaldehyde A; 6'- Hydroxy; xy; 6,8-Epoxy-3,3'-ligna-7;8'-dien-4'-ol; 9-Hydroxy; 3,3'-Ligna-8;8'-diene-4;6'- diol; 6'—Me ether; 3-Formyl-2;2'-dihydroxy-5,5'-dipropenylbiphenyl; dehyde A; 6'- Methoxy; 4'—deoxy; Magnaldehyde A; oxy; 4-deoxy; 3,3'-Ligna-8;8'—diene-4;4'-diol; 4-Et ether; 3,3'-Ligna-8;8'-diene-4;4';5-triol; 5-Me ether; Magnolignan E; Magnolignan C; Magnolignan A; 8';9'-Dihydroxyhonokiol; 3,3'-Ligna-8;8'-diene-4;4'-diol; 4-O-(2-Propenyl) ether; 4-Hydroxy-6'-methoxy-3;3'-ligna-7;7'-diene-9;9'-dial; Magnaldehyde C' 7 Honokitriol; erythro-Honokitriol; Magnolignan B; erythro-Magnolignan B' 7 Coumanolignan; Magnolignan D; erythro-Magnolignan D; 5;5'-Diallyl-2'-(3-methylbutenyloxy)biphenylol; 7-O-Ethylhonokitriol; 6'—Amino-3,3'-ligna-8;8'-dienol; N-[2-(4-Hydroxyphenyl)ethyl]; Houpulin C; Piperitylmagnolol; Piperitylhonokiol; Bornylmagnolol; Houpulin I; Houpulin F; Houpulin G; Houpulin H; Magnolignan A 4'—glucoside; ignan C 6'—glucoside; Clovanemagnolol; Eudeshonokiol A; Eudeshonokiol B; Eudesmagnolol or a combination thereof.

Contemplated compounds; medicinal compositions and itions may comprise or additionally comprise or consist of at least one active ingredient. In some embodiments; at least one bioactive ingredient may comprise or consist of plant powder or plant extract or the like.

In any of the entioned embodiments; the compositions comprising mixtures of extracts or compounds may be mixed at a particular ratio by weight. Demonstrated in example 15; an Alpinia extract and a Pepper extract may be blended in a 1:2 weight ratio; tively. In certain embodiments; the ratio (by weight) of two extracts or compounds of this disclosure ranges from about 0.5:5 to about 5:0.5. Similar ranges apply when more than two ts or compounds (e.g.; three; four; ﬁve) are used. ary ratios e 0.5: 1; 05:2, 05:3, 05:4, 056, 1:1; 1:2; 1:3; 1:4; 1:5; 2:1; 2:2; 2:3; 2:4; 2:5; 3:1; 3:2; 3:3; 3:4; 3:5; 4:1; 4:2; 4:3; 4:4; 4:5; 5:1; 5:2; 5:3; 5:4; 5:5; 1:05, 2:05, 3:05, 4:05, or 5:0.5. In certain embodiments illustrated in example 14; the disclosed individual extracts of Alpinia; and/or Pepper; and/or Magnolia and/or Kochia are blended into a composition with 3 individual extracts in a l:l:l; 2:1:1; 3:1:1; 4:1:1; 5:1:1; 12:1, 13:1; 14:1, 15:1, 1:12, 1:13; 1:14, 1:15, 1:23; 12:4, 12:5, 12:6, 12:6, 12:8, 1:2:9 or 1:2:10 etc. weight ratio; respectively. In further embodiments; the disclosed individual extracts of Finlayson nce No.: 838-1423 Alpinia, Pepper, Magnolia and Kochia have been combined into a composition called AMK as an examples but not limited to a blending ratio of 2:4:3 and 5:4:4 as of AlpiniazMagnoliazKochia as demonstrated in e 14. In further embodiments, such combinations of individual ts of Alpinia, Pepper, Magnolia and Kochia at various ations of 2 to 3 of those extracts with examples, but not limited to, azPepper (AP) and Alpinia:Magnolia:Kochia (AMK), were evaluated on in vilro, and/or ex vivo and/or in vivo models for advantage/disadvantage and unexpected synergy/antagonism of the perceived biological functions and effective adjustments of anabolic and catabolic homeostasis of chondrocytes, ellular matrix, articular cartilage, and phenotype of arthritis. The best itions with speciﬁc blending ratio of individual extracts of Alpinia, or Pepper, or ia or Kochia were selected based on unexpected synergy measured on the in vilro, and/or ex vivo and/or in vivo models due to the diversity of chemical components in each extract and different mechanism of actions from different types of bioactive compounds in each extract, and potential enhancement of ADME of natural compounds in the composition to maximize the biological s.

In any of the aforementioned embodiments, the compositions comprising mixtures of extracts or nds may be present at certain percentage levels or ratios. In certain embodiments, a composition comprising an Alpinia extract and/or a Kochia extract can include 0.1% to 49.9% or about 2% to about 40% or about 0.5% to about 8% of acetoxychavicol acetate, 0.1% to 49.9% or about 1% to about 10% or about 0.5% to about 3% of Momordin lc, or a combination thereof. In certain embodiments, a composition comprising an Alpinia extract can include from about 0.01% to about 99.9% acetoxychavicol acetate or include at least 1%, 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9%, 10%, 11%, 12%, 13%, 14%, 15%, 16%, 17%, 18%, 19%, 20%, 30%, %, 40%, 45%, 50%, 55%, 60%, 65%, 70%, 75%, or 80% acetoxychavicol acetate (e.g., l'- acetoxychavicol acetate, or aryl diacetate, or both) In certain examples, a composition ofthis disclosure may be formulated to further se a pharmaceutically or nutraceutically able carrier, diluent, or excipient, wherein the pharmaceutical or nutraceutical formulation comprises from about 0.05 weight percent (wt%), or 0.5 weight percent (wt%), or 5%, or 25% to about 95 wt% of active or major active ingredients of an extract mixture. In further embodiments, the pharmaceutical or nutraceutical formulation Finlayson Reference No.: 838-1423 comprises from about 0.05 weight percent (wt%) to about 90wt%, about 0.5wt% to about 80wt%, about 0.5wt% to about 75wt%, about 0.5wt% to about 70wt%, about 0.5wt% to about 50wt%, about l.0wt% to about 40wt%, about l.0wt% to about 20wt%, about l.0wt% to about 10wt%, about 3.0wt% to about 9.0wt%, about 5.0 wt% to about 10wt%, about 3.0wt% to about 6wt% of the major active ingredients in an extract mixture, or the like. In any of the aforementioned ations, a composition of this disclosure is formulated as a tablet, hard capsule, softgel capsule, powder, or granule.

Also contemplated herein are agents of the disclosed compounds. Such products may result from, for e, the oxidation, ion, hydrolysis, amidation, esterif1cation, and the like of the administered compound, primarily due to enzymatic processes. Accordingly, contemplated compounds are those produced by a process comprising stering a contemplated compound or composition to a mammal for a period of time sufﬁcient to yield a metabolic product thereof.

Such products are lly identiﬁed by administering a radiolabeled or not radiolabeled compound of this disclosure in a detectable dose to an animal, such as rat, mouse, guinea pig, dog, cat, pig, sheep, horse, monkey, or human, allowing sufﬁcient time for metabolism to occur, and then isolating its conversion products from the urine, blood or other biological samples.

Contemplated compounds, medicinal itions and compositions may comprise or additionally comprise or consist of at least one pharmaceutically or eutically or cosmetically acceptable carrier, diluent or excipient. As used , the phrase "pharmaceutically or nutraceutically or cosmetically acceptable carrier, diluent or excipient" includes any adjuvant, carrier, excipient, glidant, sweetening agent, diluent, vative, dye/colorant, ﬂavor enhancer, surfactant, wetting agent, dispersing agent, suspending agent, stabilizer, isotonic agent, solvent, or emulsiﬁer which has been ed by the United States Food and Drug Administration as being acceptable for use in humans or domestic animals. Contemplated compounds, medicinal compositions and compositions may comprise or additionally se or consist of at least one pharmaceutically or nutraceutically or cosmetically acceptable salt. As used , the phrase aceutically or nutraceutically or cosmetically acceptable salt" includes both acid addition and base addition salts.

Finlayson Reference No.: 838-1423 In some ments, bioactives from the disclosed individual extracts of Alpinia, Piper/Pepper, ia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not d to, AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK), can be ally combined with other RA and 0A management agents, such as non-steroidal anti-inﬂammatory agents/analgesics, COX-2 inhibiting agents including, but not limited to, acetaminophen, ibuprofen, naproxen, n, Diclofenac, Indomethacin, Piroxicam, Ketoprofen, Trolamine salicylate, neuropathic pain relief agents such as Lidocaine, biological agents Methotrexate, 11-1 and TNF-OL odies, herbal and/or plant extracts promoting joint health including but not limited to Cannabis sativa (Hemp Oil) oil or CBD/THC, full spectrum Hemp t, turmeric extract or in, terminalia extract, willow bark extract, s claw root t, Cayenne Pepper extract or capsaicin, Prickly Ash bark extract, Nexrutine or philodendra bark extract, Perluxan or hop extract, 5-Loxin/Apresﬂex or lia and/or Boswellia serrala extract, Moms alba root bark extract, Acacia catechu extract, Scutellarl'a baicalensz's root extract, rose hips extract, rosemary extract, green tea extract, sophora extract, Mentha or Peppermint extract, ginger or black ginger t, green tea or grape seed polyphenols, bakuchiol or Psoralea seed extract, ﬁsh oil, Piascledine or ASU, or dietary supplements that promote joint health, including but not limited to glucosamine compounds such as glucosamine sulfate, glucosamine hydrochloride, N—acetylglucosamine, chondroitin chloride, chondroitin sulfate and methylsulfonylmethane (MSM), hyaluronic acid, UC-II or undenatured and/or denatured collagen, Omega-3 and/or Omega-6 Fatty Acids, Krill oil, Egg Shell ne (ESM), gamma-linolenic acid, Pema Canaliculus (Green-Lipped Mussel — GLM), SAMe, o/soybean nif1able (ASU) extract, citrus bioﬂavonoids, Acerola concentrate, astaxanthin, pycnogenol, vitamin D, vitamin E, vitamin K, vitamin B, vitamin A, L-lysine, calcium, manganese, Zinc, and mineral amino acid chelate(s), boron and boron glycinate, silica, probiotics, Camphor, and Menthol.

Other embodiments of the disclosure relate to methods of use of the disclosed individual extracts of Alpinia, Piper/Pepper, Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with es, but not limited to, AlpiniazPiper/Pepper (AP) and a:Magnolia:Kochia (AMK), in this disclosure, including, but not limited to maintaining catabolic/anabolic biomarker homeostasis. Those catabolic biomarkers are, but not limited to, son nce No.: 838-1423 TNF-OL, IL-lB, IL-6, aggrecanase and matrix metalloproteinase (MMP) such as MMPl3, MlVlP9, MlVlP3, MlVIPl, uCTX-II and 4, and those anabolic biomarkers are but not limited to SOX 9, , ACAN, COLZAl, and PIIANP.

Other ments of the disclosure relate to methods of use of the disclosed individual extracts of Alpinia, Piper/Pepper, Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to, AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK), in this disclosure, including, but not limited to maintaining cartilage homeostasis, inducing cartilage synthesis (and hence, ic effect) and inhibiting the catabolic process of degradation and broken down, protecting extracellular matrix integrity, and joint cartilage, minimizing cartilage degradation, alleviating cartilage breakdown, and initiating and/or promoting and/or enhancing cartilage synthesis, cartilage renewal and cartilage rebuild, repairing damaged cartilage, maintaining, ding and repairing extra ar matrix of joint tissue, revitalizing joints structure, maintaining steady blood ﬂow to joints, promoting health joints by protecting cartilage integrity, balancing anabolic and catabolic processes, maintaining synovial ﬂuid for joint lubrication in a , diminishing the action of enzymes and proinﬂammatory cytokines that affect joint health of a mammal.

Other embodiments of the disclosure relate to methods of use of the disclosed dual extracts of Alpinia, Piper/Pepper, Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to, AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK), in this disclosure, including, but not limited to improving joint movement and/or physical function, ining joint health and mobility into old age, supporting, protecting or promoting joint comfort, alleviating joint pain, reducing joint friction, alleviating joint stiffness, ing joint range of motion and/or ﬂexibility, ing ty, reducing inﬂammation, reducing oxidative stress, reducing and protecting joint wear and tear, managing and/or ng osteoarthritis and/or rheumatoid arthritis, preventing osteoarthritis and/or toid arthritis, or reversing the progression of osteoarthritis and/or rheumatoid arthritis, Preventing and treating juvenile rheumatoid arthritis, Still's disease, psoriatic arthritis, reactive arthritis, septic arthritis, Reiter's syndrome, Behcet's syndrome, or s syndrome or the like of a mammal.

Finlayson Reference No.: 23 EXAMPLES Example 1. Preparation and HPLC Quantification of extracts from Kochia scoparia fruits The dry Kochia scoparia fruits were ground into powder. 20 grams of Kochia scoparia fruit powder were mixed with enough Diatomaceous earth to ﬁll up a 100mL extraction cell, and extracted with 100% Ethanol (EE), 70% Ethanol/water (70E) or 50% Ethanol/water (50E) by using ASE 350 Extractor ction condition: Heat = 5 minutes, Static = 5 minutes, Flush = 80 volume, Purge = 900 s, Cycles = 3, Pressure = 1500 psi, Temperature = 60°C). After extraction, the solution was concentrated with a rotary evaporator at 50°C and high vacuum to e to a solid extract.

The target components, such as Momordin 1c, in the Kochia extracts were quantiﬁed with a Luna C18 reversed-phase column (Phenomenex, 10pm, 250mm x4.6mm) in a Hitachi HPLC system detected at 205 nm wavelength. The column was eluted with a binary gradient of 0.1% Triﬂuoroacelic acid in water (mobile phase A) and acetonitrile (mobile phase B) at 1 ml/min ﬂow rate and 35°C column temperature.

Reference Standard produced according to Example xx was utilized as the quantiﬁcation rd. All s were prepared in MeOH for HPLC analysis with standard in a concentration around 3 mg/ml, and extract samples in a concentration around 10 mg/ml.

Table 1. Gradient Table of HPLC Analytical Method Time (min) Mobile phase A Mobile phase B 0.0 70 30 0 100 23 0 100 23.1 70 30 70 30 Table 2: Extraction and HPLC quantiﬁcation results of Kochia extract Sample ID Extraction solvent Extraction Yield R00577-EE R00577-70E 70% Ethanol/water 22.2% R00577-50E 50% Ethanol/water 19. 1% Finlayson Reference No.: 838-1423 Example 2. Isolation and Puriﬁcation of Momordin lc from Kochia scoparia Ethanol extract (EE, 10 g) from fruits ia scoparia was ioned between organic solvent (100 ml each) and water (150 ml) in the order of Hexane, EtOAC and BuOH to generate Hexane fraction (HE), EtOAC fraction (EA), BuOH fraction (Bu) and water fraction (WA). The compound Momordin 10 was ed in BuOH fraction (1.7 g), the marker nd was increased from 9.7% in extract to 46.2% in BuOH fraction.

Table 3. Inhibition of GAG release of Kochia extract and ons Inhibition of GAG release Sample ID ug/ml 50 ug/ml 100 ug/ml 200 ug/ml R00577-HE R00577-EA R00577-Bu R00577-WA The BuOH fraction (300 mg) was injected into a ative C18 column (21.1 x 250 mm) running at 10 mL/min, the gradient started with 30% Methanol / 0.1% formic acid water, then increased MeOH to 100% over 45 minutes, held at 100% MeOH for additional 15 minutes. The solvent elution run generated 56 fractions, and then those fractions were combined into 20 best pools based on HPLC prof11e detected at 205 nm wavelength. The compound Momordin 10 was isolated in the best pool RP17 (124 mg) and yed activity in the GAG release inhibition assay illustrated in the Example 17.

Example 3. s Development to enrich Momordin lc from Kochia extract Kochia scoparl'a fruit powder (100 g) was reﬂuxed in 500 m1 of 0.25 M NaOH water solution for one hour, then centrifuged at 4000 rpm to collect ﬁrst basic water extract and the Finlayson Reference No.: 838-1423 extraction was repeated under the same conditions once more. The basic water extract solutions were then combined and neutralized to pH 4 with 0.29 M HCl, under which, precipitation in the solution was observed. The precipitate was separated from supernatant through centrifugation at 4000 rpm, then washed with 500 mL water to remove any salty substances and centrifuged again to remove supernatant. The water washing was repeated two more times. Then 500 mL of Ethanol was added to the solid, and the oluble portion was trated and dried under high vacuum to secure 11.8 g solid that contained 14% of Momordin lc.

Kochia extracts R00577-EE (171 mg), R00577-70E (262 mg) and R00577-50E (234 mg) produced according to Example 1, were partitioned between BuOH and water, collected BuOH fraction, removed the solvent with vacuum, and quantiﬁed all three BuOH ons with quantiﬁcation method as described in Example 1. The BuOH on generated from 50% EtOH extract showed the highest Momordin lc content (3 0%).

Kochia scoparia fruits powder from another collection R00782 (520 g) was divided into two ﬂasks in equal amount, 600 ml of 50% Ethanol/water (50E) added to each ﬂask, reﬂuxed for 1 hour, extract collected through ﬁltration, reﬂux repeated two more times. All extracts (about 3 ) were combined, the organic solvent reduced on a rotary-evaporator to the ﬁnal volume of about 600 mL, and then the volume brought to 2 liters by adding more water. The extract was partitioned with BuOH three times, about 750 mL each time. The BuOH fraction was dried with a rotary evaporator under high vacuum to yield 34 g ed BuOH on. The compound Momordin lc was enriched from 4.2% in 50% ethanol extract (50E) to 24.3% in BuOH fraction.

Table 4: HPLC uantiﬁcation results of BuOH fraction from Kochia BuOH fraction BuOH fraction Momordin lc Samp1e ID weight (mg) distribution in extract R00577-70E-Bu 92.8 36% 23% R00577-50E-Bu 48.3 22% 30% Example 4. Preparation of ts from Kochia scoparia in production pilot scale Dried Kochia ia fruits (18 kg) were crushed and extracted with 5 to 10-folds volume of ethanol under 80°C for 1hour, the extraction process was repeated 3 times. After each Finlayson nce No.: 838-1423 extraction, the decoction was ﬁltered, concentrated and dried under vacuum to generate 1.8 kg extract. The extraction yield was about 10% (w/w), and the extract contained 11.8% Momordin lc.

Dried Kochia scoparia fruits powder (35 kg) was extracted with 5 to 10-folds volume of 95% ethanol under 90°C for 1 hour, then the decoction was ﬁltered to receive ﬁrst extract in solution. Added fresh solvent to the biomass and repeated the extraction process 2 more times.

Combined extract in solution from three repeats, trated and dried under vacuum with temperate between 70-85°C. The production process from 35 kg plant powder to extract powder was repeated three times (3 x 35 kg) to produce three batches of extracts with extraction yielded between 13-15%. The dried extract was ground and blended with 25% maltodextrin, then sieved to pass 80 mess to produce a ﬁne powder extract with ﬁnal production yield of 18%. The three s of extract contained 8.4%, 9.1% and 8.6% in lc, respectively.

Example 5. Preparation and HPLC Quantification of extracts from Piper Nigrum fruit Piper nigrum fruit powder (314 g) was divided into two ﬂasks in equal amount, 600 mL organic solvent 50% Methanol in dichloromethane added to each ﬂask, reﬂuxed for 1 hour, extract collected through ﬁltration, reﬂux repeated two more times under same conditions. All t ons were combined, the solvent removed on a rotary-evaporator, and the extract dried under high vacuum to yield 31 g organic t (OE). This OE extract contained 33.7% Piperine by HPLC.

Similar results were obtained using the same procedure, but with the organic solvent being replaced with ol or ethanol to provide a methanol extract (ME) or ethanol extract (EE), l:H20 (7:3) extracts, Ethanol:H20 (1:1) extracts, Ethanol:H20 (3:7) extracts and water extracts respectively The target component, Piperine, in the Piper organic extracts was quantiﬁed with a Luna C18 reversed-phase column (Phenomenex, 10pm, 250mm x4.6mm) in a Hitachi HPLC system at 254 nm. The column was eluted with a binary nt of water (mobile phase A) and Methanol (mobile phase B) at 1 mL/min ﬂow rate and 35°C column temperature. nce Standard Piperine (from Sigma) was utilized as the quantiﬁcation standard. son nce No.: 838-1423 Table 5. nt Table of HPLC Analytical Method for Piperine Time (min) Mobile phase A Mobile phase B Example 6. Preparation of extracts from Piper nigrum in production pilot scale Dried Piper nigrum fruits (10 kg) were crushed and extracted with 5 to 10-folds volume of 70% Ethanol/water under 80°C for 3 hours, ﬁltered to collect extract, extracted again under the same ions for 2 hours. Extracts from both extractions were combined, the t removed with rotary-evaporator and the sample dried under vacuum to generate 100 g 70% ethanol extract (70E). The extract contained 41.9% Piperine by HPLC analysis.

Dried Piper nigrum fruits were crushed and extracted with 90% ethanol in water under 80°C. The solution was concentrated under vacuum until the volume was reduced to less than 20% and sat at room temperature for precipitation. The solids were collected and recrystallized in l and water solution. The standardized 15:1 Piper nigrum extract contains no less than 30% Piperine.

Example 7. Fractionation and Purification of Piperine extract from Piper nigrum The organic extract (10.9 g) of dried Piper nigrum fruits obtained as described in Example was subjected to silica gel column fractionation to pursue GAG releasing inhibition activity. The OE extract was divided and loaded separately onto two pre-packed Biotage ﬂash s (120 g silica, particle size 32-60 p.111, 4 cm x 19 cm), and then eluted with Hexane, EtOAc and Methanol (as the mobile phase) at a ﬂow rate of 20 mL/minutes. The gradients started with 100% Hexane for 5 minutes, then increased EtOAc from 0% to 100% over the duration of 25 minutes, and held at 100% EtOAc for additional ﬁve minutes, then increasing MeOH from 0% to 50% MeOH/EtOAc over next period of 15 minutes, ﬁnally d the elution solution to 100% MeOH and eluted the Finlayson Reference No.: 838-1423 column for r 16 minutes. The total run time was 66 minutes and 88 fractions were generated for each column fractionation. The fractions were analyzed by silica gel thin layer chromatography (TLC) and pooled together to te eight best pools NPl to NP8. The GAG releasing inhibition assay (Example 17) conﬁrmed the highest actiVity was in best pool 4, and it contained 77% of Piperine by HPLC analysis.

Table 6. Inhibition of GAG release of Piper extract and fractions Inhibition of GAG release Sample ID 200 ug/mL OE t _92% \P 2 16% \P 7 52% \P 8 10% Piperine _ Example 8. Preparation and HPLC Quantification of extracts from Alpinia rhizome The dry Alpim'a rhizomes were ground into powder. 20 grams m'a rhizome powder was mixed with enough Diatomaceous earth to ﬁll up a 100mL extraction cell, and extracted with 100% Ethanol (EE) by using ASE 350 tor (Extraction ion: Heat = 5 minutes, Static = minutes, Flush = 80 volume, Purge = 900 seconds, Cycles = 3, Pressure = 1500 psi, Temperature = 60°C). After extraction, the solution was concentrated with an evaporator at 50°C to produce a solid extract.

Finlayson Reference No.: 838-1423 Similar results were obtained using the same procedure, but with the organic solvent being replaced with methanol or ethanol to provide a methanol extract (ME) or Ethanol:H20 (7:3) extracts, Ethanol:H20 (l : l) extracts, Ethanol:H20 (3 :7) ts and water extracts respectively.

The target component l'-acetoxychavicol acetate in extracts were quantiﬁed with a Luna C18 reversed-phase column (Phenomenex, lOum, 250mm x4.6mm) in a Hitachi HPLC system at 254 nm.

Table 7. Gradient Table of HPLC ical Method for l'-acetoxychavicol acetate Time (min) Mobile phase A Mobile phase B 0.0 70 3O The column was eluted with a binary gradient of water (mobile phase A) and itrile (mobile phase B) at 1 ml/min ﬂow rate and 35°C column temperature. Reference Standard 1'- acetoxychavicol acetate purchased from LKT lab contained both l'-acetoxychavicol acetate and p- coumary diacetate peaks with chromatogram purity of 62% and 24%, respectively, was ed as the quantiﬁcation standard. Figure 2 shows a HPLC chromatogram of Alpim'a ethanol extract at 254 nm. a plants were collected from India, China and Thailand from different geological locations and different species. The raw al powders were extracted with EtOH as bed above. The yield for EtOH extraction and HPLC quantification of l'-acetoxychavicol acetate (Marker l) and p-coumary ate (Marker 2) are listed in the table below.

Finlayson Reference No.: 838-1423 Table 8: Extraction and HPLC quantiﬁcation results ofAlpim'a t Extraction Marker 1 Marker 2 Plant Sample ID Latin Name Yield in Extract in Extract Origin R00602-EE Alpim'a aﬁcinarum 5% 1.6% 195% China R00778-EE Alpim'a galanga 046% India R00784-EE a galanga 08% India R00787-EE Alpinia galanga 7% 17% 11% India R00958-EE Alpim'a galanga 1 1% 22% 039% India R00959-EE Alpinia galanga 5% 37% 0~ 8% India R00960-EE Alpim'a aﬁcinarum 0 China L0572-EE Alpim'a aﬁcinarum 16% China L0666-EE Alpim'a galanga 15% 0 0 India L0717-EE Alpim'a a 5% 24% 1.1 1% India L0718-EE Alpim'a galanga 044% India L0719-EE Alpim'a galanga 0 ~ 3 9% India L0720-EE Alpim'a galanga 1 01% India P05797-EE Alpim'a galanga 09% Thailand Example 9. Isolation and ation of active compounds from extract ofAlpinia rhizome Alpim'a galangal rhizome dry powder (170 g) was placed in a ﬂask, 600 ml Ethanol was added to reﬂux for 1 hour, extract collected through ﬁltration, reﬂux repeated two more times. All extract solutions were combined, the solvent removed on a rotary-evaporator, and the extract dried under high vacuum to yield 27 g Ethanol extract (P05797-EE). This ethanol t ned 17% l'-acetoxychavicol acetate by HPLC is. a extract P05797-EE (12 g) was partitioned between organic t (100 ml) and water (150 ml) in the order of Hexane, EtOAc and BuOH to generate Hexane on (4.2 g).

EtOAc fraction (1.2 g), BuOH fraction (0.6 g) and water fraction (5.1 g). The GAG release Finlayson Reference No.: 838-1423 inhibition ty was found in Hexane and EtOAc fractions. Combined both active ons (5.4 g) and loaded onto a pre-packed Biotage ﬂash columns (120 g silica, particle size 32-60 pm, 4 cm x 19 cm), and then eluted with Hexane, EtOAc and ol (as the mobile phase) at a ﬂow rate of 20 utes. The gradients started with 95% Hexane/EtOAc for 5 minutes, then increased EtOAC gradually from 5% to 100% over the duration of 35 s, then held at 100% EtOAc for additional 5 minutes, before increasing MeOH from 0-100% over next period of 15 minutes, f1nally held at 100% MeOH for another 16 minutes. The total run time was 66 minutes and 88 fractions were generated. The fractions were analyzed by silica gel thin layer chromatography (TLC) and pooled together to generate 11 best pools. The best pool NP3 and best pool NP4 contained most of the weight with potent GAG release tion activity.

The silica gel column best pool NP3 (200 mg) was fractionated on a preparative C18 column (21.1 mm x 250 mm) with a linear gradient of 40% Methanol/water to 100% Methanol over 45 minutes at a ﬂow rate of 10 mL/minute to te 45 fractions, and then combined into 12 best pools based on HPLC proﬁle at 254 nm. The best pool RP3 contained the ﬁrst target compound l'-acetoxychavicol acetate (131.4 mg), and the GAG release inhibition activity (Example 17) was ed.

Table 9. Inhibition of GAG release of Alpinia extract and fractions Inhibition of GAG release Sample ID ug/mL 100 ug/mL 200 ug/mL P05797-EE _ 110% 118% P05797-HE 117% P05797-EA P05797-Bu 6% -2.8% NP3 88% 139% l'-acetoxychavicol acetate 99% p-coumaryl diacetate 13 8% The silica gel column best pool NP4 (210 mg) was fractionated on a preparative C18 column (21.1 mm x 250 mm) with a linear gradient of 30% acetonitrile/water to 80% acetonitrile Finlayson Reference No.: 838-1423 over 42 minutes at a ﬂow rate of 10 mL/minute to generate 19 fractions, and then combined into 6 best pools based on HPLC proﬁle at 254 nm. The best pool RP3 contained the second target compound p-coumaryl diacetate (4.3 mg), and the GAG activity was conﬁrmed.

Example 10. Preparation of Et0H extracts from Alpinia rhizome in production scale Dried Alpinia galanga rhizome (40 kg) were crushed and extracted with 5 to 10-folds volume of Ethanol under 80°C for 3 hours, ﬁltered to collect extract, extracted again under the same conditions for 2 hours. Extract solution were combined from both extractions, the solvent removed with -evaporator and the sample dried under vacuum to generate 2 kg ethanol extract (EE). The extract contained about 20% toxychavicol acetate ﬁed by HPLC.

Dried Alpinia galanga rhizome were pulverized and extracted with 95% ethanol. After vacuum concentration and drying, the solid extract was crushed with addition of maltodextrin to e an extract with 6:1 ratio of rhizome:extract. This standardized Alpim'a extract contains 4%-8% compound l'-acetoxychavicol e.

Example 11. Preparation of supercritical C02 fluid t from Alpinia rhizome Alpinia galangal powder (45 g) was placed into a 100 ml stainless steel vessel and pressurized with liquid CO2, heated to extraction temperature of 50°C and then pressurized to extraction pressure of 640 bar before beginning the c ﬂow of supercritical C02. The supercritical CO2 containing extract was depressurized into a collection vial. After 75 min, the soluble components extraction was completed and produced 1.23 g extract with yield of 2.96% (W/W) and 56.7% galangal acetate. After the completion of CO2 extraction 5% /W/W l was added to the supercritical CO2 and the extraction of the same sample was continued at the same conditions oftemperature and pressure to produce 0.15 g extract containing 4.7% galangal e.

Another extraction followed the previous extract protocol but was conducted with supercritical CO2/EtOH 5% W/W from the start of the tion until completion of the experiment (300 min) to generate 1.18 g extraction with yield of 2.58% and 47.3% galangal acetate.

Example 12. HPLC fication ofAlpinia extracts from different sources Finlayson nce No.: 838-1423 Alpim'a extracts were ed from different geological location and vendors in China and India, then l'-acetoxychaVicol e was ﬁed with HPLC method described in Example 8.

The HPLC quantiﬁcation results are shown as table below.

Table 10. HPLC quantiﬁcation results ofAlpim'a extract L0660 -_ 004% ”662 -_ 0 L0667 l% 0.12% L0679 4% 0.51% L0680 0% 0 ”702 075% “”03 075% “”04 072% “”05 043% L0721 l% 0.03% L0722 l% 0.03% L0729 8% 0.40% “”30 041% “”31 041% Example 13. Preparation of 50% extract from Magnolia oﬁ‘icinalis Dried Magnolia lis barks were crushed and extracted with supercritical C02, followed by concentration and vacuum drying. The dried extract was blended with 30% Maltodextrin to produce a powdery of 10:1 extract. The standardized t contains no less than 50% of total amount of Magnolol and Honokiol combined.

The GAG actiVity in 50% Magnolia extract, 30% extract, pure Magnolol and Honokiol were conﬁrmed, the results listed as table below: Table 11. Inhibition of GAG release of Magnolia extracts and compounds Sample ID Inhibition of GAG release son Reference No.: 838-1423 pig/ml 25 ug/mL 50 ug/mL 100 ug/mL Magnolol Honokiol Example 14. Preparation of Alpinia .° Magnolia .° Kochia (AMK) composition Ethanol extract of Kochia seeds (R0083 5-EE, 360 g) was milled into ﬁne powder in a food r, then Magnolia bark extract powder (L0555, 480 g) was added to the same blender and blended to ensure the powder in mity. ard, the blended Kochia and Magnolia t powder was transferred into a deep stainless-steel pan ready to mix with Alpinia extract. The oily Alpinia extract (R00829-EE, 240 g) was weighed out in a beaker, and sonicated in 400 ml MeOH for 1 hour, then the top liquid was transferred into the stainless-steel pan while stirred to mix with Kochia and Alpinia blend. Some remaining solid in beaker was sonicated in more MeOH for an additional 3 times with 100 ml each, and each time, the top liquid was erred to the pan to mix, thus all Alpinia extract was transferred in MeOH to the stainless steel pan to generate a blend of a:Magnolia:Kochia (AMK) in a weight ratio of 2:43 The mixed slurry was dried under vacuum in an oven at 45°C for one week, and then ground in a top herb grinder to secure 1042 g ﬁnd powder. Based on quantiﬁcation results for each ingredient and blending ratio, this AMK composition contained about 4% l'-acetoxychavicol acetate, 22% Magnolol/Honokiol, and 4% Momordin lc.

Another AMK composition in a weight ratio of 5:4:4 was prepared by blending all ents in powder form as described here. Alpinia extract (LO795, 30 g), Magnolia bark extract (L0789, 24 g) and Kochia seeds extract (LO798A, 24 g) were weighed out separately and placed into a food blender to mix to secure a consistent . Based on quantiﬁcation results of each ingredient and blending ratio, this AMK 5:4:4 composition contained about 3% l'- acetoxychavicol acetate, 18% Magnolol/Honokiol, and 3% Mormodin lc.

Individual extracts of Alpinia, and/or Pepper, and/or Magnolia and/or Kochia could be combined to a composition with 3 individual extracts at different ratios including 1:1:1, 21:1, Finlayson Reference No.: 838-1423 3:1:1, 4:1:1, 1:2:1,1:3:1,1:4:1,1:5:1,1:1:2,1:1:3,1:1:4,1:1:5,1:2:3,1:2:4,1:2:5, 1:2:6, 1:2:6, 1:2:8, 1:2:9 or 1:2:10 etc. by weight, respectively.

Example 15. Preparation of Alpinia .° Piper/Pepper (AP) composition Extraction methods and quantiﬁcation of bioactives from Alpinia rhizomes and Pepper fruits have been disclosed in Examples 10,11,12 and 6,7,8, respectively. The Alpinia : Pepper (AP) composition was prepared by weighing Alpinia and pepper extracts in 1: 2 ratio by weight into a vial and added proper solution to sonicate and vortex for homogeneity before each assay.

The composition ned about 7% l'-acetoxychavicol e and 20% ne.

Individual extracts of Alpinia, and Pepper could be combined to a composition at different ratios in a range from about 055 to about 5:05, including 0.5: 1, 05:2, 05:3, 05:4, 055, 1:1, 1:2, 1:3, 1:4, 1:5, 2:1, 2:2, 2:3, 2:4, 2:5, 3:1, 3:2, 3:3, 3:4, 3:5, 4:1, 4:2, 4:3, 4:4, 4:5, 5:1, 5:2, 5:3, 5:4, :5, 1:05, 2:05, 3:05, 4:05, or 5:05 by weight respectively.

Example 16. Preparation of extracts from a, Piper/Pepper, and Magnolia for topical applications Many herbs have been used as anti-inﬂammation and pain control with application orally or topically as alternative medicine. Their pain relief and nﬂammatory properties are associated with a broad range of types of bioactive compounds with potential targeting through different mechanisms and pathways. We are looking for analgesics after preparation and topical application which could penetrate the skin and function where they are needed, ing ids from Piper nigrum, bisphenolic lignans of Magnolia oﬁcinalis and phenylpropanoid Galanga e from Alpinia galanga. Those actives represent different types of chemical constituents and could deliver cological effects through different mechanisms.

Alpinia, Pepper and Magnolia extracts were prepared at a concentration of 50 mg/mL in a combination of DMSO, Propylene glycol, Aloe vera gel (121) or a combination of DMSO, ene glycol and MCT oil (1 : 1 :2) depending on the property and solubility of each material.

Aloe vera gel served a penetration enhancer to improve the skin penetration during topical administration.

Finlayson Reference No.: 838-1423 Example 17. Procedures for testing inhibition of glycosaminoglycan (GAG) release by individual ts, fractions and compounds of a, Piper/Pepper, Magnolia, and Kochia plants Cartilage tissue is primarily composed of extracellular matrix secreted by chondrocytes.

The individual components of the tissue include collagen II ﬁbers, hyaluronic acid and proteoglycans, which are ed of a glycosaminoglycan (GAG), such as chondroitin e or keratin sulfate, bonded to a protein core. Enzymatic breakdown of cartilage tissue leads to free molecules of these components in the extracellular matrix and resorption by the body.

Cartilage Explant Cultures Articular cartilage from hock joints of rabbits (2.5 kg body ) was removed immediately after each animal was sacriﬁced. The articular cartilage ts were obtained by following the method described by Sandy et al, 1986. , after the articular surfaces were exposed surgically under sterile conditions, approximately 200—220 mg articular surfaces per joint were ted and submerged into complete medium (DMEM, supplemented with heat inactivated 5% FBS, penicillin 100 U/ml, streptomycin 100 ug/ml). They were then rinsed several times with the complete medium and incubated for 2 days at 37°C in a humidiﬁed 5% C02/95% air incubator for stabilization. The te medium was replaced with a basal medium (DMEM, supplemented with heat-inactivated 1% PBS, 10 mM HEPES, and penicillin 100 U/ml streptomycin 100 pg/ml). Approximately 30 mg cartilage pieces (2X3><0.35 mm/piece) were placed in 48-well plates and treated with given concentrations of test agents. After pretreatment for 1 h, 5 ng/ml of a was added to the culture medium and further incubated at 37°C in a ﬁed 5% C02/95% air incubator. The culture medium was collected 24 h later and stored at —80°C until assay.

Glycosaminoglycan Measurements The amount of sulphated GAGs in the medium at the end of the reaction, reﬂecting the amount of articular cartilage degradation, was determined through 1,9-dimethy-methylene blue method using commercially available kit (the Blyscan proteoglycan and glycosaminoglycan assay) ing to the instructions of the manufacturer. enac was utilized as a positive control at 300 pg/ml.

Finlayson Reference No.: 838-1423 Example 18. Inhibition of glycosaminoglycan (GAG) release by individual extracts of Alpinia, Piper/Pepper, Magnolia, and Kochia plants Dose curves of Alpinia, Pepper, Magnolia, and Kochia plant extracts were tested on the ex vivo glycosaminoglycan (GAG) release assay as rated in previous example to assess their age protection effects. Cartilage ts were pre-treated with each extract before being exposed to IL-la, which caused degradation and the release of GAGs from the cartilage matrix.

The ability of each extract to reduce GAG release was found to be dose sive, with ICso values as indicated in the table below. Magnolia extract caused the greatest protective , with an ICso of 17.9 ug/mL. Pepper and Kochia extracts showed roughly the same amount of protection from cartilage degradation, with ICso values of 40.8 ug /mL and 42.1 ug /mL, respectively. Of the four extracts tested, Alpinia showed the least protective effect, with an ICso value of 71.6 ug /mL.

All four of the extracts tested protected cartilage from degradation, as demonstrated by this assay.

Table 12. GAG release ICso values for individual extracts of Alpinia, Pepper, Magnolia, and Kochia plants Extracted Plant GAG release ICso (ug/mL) Kochia 42. 1 The inhibition of GAG release ted by the four extracts tested indicates that they inhibit the degradation of cartilage, g that they inhibit cartilage catabolism. We further explored this function by testing the direct tion ofMatrix Metalloproteinases (M1V1Ps) by the ts, and by testing for their effects on transcription of catabolic effectors.

Example 19. Procedures for testing inhibition of Matrix Metalloproteinases (MMPs) by individual extracts of Alpinia, Piper/Pepper, Magnolia, and Kochia plants Individual extracts ofAlpinia, Pepper, Magnolia, and Kochia plants were incubated at 100 ug/mL with Matrix Metalloproteinase-9 (M1V1P-9) or Matrix Metalloproteinase-13 (MMP-13) in 50 mM MOPS, pH 7.2, 10 mM CaClz, 10 uM ZnClz, 1% DMSO, 0.05% Brij 35 with 4.0 uM Mca- Finlayson Reference No.: 838-1423 Pro-Leu-Gly-Leu-Dpa-Ala-Arg-NH2 (hereafter referred to as “substrate”). The substrate exhibits cence and is cleaved by both MMP enzymes, reducing ﬂuorescent . The substrate, each MlVlP enzyme, and each extract were incubated for two hours at 37°C, and the amount of substrate was quantiﬁed spectroﬂuorimetrically. Percent inhibition of each MMP enzyme was calculated for each individual extract as compared to the vehicle control. THVIP-Z was used as a positive control for the inhibition of MlVIPs.

Example 20. Inhibition of Matrix Metalloproteinases (MMPs) by individual extracts of a, Piper/Pepper, Magnolia, and Kochia plants MlVlP enzymes are expressed by chondrocytes in cartilage tissue and play important roles in the degradation of cartilage, as they are catabolic biomarkers for CA disease progression.

Secretion of MMP-l3 by the chondrocytes takes place after cytokine release and sed inﬂammatory ing and leads to degradation of the cartilage through the collagenase activity ofthe enzyme. MMP-9 is a nase enzyme that further breaks down partially digested collagen.

(Gepstein et al, 2002). Direct inhibition of either enzyme, but especially MMP-l3 may reduce their activities and lead to a decline in the lic pathways responsible for cartilage breakdown. 100 ug/mL of each individual extract of Alpinia, Pepper, Magnolia, and Kochia plants was tested for inhibition of MlVIP-9 and MMP-l3 by measuring the amount remaining of a ﬂuorescent substrate after incubation with the test extract. Percent inhibition of each MlVlP by each t is shown in the table below. Piper/Pepper and Magnolia extracts inhibited MMP-l3 by 70% and 68%, respectively, and MlVIP-9 by 44% and 36%, respectively. Alpinia extract inhibited MlVlP-l3 by 38%, but did not signiﬁcantly t MMP-9, as t inhibition was only 3%. Kochia extract moderately inhibited both enzymes with 10% inhibition of l3 and 3% inhibition of MlVIP- 9. Pepper, Magnolia, and Alpinia extracts reduce the activity ofMMPs h direct binding and inhibiting of the WP enzymes. This has important implications for the effects of these individual extracts on the catabolic pathways associated with cartilage degradation.

Table 13. Inhibition of MlVlPS by dual extracts of Alpinia, Pepper, Magnolia, and Kochia t 100 /mL MMP-13% inhibition MMP-9% inhibition __n_ 36 Kochia 10 3 Finlayson Reference No.: 838-1423 e 21. Molecular biological procedures for human chondrocyte treatment with IL-1 and quantification of anabolic and catabolic gene expression ation ofcells Human ocytes (ScienCell, catalog# 4650) were thawed and seeded in a T75 Falcon® Tissue Culture Flask (VWR, g# BD353136) using Chondrocyte Growth Medium (Sigma, catalog# 0). The cells were incubated at 37°C and 5% CO2 for 24 hours, at which point the media was replaced with fresh, 37°C Chondrocyte Growth Medium. Incubation at 37°C/5% C02 continued for an additional 48 hours, or until the chondrocytes became ~90% conﬂuent. The media was aspirated, and cells were rinsed once with 2-4 mL PBS (VWR, catalog# VWRL0119-0500). 2 mL trypsin-EDTA (Sigma, Catalog# T3924-100ML) was added to the ﬂask and left to sit for ~3-5 min or until most of the cells were detached. 8 mL of trypsin inhibitor (Sigma, Catalog# T6414-100ML) was added to the ﬂask to bring the total volume to 10 mL. The cell solution was erred to a 15 mL conical tube and centrifuged for 5 min at 1000 rpm. The supernatant was aspirated, and the chondrocytes were ended in 1 mL Chondrocyte Growth Medium. To count the cells, a 10 pL aliquot of resuspended cells was added to 90 pL trypan blue (VWR, Catalog# 12002-038). 10 pL of this solution was added to a hemocytometer. The cells were then seeded into 24 and 96-well plates (VWR, Catalog# 62406-159, 62406-08) using Chondrocyte Growth Medium from Sigma at a density of ~13,200 cells per cm2 (25,000 cells/well for 24-well plates and 4,200 well for 96-well plates). Chondrocytes were incubated for 24 hours at 37°C/5% C02. The media was aspirated, and the chondrocytes were serum-starved using Chondrocyte Medium, Basal (ScienCell, g# 4651-b). Cells were incubated for 24 hours at % C02.

Pretreatment with IL-1ﬂ 10 ng/mL IL-1B pretreatment was ed using lL-lB (Sigma, Catalog# SRP3083) and ScienCell’s Basal Chondrocyte Medium. 01d media was aspirated and replaced with 500 pL pretreatment solution for the 24-well plates, and 100 pL for the 96-well plates. A few replicates were used as a control and were not pretreated with 10 ng/mL lL-IB. Instead, fresh Basal Finlayson Reference No.: 838-1423 Chondrocyte Medium was added to the cells. The cells were incubated for another 24 hours at 37°C/5% C02.

Treatment ofcells Treatments were prepared using plant extract stored at a concentration of 1M or 50 mg/mL in DMSO and ScienCell’s Basal Chondrocyte Medium. 50 ug/mL Piascledine300 and 100 ng/mL BMP-2 n (Sigma, catalog# SRP6155-10UG) were used as positive controls. All treatments were d using VWR’s Vacuum tion Unit (VWR, catalog# 460), and brought to an IL-lB concentration of 10 ng/mL (with the exception of the untreated control). The vehicle ent consisted only of Basal Chondrocyte Medium and 10 ng/mL IL-lB. Old media was aspirated from each well and replaced with 500 uL treatment for the 24-well plates, and 100 uL for the 96-well plates. All treatments were applied in triplicate. The cells were incubated at 37°C/5% C02 for 72 hours.

RNA Extraction and RT-PCR After 72-hour treatment exposure, media was aspirated from the 24-well plates and the cells were lysed using ’s RNeasy kit (Qiagen, g# 74104) and QIAshredder kit (Qiagen, catalog# 79656). 350 uL RLT buffer with 1% B-Mercaptoethanol was initially added to each well, then the lysate mixture was transferred to a QIAshredder column for completion of the lysing step. The remainder of the RNA extraction procedure was completed according to the manufacturer’s instructions. RT-PCR was performed using SuperScript IV First-Strand Synthesis System (Life Technologies, catalog# 18091200) according to the manufacturer’s instructions. cDNA fication and Dilation cDNA was quantiﬁed using the Qubit ssDNA Assay Kit (Life Technologies, g# Q10212) according to the manufacturer’s instructions. Each cDNA sample was diluted to 2.5 ng/mL with dH20. qPCR The following primers (Life Technologies, catalog# A15612) were diluted to 8 uM in deO: C0l2A1 F: AGACTTGCGTCTACCCCAATC R: GCAGGCGTAGGAAGGTCATC son Reference No.: 838-1423 F: GCCTTTCACCACGAC R: TGCGGGTCAACAGTGCCTATC Sax-9 F: GAGACTTCTGAACGA R: CCGTTCTTCACCGACTTCCT TGFb1 F: GCAAGTGGACATCAACGGGT R: TCCGTGGAGCTGAAGCAATA MMP-3 F: AAGGATACAACAGGGAC R: ATCTTGAGACAGGCGGAACC MMP-13 F: AACGCCAGACAAATGTGACCC R: TCCGCATCAACCTGCTGAGG ADAMTS4 F: GCAACGTCAAGGCTCCTCTT R: CTCCACAAATCTACTCAGTGAAGCA GAPDH F: CAAGGCTGAGAACGGGAAGC R: AGGGGGCAGAGATGATGACC Each qPCR reaction consisted of 400 nM forward primer, 400 nM reverse primer, 1 ng/uL cDNA, and was brought to a total volume of 24 uL with PowerUpTM SYBRTM Green Master Mix (Applied Biosystems, Catalog# A25742). lO uL of each reaction was plated in duplicate on a 96- well reaction plate (Applied Biosystems, catalog# 4366932) and run on the Applied Biosystems StepOnePlus ime PCR System according to the following cycling conditions: 50°C/2 minutes, 95°C/2 s, 40X [95°C/15 seconds - 60°C/l minute].

Cell Viability After 72-hour treatment exposure, 20 uL of CellTiter 96® AQueous One Solution Cell Proliferation Assay (Promega, catalog# G3580) was added to each well in the 96-well plate. 100 uL Basal Chondrocyte Medium was used as a blank. The plate was gently tapped to miX solution, and the chondrocytes were incubated at % C02 for 30 minutes. After incubation, the absorbance of each well was measured at 492 nm.

Finlayson Reference No.: 838-1423 Example 22. Anabolic and Catabolic gene sion in human chondrocytes treated with the extracts of Alpinia, Magnolia, Kochia, Piper/Pepper, and a combination of Alpinia and Pepper ug/mL Magnolia extract ed in signiﬁcant sed expression of catabolic MMP- 3 and MIVIP-l3, with limited and not cant changes in anabolic gene expression. These data te that ia extract works to combat cell degradation by interfering with inﬂated catabolic gene expression in the presence of extracellular lL-lB. Similar to Magnolia extract, at 10 ug/mL Alpinia extract signiﬁcantly reduced MMP-l3 gene expression while signiﬁcantly up regulating SOX-9, ACAN and COL2A1. ed Kochia extract signiﬁcantly upregulated anabolic ACAN, Sox-9, and TGFBI gene expression, while having a lesser effect on downregulation of the lic markers. Pepper extract had a similar effect, causing upregulation of COL2A1, ACAN, SOX-9, and TGFBl, while not signiﬁcantly affecting catabolic markers. The combination of AlpiniazPepper showed marked synergy of MMP-l3 inhibition, while also exhibiting a decrease in 4 and maintaining an increase in TGFBl.

Table 14: Fold changes of the expression of anabolic and lic genes in human ocytes incubated with the extracts of Alpinia, Magnolia and Kochia Fold expression changes relative to vehicle —l—l—I Genes Kochia Magnolia Alpinia Pepper Alpinia: extract extract extract extract Pepper (5 pg/mL) (25 pg/mL) (10 pg/mL) (25 pg/mL) (24 pg/mL) l—l—l—l—l—I COL2A1 -O.36 —0.55* —0.4 0593* -0.12 ACAN 046* —0.24 041* 024* -0.05 sox—9 1.49** —0.44 129* 0.57** 0.35 TGF-Bl 1.98*** —0.59 2.69*** 026* 1.00* MMP-3 -8,979 —131,445** —3,040 4,452 -895 MMP-13 —193 -699* —212* -13 -1,924** ADAMTS4 461 —5.22 _161 -0.23 430* CT values from the qPCR were used to calculate AACT, which was normalized to the untreated control. AACT values were used to calculate the fold expression change of each gene. The values Finlayson Reference No.: 23 in the table indicate the difference in fold expression change between each treatment and the vehicle control. >“P3005, >“"‘P£0.005,*""“P300005, 1 Outlier data.

In summary, Magnolia extract can contribute gulation of catabolic homeostasis, both Kochia and Pepper ts can upregulate gene expression of anabolic pathways of chondrocytes, and Alpinia alone and in combination with Pepper extract can demonstrate both activities.

Example 23. Molecular biological ures for rat chondrocyte treatment with IL-1 and quantification of TGF-Bl gene expression ation s ocytes for monolayer cultures were isolated from knee cartilage of young rats and cultured as follows: Sprague Dawley rats, 3 weeks of age, were euthanized and their hind limbs were collected. Knee cartilage was cut from the subchondral bone using a e scalpel blade.

Cartilage shaVings were ed with collagenase in serum-free Dulbecco’s Modiﬁed Eagle’s Medium (DMEM). Once digested, the cell suspension was centrifuged to obtain a cell pellet. This pellet was resuspended in DMEM containing 10% FBS and the cells were counted. The cells were then plated on tissue culture plastic at a density of 10,000 cells/cmz. The isolated chondrocytes were then ampliﬁed in monolayer in culture medium (DMEM/FCS-10% supplemented with HEPES (25mM)) until passage 1 and frozen at -80°C. Thawed chondrocytes were used in the experiment described.

Chondrocytes were seeded at day-l and cultured in monolayers in 12-well plates for 24 hours. Treatments (including lL-lB) began at day 0 and were performed over 3 days.

The ing 17 treatments or control conditions were carried out: - Untreated cells (cultured in proliferation medium) - IL-lB treated cells -- vehicle - IL-lB treated cells -- BMP-2 (100 ng/mL) - IL-lB treated cells -- Alpinia (25 ug/mL) - IL-lB treated cells -- Pepper (25 ug/mL) - IL-lB treated cells -- Magnolia (25 ug/mL) - IL-lB treated cells -- Kochia (100 ug/mL) - IL-lB treated cells Finlayson Reference No.: 838-1423 All treatments and controls were carried out in cate. Kochia t was found to be non-toxic at 100 ug/mL and was tested at that concentration. The extracts of Alpinia, Pepper, and Magnolia were tested at 25 ug/mL due to cytotoxicity. Chondrocytes were lysed and total RNA was d using the NucleoSpinR RNA 11 kit (Macherey Nagel).

Treatment ofcells Treatments were prepared using plant extract stored at a tration of 100 mg/mL in DMSO and diluted in culture medium. 100 ng/mL BMP-2 protein (RandD Systems, catalog# 355- BM-010) was used as positive control. All treatments were t to an IL-lB concentration of 10 ng/mL (with the exception of the untreated control). The vehicle treatment consisted only of chondrocyte medium, 0.1% DMSO and 10 ng/mL lL-lB. All treatments were applied in triplicate.

The cells were incubated at 37°C/5% C02 for 72 hours.

RNA Extraction and RT-PCR Chondrocytes were lysed and total RNA was puriﬁed using the NucleoSpinR RNA 11 kit rey Nagel). One microgram of total RNA was retro-transcribed using M-MLV RT (Life Technologies). RT-PCR was performed using SuperScript IV First-Strand Synthesis System (Life Technologies, catalog# 18091200) according to the manufacturer’s instructions.

The following primers were used: TGFbl F: CCCCTGGAAAGGGCTCAACAC R: CCAGGTCCTTCCTAAAGTC RPL19 F: TGCCGGAAGAACACCTTG R: GCAGGATCCTCATCCTTCG B—actin F: CCAACCGTGAAAAGATGACC R: ACCAGAGGCATACAGGGACA Each qPCR reaction consisted of 5 uL iQTM SYBR Green ix (Biorad, ref 1708882), 0.6 uL of forward primer (5 uM), 0.6 uL of reverse primer (5 uM), 1.8 uL H20, and 2 uL cDNA (5 ug/HL) Finlayson Reference No.: 838-1423 Example 24. TGF-Bl gene expression in rat chondrocytes treated with the extracts ofAlpinia, Pepper, Magnolia and Kochia in an ndent trial ug/mLMagnolia extract and 100 ug/mL Kochia extract resulted in signiﬁcant increased expression of anabolic TGF-Bl, whereas Alpinia and Pepper extracts did not have a cant effect. In this study, using primary rat chondrocytes, IL-lB was added at the same time as the treatment, and there was no pre-treatment. Under these ions, it’s clear that Magnolia and Kochia extracts contribute to chondrogenesis through upregulation of TGF-Bl, a regulator of chondrogenic gene expression.

Table 15. Fold changes of the expression of anabolic and catabolic genes in human chondrocytes incubated with the extracts of Kochia, Pepper, Magnolia and Alpinia Fold gene expression s relative to e Genes ' Kochia extract Pepper extract Magnolia extract Alpinia extract (100 pg/mL) (25 pg/mL) (25 pg/mL) (25 pg/mL) l—l—l—l—I TGF-Bl 2837* 0.805 * 0.988 CT values from the qPCR were used to calculate AACT, which was normalized to the untreated control. AACT values were used to calculate the fold expression change of each gene. The values in the table indicate the ence in fold expression change between each treatment and the vehicle control. >“P3005, >“"‘P£0.005,**"‘P£0.0005.

In summary, ia extract can contribute downregulation of lic genes in human chondrocytes and upregulation of TGF-Bl in rat chondrocytes, while both a and Kochia extracts can upregulate anabolic gene expression of human chondrocytes while downregulating catabolic genes. Kochia t also showed upregulation of TGF-Bl gene expression in rat chondrocytes, solidifying its role as an anabolic effector in chondrocyte homeostasis.

Example 25. Animals and housing Rats were purchased from a USDA approved vendor. Sprague Dawley rats were purchased at the age of 8 weeks and acclimated upon arrival for a week before being assigned randomly to their respective groups. Rats (3/cage) were housed in polypropylene cages and individually Finlayson Reference No.: 838-1423 identiﬁed by numbers on their tails. Each cage was covered with a wire bar lid and ﬁltered top (Allentown, NJ, USA). Individual cages each had a cage card to indicate the project number, test article, dose level, group, and animal numbers for identiﬁcation. Harlan T7087 soft cob bedding was used and changed at least twice weekly. Animals were provided with fresh water and rodent chow diet # T2018 (Harlan Teklad, 370W, Kent, WA, USA) ad libilum and housed in a temperature-controlled room (222°C) on a 12 h light-dark cycle. All animal experiments were conducted according to the institutional ines congruent with the guide for the care and use of tory animals.

Example 26. Principle of Osteochondral defect (0CD) model Through the years, various in vivo models have been introduced for the treatment of chondral defects. Among these, the microfracture technique is one of the few methods utilized to stimulate the bone marrow in the repairing process by taking advantage of the body’s own healing potential. This technique enhances the al acing by providing a suitable environment for new tissue formation. At the time of model induction, the exposed weight bearing surface of the femur ndral bone plate will be drilled with a precision drill bit until fat droplets and blood come out of the microfractured hole into the knee. This marrow “super clot” provides an optimal environment for the body’s own marrow cells (mesenchymal stem cells) from the bone marrow to differentiate into appropriate articular cartilage-like cell lines that in turn produce the ellular matrix which eventually matures into a stable repaired tissue.

The healing process occurs through a protracted period where post-operative management plays a al role for a quicker and sful recovery. Natural dietary ments for joint care with anabolic activity could in fact assist a faster ry by enhancing the body’s cartilage regeneration s.

In our lab, we developed the modiﬁed microfracture induced injury in vivo model and evaluated AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK) compositions at 200 mg/kg for their anabolic (cartilage sis, renewal, rebuild) activity following a daily oral administration for 6 weeks post-model induction. Piascledine (avocado/soybean unsaponiﬁables) at oral dosage of 200 mg/kg was used as a positive control. Piascledine (avocado/soybean unsaponiﬁables) is a dietary supplement promoted by the manufacturer as an OA disease modulator with lic and anabolic s demonstrated in preclinical in vitro and in vivo Finlayson Reference No.: 838-1423 models. It is reported to possess properties known to prevent cartilage degradation by inhibiting the release and activity of matrix metalloproteinases and by increasing tissue inhibitors of these lic enzymes. Its cartilage repair activity was also suggested as a result of inhibition of inﬂammatory cytokines (Christiansen et al., 2015, Goudarzi et al., 2018) Example 27. 0CD Model induction and dosing The study ed a total of 55 rats divided into 5 groups (N=l l/group). Five additional rats were utilized for drill bit size determination and model optimization. Drill bit sizes of 0.35, 0.6, 0.9, 1.35 and 2 mm were tested, and the 1.35 mm drill bit was chosen. Rats received the respective dosages h the oral route daily for 2 weeks before model induction. Groups included: Gl= Normal control, G2 = OCD model vehicle control, G3 = Piascledine (200 mg/kg), and G4 = AP (200 mg/kg) and G5 = AMK (200 mg/kg).

On the duction treatment start day, average body weight per group was 357.3 :: 16.4 g. Older rats were chosen for this study to minimize the interference of spontaneous recovery. Rats were gavaged daily with freshly prepared respective material suspended at 10 ml/kg per rat for 2 weeks before induction. Samples in solution were vortexed between animals to maintain the homogeneity of test materials. Following a baseline measurement for weight (368.7 :: 4.4 g), on the induction day, a small incision was made on the left hind knee of ane-sedated rats and the subchondral bone on the weight bearing surface of the femur was exposed. A drill bit (1.35 mm) was then used to carefully induce a modified microfracture drill hole using a ﬁnger spin on the exposed surface until blood was e as an indication for the adequate penetration of the bone marrow for all the groups except for the rats in the normal control group, which followed the same surgical procedure without the drilling. The joint capsule and the skin were sutured using a 4-0 coated vicryl absorbable suture and the s were placed back in their cages to r from anesthesia.

Table 16. Study groups of the Osteochondral defect model (OCD) Dose (mg/kg) Control + e 11 0 OCD+ vehicle 11 0 Finlayson Reference No.: 838-1423 OCD + Piascledine 11 200 OCD + AP 11 200 After induction, oral treatments were continued for 6 weeks. Rats were monitored for pain sensitivity using the citance meter for weight bearing measurements at week 6. At the end of the study, serum was ted for biomarker analysis. At necropsy, the femorotibial joint was ted out, coded in a double blind way, preserved with formalin and sent to wide Histology for histopathology analysis of the affected structure. Photos of the joint tissues were taken for each rat for all groups. Histopathology analysis was carried out on blinded tissues by a third-party certifled pathologist as the end point measurement for this study Example 28. Weight hearing as a e of pain sensitivity in 0CD model The incapacitance tester was used to measure the weight bearing for OCD rats treated with AlpiniazPiper/Pepper (AP) and AlpiniazMagnoliazKochia (AMK) compositions produced in example 14 and 15 against vehicle and positive controls. In this method, rats shift their body weight to the normal (unaffected) leg to relieve the pain d by weight to the surgical leg. In the current study, rats were expected to put more weight on the right leg. As the healing progressed, the weight distribution could have changed to reﬂect the homeostasis of “arthritis” in terms of the speed of healing and the tolerance of pain for each leg. Surgery was performed on the left leg of each rat in all the groups. All the rats received drilling on the left leg except the normal control (NC) group which underwent the same surgery procedure without the drilling.

Table 17. Weight bearing as a measure of pain sensitivity for OCD rats treated with AMK and AP compositions against vehicle and positive controls Weight Bearing ence % P-values vs (R-L) Improvement e compared to d Vehicle 0CD 84.0 0.001 Finlayson Reference No.: 23 Vehicle 11 108.5:223.9 240.6 39.3 - - Piascledine AP 200 11 117.1::15.4 157.1::13.5 40.0::16.9 51.5 0.006 As seen in table 17, rats shifted their body weight to the contralateral paw (normal right leg without surgery) to relieve the pain. As time went by, rats progressively started to put more weight on the left leg, making the right leg carry less weight. In week 6, there was statistically signiﬁcant weight distribution between the right and left legs of rats treated with AlpiniazPiper/Pepper (AP) and azMagnoliazKochia (AMK) compositions compared to the vehicle group, which still heavily favored their right leg. When compared to the vehicle treated group, rats treated with AMK and AP compositions showed a 59.9% and 51.5% improvement in weight bearing, respectively. Compared to the normal control rats, vehicle treated OCD rats put on 6-fold increased weight on the right leg. The positive control, Piascledine showed 45.6% improvement.

Example 29. Histopathology analysis for cartilage regeneration markers in the 0CD model Hematoxylin and Eosin (HE) and in 0 green staining were carried out according to Nationwide Histology’ s protocols. Induction of the model was conﬁrmed by visual observation of a drill hole on the knee (Figure 3). This was also later conﬁrmed by the histopathology s showing the normal appearance and scores that were given for the tissue evaluations. Each specimen underwent 3 sections for HE and an additional 3 sections for the Safranin O stain with identical orientation for each block aiming to pass through the drilled hole. It is stated that the more comprehensive quantitative histological scoring system (such as Sellers method) could yield a higher power of mination between different degrees of cartilage repair, resulting in enhanced sensitivity and city in the pathophysiological condition of articular cartilage repair. As such, we suggested to the pathologist to adapt the s evaluation method for this study and tabulated the data as seen in Tables 18 and 19.

As seen in Table 19 and Figures 3 and 4, rats d with AP ition showed statistically signiﬁcant improvements in: l. ﬁlling ofthe defect relative to the surface ofthe normal Finlayson Reference No.: 838-1423 adjacent age, 2. integration of repaired tissue with the surrounding articular age, 3. matrix staining, and 4. cellular morphology compared to the e treated group. These improvements were found to be48.9%, 73.5%, 28.7% and 50.5% when compared to vehicle treated disease model rats, respectively. A strong trend of signiﬁcance was also observed for the architecture of the e and formation of tidemarks with 37.7% (p=0.07) and 32.3% (p=0.07), respectively, when compared to the vehicle group. Similarly, rats treated with AMK composition showed statistically signiﬁcant ement of: 1. integration of repair tissue with surrounding articular cartilage, 2. matrix ng with Safranin O-fast green, 3. cellular morphology, 4. architecture ofthe surface and formation oftidemarks compared to the vehicle treated group. These improvements were found to be 62.5%, 33.0%, 47.9%, 44.3% and 43.2% when compared to e treated disease model rats, respectively. On the other hand, the positive control, Piascledine, showed statistically signiﬁcant improvement in integration of repair tissue with surrounding articular cartilage (62.5% improvement vs vehicle treated OCD model) and architecture of surface (35.7% improvement vs e treated OCD model) when compared to the vehicle-treated e model. Figure 3 shows images of a drill site of OCD rats after 6 weeks of treatment showing signiﬁcant differences in healing progress from different oral treatment groups.

The histopathological results clearly demonstrated the anabolic changes to damaged joint cartilage and improved ural integrity of the joint after oral treatment of OCD rats with AlpiniazPepper (AP) and Alpinia:Magnolia:Kochia (AMK) itions. Natural dietary supplements exampled by, but not limited to, AP and AMK compositions increased anabolic activity by regulating homeostasis of chondrocytes, extracellular matrix, lar cartilage, and phenotype ofj oint. These supplements could, in fact, assist in faster recovery of damaged age and improved joint structure ity by enhancing the body’s cartilage regeneration process. The speciﬁc regeneration, renewal, rebuilding and regrowth functions are associated with, but not limited to, ﬁlling of the defect relative to the surface ofnormal adjacent cartilage, integrating repair tissue with surrounding articular age, regenerating extra cellular matrix, improving cellular morphology, renewing architecture within the entire defect, regenerating architecture of surface, increasing percentage of new subchondral bone, and enhancing formation of tidemarks. Figure 4 shows in O stain of the subchondral bone of OCD rats at the drill site. The black circle indicates the drill site for representative animal histopathology slides.

Finlayson Reference No.: 838-1423 Table 18. Sellers cartilage regeneration parameters from treatment groups Sellers cartilage regeneration ters Group N A B c D E F G H (mg/kg) l 0 10 0 :: 0 0 :: 0 0 :: 0 0 :: 0 0 :: 0 0.09:0.29 0.09:0.29 0.27:0.45 Vehicle 0 10 1.60::1.02 2.40::1.02 3.70:0.46 4.22::0.63 1.80::1.25 2.33:0.94 2.80::1.54 3.22:1.03 Piascledine 200 10 1.40::0.70 0.90::0.57 3.90:0.32 4.40::0.70 1.40::0.70 1.50::0.71 2.30:0.82 3.00:0.94 AMK 200 10 1.10::0.99 0.90::0.88 2.48::1.71 2.20::1.75 1.03:0.95 1.30:1.06 1.73:1.32 1.83:1.38 AP 200 10 0.82::0.58 0.64::0.98 2.64::1.23 2.09::1.62 1.00::0.74 1.45::0.99 1.73:1.21 2.18:1.19 es vs Vehicle treated OCD model A B C D E F G H Grou (m k ) N Control 0 10 - - - - - 0.000 0.000 0.000 Piascledine 200 10 0.628 0.001 0.288 0.579 0.449 0.049 0.396 0.640 AMK 200 10 0.295 0.003 0.044 0.005 0.151 0.044 0.123 0.027 AP 200 10 0.051 0.001 0.024 0.002 0.102 0.071 0.106 0.066 B- Filling of the defect relative to surface of normal adjacent age, C- Integration of repair tissue with surrounding articular cartilage, D- Matrix staining with in O-fast green, D- Cellular morphology, E- Architecture within entire defect, F- Architecture of surface, G- Percentage of new subchondral bone, H- Formation of rk.

Table 19: Cartilage Repair Score According to Sellers method of histopathology analys1s A B C D E F G H Filling fo Integration the defect Architecture. relative. of repair Cellular _ _ _ tage Within entire _ _ _ _ tissue With Matrix morphology ( Architecture of new Formation. of to surface _ _ _ defect (not surrounding subchondral . staining a-b-c-d / 0 thru ace tidemark ofnormal _ _ _ including articular bone _ 5) adjacent _ _ margins) . cartilage cartilage lll%— Normal Normal 0% Normal 0 125% =1 continuity (a) Normal 0 Normal 0 = 0 =0 Complete :0 Finlayson Reference No.: 838-1423 integration (b) Mostly Slight Decreased round cells 75%—99% =1 91Vo— Slightly 1—3 small fibrillation or 75%—89% cellularity with the 50%—74% =2 110% =0 reduced =1 voids = 1 irregularity =1 =1 morphology of 25%—49% =3 chondrocytes < 25% =4 Gap or lack > 75% of tissue 76Vo— of continuity Moderately With columns 1—3 large 50%—74% 50%—74% =2 90% =1 on one side reduced =2 in radial zone voids = =2 =2 =0 Gap or lack 25%—75% of Severe 51Vo— of continuity Substantially tissue With > 3 large fibrillation or 25%—49% 75% =2 on two sides reduced =3 s in voids = disruption =3 =3 radial zone =1 =3 < 25% of tissue With columns Clefts or 26Vo— None =4 in radial zone fibrillations = < 25% =4 50% =3 ganized) 4 (c) 50% round cells With the < 25% morphology chondrocytes = > 75% of tissue With columns in radial zone = %—75% of tissue With columns in radial zone = 3 < 25% of tissue With columns in radial zone = (disorganized) d) Mostly spindle-shape (fibroblastlike ) cells = 5 Orth P, Zurakowski D, ringer D, Madry H. Reliability, reproducibility, and validation ofﬁve major histological scoring s for mental articular cartilage repair in the rabbit model. Tissue Eng Part C Methods. 2012 May,18(5):329-39.

Finlayson Reference No.: 838-1423 Example 30. Accelerated healing as measured by Sellers age regeneration histopathology analysis method for tissues from the 0CD model We also analyzed data from the histopathology by summing up the overall parameter s observed in the healing process from A to H. It was found that when rats were treated with AlpiniazPepper (AP) and Alpinia:Magnolia:Kochia (AMK) compositions (Example 14 and ) daily at 200 mg/kg for 6 weeks, there was 40.5% and 40.4% increase in healing than OCD rats in the vehicle treated group, respectively (Table 20). As seen in this data summary, it is clearly evident that the OCD model was induced and cant ement in healing (and hence cartilage repair, ration, renewal, rebuilding) was observed as a result of the AMK and AP oral treatment. For comparison, the Piascledine group showed only a 10.9% faster healing s compared to the vehicle-treated OCD rats.

Table 20. Accelerated healing of cartilage according to Sellers histopathology analysis P-value vs Sellers cartilage P-value vs e, % , , regeneration Vehicle Group N d accelerated overall value treated 0CD hea in1' g (A to H) 0CD model model Control 0.46 :: 0.89 0.0000 97.8 0.0000 Vehicle 21.10 :: 4.32 Piascledine 18.80 :: 4.24 0.258 10.9 0.258 AMK 12.57 :: 8.81 0.014 40.4 0.014 AP 12.55 :: 7.24 0.006 40.5 0.006 Example 31. TGF-Bl as an anabolic regulator of Cartilage sis in 0CD rats For biomarker analysis of OCD study illustrated in examples —27-29, cardiac blood was collected for each animal at necropsy. Blood was spun at 3000 rpm for 15 min. About 700-800 p1 of serum was isolated from each rat. Samples were kept at -80°C until use. The presence of TGF- [31 in rat serum was measured using the Rat TGF-Bl Quantikine ELISA kit from RandD Systems Finlayson Reference No.: 838-1423 (product#: MBlOOB) as follows: Latent TGF-Bl in serum was activated with l N HCl, then neutralized with 1.2 N NaOH/O.5 M HEPES. ted serum was diluted 60-fold and added to a microplate coated with TGF-Bl antibody (ﬁnal dilution factor of serum is 90). After 2 hours at room temperature, TGF-Bl in serum was bound to the plate and the plate was ghly washed. -conjugated TGF-Bl antibody was added to the plate and allowed to bind for 2 hours at room temperature. The washing was repeated, and enzyme substrate was added to the plate. After developing for 30 minutes at room temperature, a stop solution was added, and the absorbance was read at 450 nm. The concentration of TGF-Bl was calculated based on the absorbance readings of a TGF-Bl standard curve.

As seen in Table 21, below, there was a statistically signiﬁcant increase in the serum level of TGF-Bl in the AP-treated group compared either to the vehicle-treated OCD model or normal control rats. These increases were found to be 19.5% and 17.1% for AP composition and 9.5% and 7.3% for AMK composition ve to the normal l and the vehicle-treated OCD group, respectively. The TGF- [31 increase in the AMK-treated group was not signiﬁcant compared to the e-treated group.

Table 21. TGF-Bl as an anabolic regulator of Cartilage synthesis in OCD rats treated with AlpiniazPepper (AP) and AlpiniazMagnoliazKochia (AMK) compositions Group Control Vehicle Piascledine AP . 19.5 0.02 son Reference No.: 838-1423 Among the anabolic biomarkers, one of the most relevant indicators of cartilage synthesis, TGF-Bl, was found ed in the AP and AMK composition-treated rats to the point where the increase was statistically signiﬁcant compared to vehicle treated OCD rats for the AP group.

Signiﬁcant published data support the fact that this anabolic factor is known to be involved in the maintenance of age homeostasis and to stimulate cartilage repair processes by ocytes.

While the level of TGF-Bl is high in healthy cartilage, its sion is low in patients with CA.

In experimental animals with arthritis, the injection of TGF- [31 into the knee increased the level of proteoglycan while protecting against cartilage loss in others, suggesting its importance in ding and homeostasis of the extracellular matrix components of the articular cartilage (van Beuningen er al., 1994, Verdier el al., 2003, Glansbeek el al., 1998). Therefore, these noticeable changes observed in our study demonstrated tipping the balance to the anabolic direction by either AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK) composition that could be ated with regulating homeostasis of chondrocytes, extracellular matrix, articular cartilage, and phenotype of a damaged joint with treatment effect much faster than the neous ry observed for the vehicle-treated OCD group.

Example 32. Symptom relief function of individual Alpinia, Pepper, Magnolia and Kochia extracts in carrageenan-induced paw edema model Carrageenan-induced paw edema in rats was used to evaluate the anti-inﬂammatory and ain activities of individual Alpinia, Pepper, Magnolia and Kochia extracts. Sprague Dawley (SD) rats (N=5 per group) were given Alpinia, , Magnolia and Kochia extracts at 300 mg/kg orally one hour after intra-plantar injection of 100 pl carrageenan. Pain ivity and paw edema were monitored at T0 (before carrageenan) and 2, 4 and 6 hours after carrageenan. Ibuprofen as a positive control was used at 150 mg/kg. As seen in Table 22 below, ranges of percent reductions, such as 26.1-37.3%, 7.5-33.2%, l-l4.7% and l7.9-32.3% in paw edema and 21.2-33.8%, 15.3- 27.1%, 18-26.3% and 23.2-33.2% in pain sensitivity were observed for rats treated with the extracts from Alpinia, Magnolia, Kochia and Pepper, respectively. Except for in paw edema measurements 5 hr after Kochia, all ent groups showed statistically signiﬁcant reductions of pain and inﬂammation.

Finlayson Reference No.: 838-1423 Table 22. Decrease of paw edema and reduction of pain sensitivity of carrageenan rats treated with AlpiniazPiper/Pepper (AP) and Alpinia:Magnolia:Kochia (AMK) compositions Average SD % change of vehicle Group 1hr 3hr 5hr 1hr 3hr 5hr 1hr 3hr 5hr Paw edema Vehicle 2.51 3.08 2.80 0.19 0.16 0.08 - - - Ibuprofen 1.43 1.59 1.77 0.40 0.30 0.37 43.03 48.38 36.79 Alpinia Galanga 1.69 1.93 2.07 0.11 0.32 0.20 32.67 37.34 26.07 Magnolia aﬁcinalis 1.99 2.06 2.59 0.33 0.45 0.60 20.88 33.18 7.50 Kochia Scoparz'a 2.14 2.64 2.78 0.26 0.23 0.33 14.74 14.16 0.71 Pepper Nigzum 1.70 2.13 2.30 0.23 0.51 0.56 32.27 30.84 17.86 Pain sensitiviQ Vehicle 46.75 65.87 68.45 2.57 2.25 2.56 - - - Ibuprofen 25.02 35.67 45.49 3.49 3.42 4.28 46.49 45.85 33.55 Alpinia Galanga 30.95 44.02 53.93 2.11 2.58 3.19 33.79 33.17 21.21 Magnolia lis 36.73 48.05 58.01 1.34 2.74 3.53 21.43 27.05 15.25 Kochia Scoparia 34.75 48.53 56.16 3.77 4.45 2.91 25.67 26.33 17.96 Pegger Nigzum 31.22 44.37 52.55 4.10 6.53 7.45 33.22 32.64 23.24 e 33. Lead composition-finding study on eenan—induced paw edema model Carrageenan-induced paw edema model was used to evaluate the anti-inﬂammatory and antipain activities of natural compositions that were combinations of individual plant ts from Alpinia and Magnolia at blending ratios of 1:1 (150:150 mg/kg), 1:2 (100:200 mg/kg), 2:1 (200:100 mg/kg), 1:4 (60:240 mg/kg) and 4:1 (240:60 . Rats were administered with the compositions at the same dosage of 300 mg/kg orally. As seen in Table 23 below, signiﬁcant inhibition in pain and inﬂammation was ed for all the ratios tested for these medicinal plant Finlayson Reference No.: 838-1423 combinations. Slightly higher inhibition relative to the other ratios was found when rats were treated with a ratio of 1:2 azMagnolia. Alpinia and Magnolia combination at 1:2 ratio showed 36.7%, 33.3% and 29.3% in pain reduction and 37.2%, 34.5% and 29.3% in ion of inﬂammation at 1h, 3hrs and 5hrs after treatment, respectively, when compared to the vehicle- treated disease model. In this study, we ob served that combining these two nal plant extracts at this c ratio produced higher inhibition of pain and inﬂammation (in the ﬁrst hours and at 5hr after treatment) when compared to each individual plant administered at the same dosage (compared to data from example 32 above). As a result, we selected the composition as example, but not limited to, 1:2 ratio of Alpinia with Magnolia for more subsequent studies.

Table 23. Anti-pain and anti-inﬂammatory activity of various ratios of Alpinia lia extracts Anti-pain nflammation ts Ratio Percent " Percent change" 1hr 3hr 5hr 1hr 3hr 5hr Ibuprofen 150 1 50.51 46.37 37.42 49.50 48.62 37.66 Alpinia to magnolia 300 1 to 1 29.26 34.41 21.04 28.15 28.40 25.04 Alpinia to ia 300 1to 2 36.71 33.30 29.27 37.20 34.53 29.31 Alpinia to magnolia 300 2 to 1 33.52 34.38 25.52 32.53 31.60 25.99 Alpinia to magnolia 300 4 to 1 27.76 30.30 24.28 23.55 27.02 19.66 Alpinia to magnolia 300 1to 4 15.22 16.90 11.68 12.52 15.86 15.04 *P S 0.05 compared to vehicle Example 34. Anti-pain and Anti-inﬂammatory activities of combinations ofAlpinia galanga and Kochia scoparia in the carrageenan-induced paw edema model Carrageenan-induced paw edema model was used to evaluate the anti-inﬂammatory and antipain activities of Alpinia and Kochia extracts, which were combined at 1:1 (150: 150 mg/kg), 1:2 (100:200 mg/kg), 2:1 (200:100 mg/kg), 1:4 (60:240 mg/kg) and 4:1 (240:60 mg/kg) ratios. Rats were administered with the compositions at 300 mg/kg orally in total. As seen in Table 24 below, signiﬁcant inhibition in pain and inﬂammation was observed for all the ratios tested for these Finlayson Reference No.: 838-1423 medicinal plants. A slightly higher inhibition relative to the other ratios was found when rats were tested with a 1:1 Alpinia to Kochia ratio followed by 4:1 Alpinia to Kochia ratio. Alpinia and Kochia extract’s combination at 1:1 ratio showed 25.0%, 27.6% and 25.7% in pain reduction and 26.4%, 30.9% and 30.6% in reduction of inﬂammation at 1h, 3hrs and 5hrs after ent, respectively, when compared to vehicle-treated disease model. Similarly, the Alpinia and Kochia extract combination at 4:1 ratio showed 20.4%, 26.9% and 26.3% in pain reduction and 24.1%, .7% and 29.1% in reduction of inﬂammation at 1h, 3hrs and 5hrs after treatment, respectively, when compared to the vehicle-treated e model.

Table 24. Anti-pain and anti-inﬂammatory activity of various ratios of Alpinia and Kochia extracts Anti-pain Anti-inflammation Extracts Ratio Percent change" t change" (mg/kg) 1hr 3hr 5hr 1hr 3hr 5hr Ibuprofen 100 1 50.51 46.37 37.42 50.07 47.40 37.28 Alpinia to Kochia 300 1 to 1 24.96 27.56 25.72 26.36 30.88 30.55 Alpinia to Kochia 300 1 to 2 21.70 23.25 24.63 26.50 29.86 29.66 Alpinia to Kochia 300 2to 1 12.19 21.26 14.40 11.75 20.31 10.90 Alpinia to Kochia 300 1to 4 13.08 18.21 21.49 13.71 22.00 23.41 Alpinia to Kochia 300 4 to 1 20.36 26.92 26.27 24.13 30.66 29.06 *P S 0.05 compared to vehicle Example 35. m relief effects of composition AMK (Alpinia, Magnolia and Kochia) We trate in this example, but not d to it, that adding a third component to an AlpiniazMagnolia composition further increased the efficacy of the composition. The Kochia scoparia extract with both anabolic and catabolic modulation activities on chondrocytes as demonstrated in examples 22 and 24 was ed as a third component and evaluated in the carrageenan induced rat paw edema model as shown in the next e. Carrageenan-induced paw edema was used here again for the tion of AM (1 :2) blended with Kochia at 4:1, 2:1 son Reference No.: 838-1423 and 1:1 ratios with a ﬁnal dosage of 300 mg/kg. While the addition of Kochia seemed to boost the efﬁcacy of AM in all the ratios, there was a statistically signiﬁcant increase in anti-pain and anti- inﬁammation activity when Kochia was added at a 2:1 ratio to AM (i.e. 2A:4M:3K). There was 40.8, 45.2 and 33.1% reduction in pain and a 42.1, 37.8 and 36.0% reductions in inﬂammation at 1h, 3hrs and 5hrs after treatment, respectively, when compared to the vehicle-treated disease model. These inhibitions were higher than for dual extracts and the Alpinia and Magnolia combination. At this , the ﬁnal ratio for the most effective composition was determined as 2A:4M:3K.

Table 25. Anti-pain and anti-inﬂammatory activity of various ratios of AM and Kochia Anti-pain Anti-inflammation Extracts (HIE/leg) Ratio Percent change" Percent change" 1hr 3hr 5hr 1hr 3hr 5hr Ibuprofen 150 1 44.4 47.9 30.8 47.3 49.7 37.6 AMtoK 300 4to 1 34.6 42.5 27.5 36.7 40.3 34.2 AMtoK 300 2to 1 40.8 45.2 33.1 42.1 37.8 36.0 AMtoK 300 1to 1 21.9 36.9 22.9 34.8 33.4 24.5 *P S 0.05 compared to vehicle Example 36. Synergistic ty of AlpiniazMagnoliazKochia (AMK) composition in reducing pain and inflammation in carrageenan-induced rat paw edema model The merit of combining Alpinia, Magnolia and Kochia for AMK (2:4:3 ratio, respectively) was further demonstrated in this e on the carrageenan rat paw edema model. Rats were gavaged with each constituent as they appeared in the 300 mg/kg of the AMK individually in order to determine whether the plant extracts acted synergistically. For the 2:4:3 ratio of AMK, rats were administered with 67 mg/kg of Alpinia extract, 133mg/kg of Magnolia extract and 100mg/kg of Kochia extract. The percent inhibition of pain and inﬂammation of the combined itions at 300 mg/kg were compared with those dosages of individual extracts to ﬁnd out potential additive, nistic or synergistic effects in combination using the Colby’s equation.

Finlayson Reference No.: 838-1423 Table 26: Synergistic activity of combination of Alpinia, Magnolia and Kochia extracts in reducing pain and inﬂammation in carrageenan induced rat paw edema model 1hr 3hr 5hr 67 17.8 13.8 10.5 n 133 22.6 17.2 12.2 . . 54.8 45.7 30.3 . . . 45.5 39.1 27.4 45.0 m 28.6 Colby's synergy equation for Expected = A-C+B For the blending of these plant extracts to have unexpected synergy, the observed inhibitions needed to be greater than the calculated expected value. As seen in Table 26, the observed efﬁcacies were, in fact, greater than the expected values at each time point red, suggesting synergy among these medicinal plant extracts in reducing pain and ation.

Though previously reported studies ted the potential anti-inﬂammatory activity of these herbs, none of them were put together in the standardized blend presented in this patent with the depicted potency.

Example 37. AP composition-ﬁnding study using the carrageenan-induced paw edema model Carrageenan-induced paw edema model was used to te the anti-inﬂammatory and antipain activities of Alpinia and Piper/Pepper extracts which were combined at 1:1 (150:150 mg/kg), 1:2 (100:200 , 2:1 (200:100 mg/kg), 1:4 (60:240 mg/kg) and 4:1 (240:60 mg/kg) ratios.

Rats were administered with the compositions at 300 mg/kg orally in total. As seen in Table 27, below, signiﬁcant tion in pain and inﬂammation was observed for all the ratios tested for Finlayson Reference No.: 838-1423 these nal plants. Slightly higher inhibition, relative to the other ratios, was found when rats were tested with a 1:2 Alpinia to Piper/Pepper ratio. Alpinia and Piper/Pepper extracts combined at a 1:2 ratio showed 42.4%, 44.3% and 34.7% pain ion and 39.2%, 43.4% and 33.7% reduction of ation at 1h, 3hrs and 5hrs after treatment, respectively, when compared to vehicle-treated disease model. This composition was selected for dose-response and synergy studies.

Table 27. Anti-pain and nﬂammatory activities of various ratios of Alpinia and Pepper Anti-pain nflammation Extracts Ratio Percent change" Percent change" (mg/kg) 1hr 3hr 5hr 1hr 3hr 5hr Ibuprofen 100 1 48.44 47.46 37.77 45.00 50.31 41.84 Alpinia to Pepper 300 1to 1 31.44 38.21 24.19 33.31 33.75 22.86 Alpinia to Pepper 300 1 to 2 42.36 44.33 34.70 39.23 43.44 33.67 a to Pepper 300 2to 1 33.25 35.42 21.67 27.69 18.31 11.16 Alpinia to Pepper 300 1to 4 33.25 33.93 31.27 31.23 34.63 25.17 Alpinia to Pepper 300 4 to 1 35.40 37.25 23.73 25.08 29.25 21.77 *P S 0.05 compared to vehicle Example 38. Dose-response study of selected AP compositions ition AP was selected as the lead composition from previous in vivo experiments due to its inhibition of inﬂammation and pain at the 1:2 ratio, when administered orally to rats at 300 mg/kg. Here, we evaluated the dose-response effect of this ation in carrageenan - induced rat paw edema model administered at 100, 200 and 300 mg/kg. As seen in Table 28, below, dose-correlated inhibition ofinﬂammation and pain was observed for the composition. The highest anti-inﬂammatory activities were observed at the 300 mg/kg for the composition followed by the 200 mg/kg and 100 mg/kg. Inhibition of 42.8%, 43.5% and 32.0% of inﬂammation and 44.8%, 44.4% and 34.7% of pain was observed at 1hr, 3hr and 5hrs after treatment, respectively Finlayson Reference No.: 838-1423 Table 28. Dose response in anti-pain and anti-inﬂammation activity of composition AP Anti-pain Anti-inﬂammation Extracts Ratio Percent change* Percent change" (mg/kg) 1hr 3hr 5hr 1hr 3hr 5hr Ibuprofen 100 1 50.5 46.1 38.5 51.0 48.0 39.0 Alpinia to Pepper 100 1to 2 10.7 18.0 13.1 26.2 14.2 11.0 a to Pepper 200 1 to 2 29.3 33.7 27.8 37.9 27.1 25.1 Alpinia to Pepper 300 1 to 2 44.8 44.4 34.7 42.8 43.5 32.0 *P S 0.05 compared to vehicle Example 39. y determination of lead extracts in composition AP The merit of combining Alpinia with Pepper for AP (1:2 ratio) was ted in the carrageenan rat paw edema model. Rats were gavaged with each constituent as they appeared in 300 mg/kg of the AP. For the 1:2 ratio of AP, 100 mg/kg of Alpinia and 200 mg/kg of Pepper extract were administered to the rats. The percent inhibition of pain and inﬂammation of the compositions at 300 mg/kg was compared with those s of individual extracts to ﬁnd out potential additive, antagonistic or synergistic effects in combination using Colby’s equation (Colby 1967). For the ng of these plant extracts to have unexpected synergy, the observed inhibition needed to be greater than the calculated value.

Table 29. Unexpected synergistic activities of Alpinia and Pepper in 1A2P combination (1113;;) 100 1A (X) 16.4 15. 34 2115 1163 Finlayson Reference No.: 838-1423 Observed 42.81 43.52 31.96 44.82 44.40 34.73 Colby's synergy equation for Expected:( X+Y)—XY/100 As seen in Table 29, the observed efﬁcacies were in fact greater than the expected values at each time point red, suggesting the unexpected synergistic activities of these plant extracts in reducing pain and inﬂammation.

Example 40. Stimulation of age synthesis and inhibition of cartilage degradation by composition AlpiniazMagnoliazKochia (AMIQ in the Collagen-Induced Arthritis (CIA) rat model Several biomarkers of bone, cartilage, and the synovium have been described, and their changes have been igated in patients with CA for efficacy of intervention, disease prognosis, diagnosis and progression (Garnero et al., 2000). Loss of cartilage is believed to result from an imbalance of cartilage homeostasis to the catabolic direction by a combination of decreased repair processes and increased degradation activities in OA patients. Due to the d capacity for cartilage repair and as type II collagen is the most nt protein of the cartilage , the assessment oftype II collagen sis and degradation seemed to be a feasible approach to assess efficacy of OA interventions. For example, cartilage tissue from patients with CA and y controls have shown both d sis and increased degradation of type II collagen (Nelson et al., 1998, Billinghurst et al., 1997).

Therefore, the use of two biomarkers each addressing the synthesis or degradation of articular cartilage (in particular type II collagen) could be used as tools to better predict either OA progression or efficacy of OA treatment. This method coupled both the anabolic and catabolic processes of articular cartilage homeostasis. During cartilage development, type II collagen is synthesized as lagen with N—and C-propeptide terminals, and type II procollagen is produced in two forms (Type A and type B) as the result of alternative RNA splicing. The release of either of the propeptides from the synovial ﬂuid to the blood circulation at the time of secretion and before incorporation of type II collagen into ECM can be used to determine the rate of cartilage synthesis or regeneration or ding. On the other hand, urinary peptides of type II collagen (uCTX-II), is a prominent marker for cartilage degradation. Urine C-terminal telopeptide of type II collagen (uCTX-II) has been by far the most studied and frequently referred to and validated biomarker of cartilage degradation that could be used for the purpose of sis, determining the severity of disease or extent of disease ssion, prognosis, and monitoring Finlayson Reference No.: 838-1423 efficacy of treatment (Oesterggaard et al., 2006). In clinical studies, high levels of uCTX-II are a good predictor of increased risk ofjoint ction (Garnero et al., 2001).

We used two primary biomarkers, uCTX-II and PIIANP, to determine the cartilage homeostasis of degradation (and hence catabolic activity) and cartilage rebuilding (and hence anabolic activity) effects of the novel composition AlpiniazPepper (AP) and a:Magnolia:Kochia (AMK) stered orally in the collagen-induced rat arthritis model.

Previously, Garnero et al measured these markers [Type II collagen synthesis and degradation: N- propeptide of type IIA procollagen (PIIANP) and urine CTX-II, respectively] and ated them to ﬁndings on radiographs and arthroscopy of OA patients. Their s showed that patients with low serum levels of PIIANP and high urine levels of CTX-II had relative risks of progression of OA of 2.9 by radiography and 9.3 by arthroscopy ro et al, 2002). They explained their observation that these patients have an ling effect between collagen synthesis and ation, which is leaning more towards the progression of OA.

Table 30. Type II collagen sis and degradation predicts efficacy of OA intervention.

. Imbalance Regeneratlon Degradation (catabolic — anabolic) 200 —— . . O Uncoupling ance): (CTX-II)-(PIIANP) Z score = number of SDs from the mean of normal control rats.

Adapting their method, we calculated the Z-factor for cartilage synthesis and degradation using data from PIIANP and uCTX-II, respectively. For an intervention to drive the OA catabolic progression towards anabolic or regenerative activities, the Z-score values have to come close to zero. As seen in Table 30, below, both the regeneration Z-score (AMK: -0.59 :: 0.20 vs CIA: -l .39 Finlayson Reference No.: 838-1423 :: 0.23 showing less compromised rebuild function from AMK) and degradation Z-score values (AMK: -0.07::0.45 vs CIA: l.59::0.3l showing less degradation from AMK) (Table 30) for AMK were signiﬁcantly different from the vehicle-treated disease group (CIA group). These improvements in driving the OA ssion to normalcy by inducing cartilage synthesis and protection of its degradation were found to be 82.6% and 56.4% for the AMK and Methotrexate treated animals, respectively, relative to the vehicle treated CIA rats.

Example 41. Collagen-Induced tis model induction and AMK treatment Male Sprague Dawley rats (7—8 weeks old, 11 = 40) were purchased from Charles River tories Inc. ngton, MA, USA) and acclimated upon arrival for two weeks before being assigned randomly to their tive ent : G1 = Normal control (—) (n = 10/group), G2 = collagen-induced arthritis (CIA) + Vehicle (0.5% Carboxy Methylcellulose) (n = 10/group), G3 = CIA + Methotrexate (+) (75 ug/kg) (n = lO/group), and G4 = CIA + AMK (+) (200 mg/kg) (n = 10/group). Treatment was initiated two weeks before model induction and lasted for an onal three weeks thereafter. Collagen type-II (Lot # 845) from bovine nasal septum and Incomplete Freund’s adjuvant (IFA) (Lot # SLBRO642v) were purchased from Elastin Products Company ville, MI, USA) and Sigma (St. , MO, USA), respectively. All als were kept at suitable temperatures as recommended by the manufacturer. At the time of preparation, 60 mg of collagen was weighed and added to pre-chilled 15 mL 0.1 M acetic acid in a 60 mL-sized ﬂask with a magnetic stirrer to yield 4 mg/mL concentration (Brand, et al., 2003, Rosloniec et al., 2001).

The mixture was dissolved by gently stirring overnight at 4 oC. The next morning, the dissolved collagen was emulsiﬁed with equal volume of IFA (15 mL) to achieve a final concentration of 2 mg/mL collagen. Rats sedated with isoﬂurane were then primed intradermally with 400 uL of the emulsified collagen at the base of their tail at two sites using a 1 mL syringe ﬁtted with a 26 G needle. The dissolved mixture was kept in an ice bucket and stirred between groups at the time of ion to preserve m consistency. On the seventh day, rats were inoculated with a booster dose of 2 mg/mL type II collagen emulsified with equal volume of incomplete adjuvant at 100 uL/rat/site.

Clinical findings such as arthritis ty index, paw thickness, ankle diameter (using Digital Absolute, Model # PK-0505CPX, Mitutoyo Corporation, Kawasaki, Japan), and pain Finlayson nce No.: 838-1423 sensitivity (using Randall Salitto, IITC Life Science Inc., Woodland Hills, CA, USA) were monitored during the course of study. Urine was collected from overnight fasted rats using metabolic cages after three weeks of ent post-model induction. At Necropsy, serum from the cardiac and synovial lavage (100 uL of saline was injected into the articular cavity and aspirated back to the syringe) for kers and ankle joint for histopathology were collected from each animal.

Linear trapezoid rule was used to calculate area under the curve (AUC) for days 9-21. % Inhibition = {(Mean value of treatment-mean value of CIA+)/(Mean value of control-mean value of 100.

Example 42. Reduction of Arthritis Severity Index of Rats by composition AMK in the CIA model Rats continued to show a slow progression of disease for the duration of study. As seen in the data, rats treated with Methotrexate and AMK showed statistically signiﬁcant suppression of arthritis severity from day 12 and continued this signiﬁcance for the duration of study (Table 31).

At the end of the study, average severity scores of 3.75 :: 0.32, 1.78 :: 0.79, and 1.95 :: 1.17, were observed for rats treated with Vehicle, Methotrexate, and AMK, tively. It demonstrated a clear separation of the effect and potency of AMK and Methotrexate treatments.

When the area under the arthritis severity curve was calculated, the percent reductions of 62.55% (p=0.04) and 51.35% 4) with tical signiﬁcance were observed from positive l Methotrexate and AMK treatment (Table 31), respectively.

Example 43. Reduction of the ankle diameters of CIA rats by composition AMK, ting its anti-arthritic activity In agreement with the severity score, rats treated with Methotrexate and AMK showed a statistically signiﬁcant reduction in ankle diameter starting from day 12 and maintained this signiﬁcance for the duration of study (Table 32). These groups showed a statistically cant reduction in ankle width when the area under the curve was considered for days 9 to 21. Percent reductions of 65.94% and 55.84 % with tical signiﬁcance in ankle diameter were observed for rats treated with Methotrexate and AMK, respectively (Table 32).

Finlayson Reference No.: 838-1423 Example 44. Reduction of the paw thickness of CIA rats by composition AMK, indicating its anti-arthritic activity In agreement with the severity score and ankle diameter, rats treated with Methotrexate and AMK showed a statistically signiﬁcant ion in paw swelling starting from day 12, this signiﬁcance was maintained for the duration of the study (Table 33). When the total area under the swelling curve (day 12—day 21) was considered, Methotrexate and AMK groups showed statistically signiﬁcant reductions (71.7% and 64.3%) in paw edema compared to the vehicle treated CIA group, respectively (Table 34).

Example 45. Arthritis index, ankle diameter and area under the response curve (AUC) for paw thickness of CIA rats treated with ition AlpiniazMagnoliazKochia (AMK) As seen in Table 34, above, rats treated with AP showed 64.23%, 55.8% and 51.4% inhibition in paw thickness, ankle diameter and arthritis severity index during the course of the study period when compared to e-treated CIA rats, respectively. These ions were more than 50% in each parameter and statistically signiﬁcant for each parameter, indicating the potency of composition AMK in reducing arthritis-associated symptoms. In ison, the Methotrexate- treated rats showed 71.7%, 65.9% and 62.6% reduction in paw thickness, ankle diameter and arthritis severity index, respectively.

Example 46. Reduction of compression-induced pain in CIA rats by composition AlpiniazMagnoliazKochia (AMK) indicating its symptom relief activity Response to pressure as a measure of pain sensitivity was assessed using the Randall— Salitto probe attached to an electronic monitor on priming day, boost day, and days 12, 14, 16, 19, and 21. Both the left and right hind legs were monitored on those days and their average was used for data analysis. Changes from the e-treated CIA rats have been reported as pain tolerance on those days. The highest pain tolerance was observed for rats in the Methotrexate group ed by the AMK group (Table 35) in the disease models. These reductions, 6.8%, 13.5%, 28.2, 40.8%,and 43.9% for Methotrexate and 6.9%, 17.5%, 23.2%, nd 39.0% for AMK on days 12, 14, 16, 19, and 21, tively, were statistically signiﬁcant as of day 12 and remained cant for the duration of the study except on day 14 for the Methotrexate group, when reduction was not statistically signiﬁcant.

Finlayson nce No.: 838-1423 Table 31. Changes of Arthritis severity index for rats treated with AMK in CIA model: Arthritis Index Groups Stat Boos Day Day day Priming t 9 10 21 Sd 0.00 0.00 0.00 0.00 . . . . . . . . 0.00 Mga 0.00 0.00 0.00 0.03 . . . . . . . . 3.75 0.00 0.23 * 0.46¥ 0.701: 1. 10e 1.50e 1.76e 2.03e 1.78e (75ug/kg) Sd 0.00 0.00 0.00 0.00 . . . 0.71 0.74 0.81 0.91 1.03 0.79 0.00 0.00 0.00 0.03 1: e e e € 1: . . . 0.98 1.48 1.80 2.03 2.15 1.95 (200mg/kg) Sd 0.08 0.15 0.44 0.50 0.62 0.58 0.71 0.67 1.02 1.17 * P5005; f PS0001;¥PS00001;€PS 1 0: No sign of grossly visible arthritis (Normal) 1: Swelling and/or redness of one or two interphalangeal joints (or mild swelling and erythema of digits or ankles) 2: Involvements of three to four interphalangeal joints (or moderate swelling and erythema of digits or ankles) 3: Swelling of entire paw (or marked ng ofpaws including digits) 4: Deformity and ankylosis (or sever swelling and erythema with limited motion in many joints) Finlayson nce No.: 838-1423 Table 32. Changes in ankle width for CIA rats treated with Alpinia:Magnolia:Kochia (AMK), Ankle diameter “II...- 0.02 0.02 0.02 0.02 0.03 0.05 0.04 0.03 6.98 7.21 7.62 8.50 8.65 9.25 9.45 6.06 0.48 0.80 0.76 0.84 1.00 1.20 1.17 0.10 6.33 6.50* 6.67* 6.85* 7.06* 7.28* 732* 6031‘ 0.22 0.46 1.00 1.30 1.30 1.32 1.16 0.10 M 6.19 6.37 6.861‘ (200mg/kg) . . 0.21 0.27 0.35 0.64 1.14 1.33 1.75 1.70 0.04 * P5005; f PS0001;¥PS00001;€PS 0.00001 Finlayson Reference No.: 838-1423 Table 33. Changes in paw thickness as a measure of anti-arthritic effect of Alpinia:Magnolia:Kochia (AMK), in CIA rats Paw thickness Groups Stat Primi Day Day Day Day Day Day Day Day Day Day Day ng 9 10 11 12 13 14 15 16 17 19 21 Mga 2.97 2.97 3.01 3.10 3.12 304* 3 05¥ 2.97€ 2.97€ Sd 0.06 0.04 0.04 0.03 0.05 0.03 0.03 0.04 0.06 0.05 Mga 3.03 3.87 4.24 4.79 5.34 5.77 6.20 5.84 3.03 3.10 0.05 0.05 0.21 0.43 0.39 0.56 0.61 0.97 0.85 0.80 0 77 0.05 0.05 (75ug/kg Sd 0.05 0.40 0.67 0.73 0.79 0.85 0.93 0.69 0.05 0.06 AMK Mga 3.05 3.35 3.52* 3.66* 385* 4.26T 4.56T 4.50T 3.05T 3.03* (200mg/ 0.05 0.05 0.10 0.21 0.37 0.53 0.54 0.75 0.91 1.20 1.20 0.05 0.05 Table 34. Area under the response curve for CIA rats treated with Alpinia:Magnolia:Kochia (AMK) AUC(119-1121) 0A) Inhibition. . . P-Values VS CIA + vehicle.

(Mean :1: SD) Group Paw Arthritis Paw Ankle tis Paw Ankle Arthritis thickness index thickness er index thickness diameter index 71.71 65.94 62.55 0.01 0.02 0.04 (Bug/kg) ----- Finlayson Reference No.: 838-1423 21.22:-0 3 39.912-0 3 /k ' ' ‘ ‘ 6.33::0.31 64.26 55.84 51.35 0.03 0.05 0.04 Table 35. Anti-pain activity of Alpinia:Magnolia:Kochia (AMK) in CIA rats Compression pain resistance vs CIA + vehicle (Mean :1: SD) Group Day 21 Normal control (75 -. : . . 1348:1598 28.18::12.53T 4077:1091€ 43.88::5.97¥ ug/kg) (200 - . : . . . . . 17.52::14.17* 2324:1145T 32.36::9.80¥ 39.032751¥ Ing/kg) *P S 0.05; 7P S 0.00]; ¥P S 0.0001; €P S 0.00001 Example 47. Reduction of proinﬂammatory cytokines and matrix degrading enzymes by composition AlpiniazMagnoliazKochia (AMK) in CIA rats The presence of catabolic cytokines IL-lB, "INF-or, or 1L-6 was ed using Rat lL-lB, TNF-d, and IL-6 Quantikine ELISA kit from R and D Systems (product#: RLBOO for IL-lB, RTAOO for TNF-OL, and R6000B for 1L-6) as follows: diluted serum was added to a microplate coated with polyclonal lL-lB, "INF-or, or IL-6 antibody and allowed to bind for 2 h at room ature. The microplate was washed thoroughly to remove unbound serum and then a onal enzyme-conjugated IL-lB, TNF-OL, or IL-6 antibody was added and d to bind for 2 h at room temperature. Washing was repeated, enzyme substrate was added, and the plate was developed for 30 min at room temperature. After the addition of stop solution, the absorbance was read at 450 nm, multiplied by on factor, and the concentration of IL-lB/TNF-d /IL-6 calculated based on the absorbance readings of an lL-lB/TNF-d /lL-6 standard curve.

The presence of age degradative enzyme MMP-13 was measured using the Rat Matrix Metallo-Proteinase 13 (MMP-13) ELISA kit from Mybiosource (product#: 1Vﬂ3 S7021 12 for MlVIP-13) as follows: serum was added to a microplate coated with MMP-13 antibody and allowed to bind for 2 h at 37 oC. The samples were removed and then a -conjugated MMP-13 antibody Finlayson Reference No.: 838-1423 was added and allowed to bind for l h at 37 oC. The microplate was thoroughly washed, and an avidin-conjugated Horse Radish Peroxidase was added and allowed to bind for l h at 37 oC.

Enzyme substrate was then added, and the plate was developed for 30 min at 37 0C. After the addition of stop solution, the absorbance was read at 450 nm, multiplied by dilution factor, and the tration of MMP-l3 calculated based on the ance readings of an MMP-l3 standard curve An increased production of catabolic cytokines is the integral part of collagen-induced arthritis pathology. Rats treated with AMK composition showed a statistically cant reduction in serum IL-lB level when compared to the vehicle-treated CIA group (Table 36).

Similarly, marked decreases in serum TNF-d and IL-6 levels were observed for CIA rats d with AMK or Methotrexate. As depicted in Table 36, signiﬁcant increases in serum catabolic cytokines IL-lB and IL-6 level were observed for the vehicle-treated CIA group compared to the normal control. AMK-treated rats showed a statistically signiﬁcant reduction in serum IL-lB (67.4% inhibition, compared to diseased control), IL-6 (60.2% inhibition, compared to diseased control) and TNF-d (75.5% inhibition, ed to diseased control) levels when compared to vehicle-treated diseased rats (Table 36). Methotrexate-treated rats showed d serum IL-lB (71.5% inhibition, compared to diseased l), IL-6 (78.6% inhibition, ed to diseased control) and TNF-d (86.2% inhibition, compared to diseased control) levels when compared to vehicle-treated diseased rats (Table 36). This example y demonstrated that the natural AMK composition is capable of reducing the lic processes of arthritic animals.

Similarly, a marked increase in the level of serum MIVIP-l3 level was observed for the vehicle-treated arthritis diseased rats, when compared to the normal control rats. As seen in Table 36, CIA rats treated with AMK showed a statistically signiﬁcant reduction in catabolic cartilage degradative enzyme l3 level compared to vehicle-treated CIA rats. This 81.4% inhibition of MIVIP-l3 from AMK-treated CIA rats was calculated as statistically signiﬁcant vs. CIA-treated rats. Though it was not statistically signiﬁcant, there was a noteworthy reduction (78.6% compared to vehicle-treated CIA rats) in serum MIVIP-l3 level for the positive drug control rexate- d rats.

Table 36. Effect of Alpinia:Magnolia:Kochia (AMK) on proinﬁammatory cytokines in CIA rats Finlayson Reference No.: 838-1423 IL-lB IL-6 TNF-a MMP-13 (pg/mL) (pg/mL) (pg/mL) (pg/mL) Normal Control MTX (75 ug/mL) AMK /kg) 5.52 :: 3.25** 18.99 :: 8.06** 0.66 :: 094* 8.38 :: 186* P S 0.05 vs Vehicle; >X”le S 0.01 vs Vehicle; >X”WP S 0.00] vs Vehicle Example 48. Reduced cartilage degradation and increased cartilage regeneration/rebuilding ty of AlpiniazMagnoliazKochia (AMK) in CIA rats The presence of the cartilage degradation biomarker I was measured using the Rat CTX-II ELISA kit from ource (product#: lVﬂ3S2880519) as follows: diluted urine was added to a microplate coated with CTX-II antibody and allowed to bind for 2 h at 37 0C. A biotin- conjugated antibody against CTX-II was then added and allowed to bind to the CTX-II from the rat urine for 1 h at 37 oC. The microplate was washed thoroughly to remove unbound urine and antibody before an -conjugated avidin dy was added to bind to the biotin-conjugated antibody for speciﬁc detection. The avidin antibody was allowed to bind for 1 h at 37 oC. Washing was repeated, enzyme substrate was added, and the plate was developed for 30 min at 37 0C. After the on of stop on, the absorbance was read at 450 nm, lied by dilution factor, and the concentration of CTX-II calculated based on the absorbance readings of a CTX-II standard curve. CTX-II amount was normalized to the amount of Creatinine in the urine using the Creatinine Parameter Assay Kit from R and D Systems (product#: KGEOOS) as follows: urine was diluted 1:20, mixed with alkaline picrate (5 parts 0.13% picric acid: 1 part 1 N NaOH) in a microplate and incubated at room temp for 30 min. Absorbance was read at 492 nm and Creatinine amount in urine was calculated based on the ance readings of a Creatinine standard curve.

The presence of cartilage regeneration/rebuilding biomarker PIIANP was measured using the Rat Procollagen Type IIA N—Prop (PIIANP) ELISA kit from Mybiosource (product#: lVﬂ3S93 99069) as follows: synovial ﬂuid was added to a microplate coated with PIIANP antibody Finlayson Reference No.: 838-1423 as well as an HRP-conjugated PIIANP antibody and allowed to bind for one hour at 37°C. The microplate was thoroughly washed, and a Chromagen solution was added and allowed to bind for minutes at 37°C. After the addition of stop solution, the absorbance was read at 450 nm and the tration ofPIIANP calculated based on the absorbance readings of a PIIANP standard curve.

Signiﬁcant urine CTX-II level changes both in the arthritis disease model and treatment groups were observed. As provided in Table 37, a statistically cant increase in urine CTX- II level was ed for the vehicle-treated CIA group compared to the normal control animals conﬁrming the increased catabolic ses of diseased animals. A higher level of urinary CTX- II is a sign of cartilage degradation, which was signiﬁcantly inhibited by the composition AMK.

Treatment with AMK spared signiﬁcant degradation of cartilage (inhibited up to 36.7%) compared to vehicle-treated diseased CIA rats. The positive control Methotrexate showed 26.4% inhibition of the age ation ker compared to CIA with p = 0.06.

Similarly, the anabolic effect from AMK composition was conﬁrmed by measuring cartilage synthesis/regeneration/rebuilding biomarker - synovial PIIANP. As seen in Table 37, below, a statistically signiﬁcant increase in synovial PIIANP was observed for the rats treated with AMK when compared to vehicle-treated CIA rats. Rats in this AMK- treated group showed a 79.4% increase in cartilage synthesis/regeneration/rebuild biomarker - synovial PIIANP when compared to vehicle-treated CIA rats. The Methotrexate-treated rats showed 69.8% increase in cartilage repair compared to vehicle-treated CIA rats. In contrast, the e-treated CIA rats experienced more than a d decrease in the level of PIIANP indicating the shift of arthritic animals more towards age ation than repair.

Table 37. Anti-catabolic and anabolic activities of AMK in CIA rats CTX-II PIIANP Group (ng/g creatinine) (ng/mg) Normal Control MTX (75 ug/mL) Finlayson Reference No.: 838-1423 AMK (200 mg/kg) 2152.3 246.9*** 0.63 013* >X7) S 0.05 vs Vehicle; >X”kl? S 0.0] vs Vehicle; >X”WP S 0.00] vs Vehicle Example 49. Histopathology gs for CIA rats treated with A1pinia:Magnolia:Kochia (AMK), For histopathological examination, the ankle joints were kept in 10% formalin for 72 h.

The ﬁxed specimens were then decalciﬁed with Clear Rapid for one and a half days and embedded in parafﬁn. Standardized 5 um serial sections were obtained at the medial and lateral section in the sagittal plane of the joint and were d with hematoxylin and eosin (HE) and Safranin O-fast green to enable evaluation of proteoglycan content. A modiﬁed Mankin system (Mankin et al., 1971) was used to score structural and cellular alterations ofjoint tissues resulting from disease progression and/or treatment y. The histological analysis was conducted at Nationwide Histology and slides were examined by a certiﬁed pathologist.

The histopathology data was in alignment with the ty score of arthritis. When compared to the normal control rats, vehicle-treated rats showed severe synovitis, marked cartilage degradation, synovial hyperplasia, pannus formation, and bone erosion (Figure 5, Table 38). These changes for the vehicle-treated CIA rats in comparison to the normal controls were reﬂected as 3 .3-fold, 3.8-fold, 4.7-fold and 24.2-fold increase in cartilage degradation, GAG loss, bone erosion and inﬂammation, respectively. In contrast, rats treated with AMK had nearly normal logy, with minimal alterations in matrix ity, a er articulation cartilage e, low levels of mononuclear cell inﬁltration, and synovial hyperplasia, as well as reduced articular bone damage. Cartilage protection and hence anti-catabolic activity of composition AMK was found to be 65.1% with a 61.9% nance of matrix integrity in comparison to the vehicle-treated CIA rats. In agreement with the biomarker data (reduced lic cytokines IL-IB, TNF-oc and IL-6), there was an 88.2% reduction in inﬂammation in composition AMK-treated rats when compared to vehicle-treated CIA rats. There was also a 73.1% reduction in bone erosion for the CIA rats treated with AMK composition. These changes were statistically signiﬁcant for each parameter monitored ed to vehicle-treated CIA rats.

Table 38. Histopathology ﬁndings in CIA rats treated with A1pinia:Magnolia:Kochia (AMK) Finlayson Reference No.: 23 Cartilage destruction GAG Loss Bone n Inﬂammation Group (Mean i SE) (Mean i SE) (Mean i SE) (Mean i SE) 1.08 :: 024* 0.71:: 0.27** 0.21:: 0.12** Normal Control (74.0%) (78.8%) (95.9%) 2.90 0.63 2.04 062* 1.13 046* 3.25 1.02 MTX (75 ug/mL) (32.6%) (50.8%) (66.3%) ) AMK 1.50 017* 1.58 049* 0.90 029* 0.60 035* (200mg/kg) (65.1) ) (73.1%) (88.2%) >X<P S 0.05 vs Vehicle; ** P S 0. 01 vs Vehicle; data in the parenthesis is percent inhibition against vehicle treated disease model. Cartilage destruction (0—6): Cartilage ess/thinning, irregular surface frayed/ issure loss, degeneration, ulcerative necrosis/ﬁagmentation, severe disorganization/chaotic; Bone damage (0—6): Subchondral bone thickness/volume and density, osteoclastic activity, ndral bone damage; Inﬂammation/Cellular inﬁltration (0—6): Cellular Infiltration/Inflammation and eration, hypercellular, cluster/hypocellular; Matrix GAGs loss (0—6): Matrix GAG reduction: radial, erritorial to pericellular loss ofstaining, femoral condyle/tibial plateau integrity, and thickness of articular Cartilage. Data expressed as Mean :: SE.

Figure 5 shows histopathology images (HE a-d and Safranin O e-f) from ankle joint of CIA induced rats treated with AMK and MTX. A and e - normal control, b and f - CIA+ e, 0 and g — CIA+MTX, d and h — CIA+ AMK.

Following documentation of the above AlpiniazMagnoliazKochia (AMK) efﬁcacy outcomes from the CIA model as described from Examples 40 - 49 here in the current subject matter, a esponse study for AMK in the CIA model was carried on to extrapolate an optimum human equivalent dose conversion as suggested by the FDA ) In this FDA guidance for the industries, a 0.16 conversion factor has been suggested for a rat dosage in mg/kg to human (i.e. rat dose in mg/kg multiply by 0.16 = human equivalent dose in mg/kg). As such, in this CIA study rats are being administered at oral doses of 40, 60, 80 and 120 mg/kg/day of AMK for 5 weeks. These dosages would give a human equivalent dose of 448, 672, 896 and 1344 mg/day for an average 70kg adult.

Finlayson Reference No.: 838-1423 We believe that results from this dose-response study would provide a basis for future human clinical trial dosage determination.

Example 50. Second Collagen-Induced Arthritis model induction and AP treatment Male Sprague Dawley rats (7—8 weeks old, 11 = 40) were purchased from Charles River Laboratories Inc. (Wilmington, MA, USA) and acclimated upon arrival for two weeks before being assigned ly to their respective treatment groups: G1 = Normal control (—) (n = 10/group), G2 = collagen-induced arthritis (CIA) + Vehicle (0.5% Carboxy Methylcellulose) (n = 10/group), G3 = CIA + Methotrexate (+) (0.5 mg/kg) (n = 10/group), and G4 = CIA + AP (+) (200 mg/kg) (n = lO/group). Treatment was ted two weeks before model induction and lasted for an additional three weeks thereafter. Collagen type-II (Lot # 845) from bovine nasal septum and Incomplete Freund’s adjuvant (IFA) (Lot # SLBR0642v) were sed from Elastin Products Company (Owensville, MI, USA) and Sigma (St. Louise, MO, USA), respectively. All materials were kept at suitable atures as recommended by the manufacturer. At the time of preparation, 60 mg of collagen was weighed and added to pre-chilled 15 mL 0.1 M acetic acid in a 60 mL-sized ﬂask with a magnetic stirrer to yield 4 mg/mL concentration , et al., 2003, Rosloniec et al., 2001). The mixture was dissolved by gently ng overnight at 4°C. The next morning, the dissolved en was emulsified with equal volume of IFA (15 mL) to e a final concentration of 2 mg/mL collagen. Rats sedated with isoﬂurane were then primed intradermally with 400 uL of the emulsified collagen at the base of their tail at two sites using a 1 mL syringe fitted with a 26 G needle. The dissolved mixture was kept in an ice bucket and stirred between groups at the time of injection to preserve uniform consistency. On the seventh day, rats were ated with a booster dose of 2 mg/mL type II collagen emulsified with equal volume of incomplete adjuvant at 100 uL/rat/site.

Clinical findings such as arthritis severity index, paw thickness, ankle er (using Digital Absolute, Model # 5CPX, Mitutoyo Corporation, ki, Japan), and pain sensitivity (using Randall Salitto, IITC Life Science Inc., Woodland Hills, CA, USA) were monitored during the course of study. Urine was collected from overnight fasted rats using lic cages after three weeks of treatment post-model induction. At Necropsy, serum from the cardiac and synovial lavage (100 uL of saline was injected into the articular cavity and Finlayson Reference No.: 23 aspirated back to the syringe) for biomarkers and ankle joint for histopathology were collected from each animal.

Linear trapezoid rule was used to calculate the area under the curve (AUC) for days 9-21.

% Inhibition = {(Mean value of treatment-mean value of CIA+)/(Mean value of control-mean value of CIA)}*100.

Example 51. Reduction of arthritis severity index by composition AP in CIA rats Rats continued to show a slow progression of disease for the duration of study. As seen in the data below, rats treated with both the treatment groups such as Methotrexate and AP showed statistically signiﬁcant suppression in arthritis severity from day 12 and continued this signiﬁcance for the duration of study (Table 39).

At the end of the study, average severity scores of 3.5 :: 0.42, 1.1 :: 0.17, and 2.0 :: 0.89, were observed for rats treated with Vehicle, Methotrexate and AP, tively. These values demonstrated a clear effect and potency ofAP and drug ents in on to the vehicle-treated disease model. When the area under the arthritis severity curve was calculated, the percent reductions of 78.8% (p=0.002) and 54.9% 2) with statistical cance were observed from positive drug control Methotrexate and AP treatment, respectively. (Table 39).

Example 52. Reduction of ankle diameter by composition AP in CIA rats Statistically signiﬁcant reduction in ankle diameter was ed for rats treated with Methotrexate and AP until day 16 post induction (Table 40). Thereafter, only the Methotrexate group showed a statistically cant reduction in ankle diameter. Only Methotrexate group showed a statistically signiﬁcant reduction (i.e. 93.6%) in ankle width when the area under the curve was considered for days 9 to 20. A statistically non-signiﬁcant 60.6% reduction in ankle diameter were ed for AP-treated CIA rats for the AUC (Table 40).

Table 40. Changes in ankle diameter for CIA rats treated with AP composition Ankle diameter Groups Stat Priming Finlayson Reference No.: 23 MTX (0.5mg/kg) AP (200mg/kg) **P£0.001; >“""“P£O.0001; MTX: Methotrexate Finlayson Reference No.: 23 Table 39. Changes of Arthritis severity index for rats treated with AP in CIA model Inductions Arthritis Index ps Primi Day Day Day Day Day Day Day Day Day Day Boost ng 10 11 12 13 14 15 16 17 19 20 * * * * * * * * Mean 0.00 0.00 0.00 0.00 0’20 0’20 0’20 0’20 0‘20 0‘20 0‘20 0‘20 Sd 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 Mean 0.00 0.00 0.08 0.23 0.75 1.25 2.1 2.875 3.375 3.725 3.825 3.6 Sd 0.00 0.00 0.11 0.28 0.45 0.55 0.60 0.32 0.36 0.31 0.35 0.45 * * Mean 0.00 0.00 0 0 0‘25 0** 0** 0‘15 03:5 1** 18:5 1.1** (0.5m g/kg) Sd 0.00 0.00 0.00 0.00 0.15 0.00 0.00 0.23 0.20 0.00 0.16 0.17 * * * * Mean 0.00 0.00 0 0 01* 025 0:5 1‘25 1.6** 1.9** 195* 2&3 AP(20 0mg/k Sd 0.00 0.00 0.00 0.00 0.17 0.35 0.52 0.56 0.59 0.80 0.83 1.00 *P s 0.001; **P s 0.0001 Finlayson Reference No.: 23 Example 53. Reduction of paw ess by composition AP in CIA rats In agreement with the severity score and ankle diameter, rats treated with Methotrexate and AP showed a statistically signiﬁcant reduction in paw swelling ng from day 12 and maintained this signiﬁcance for the duration of study (Table 41). However, when the total area under the swelling curve (day 7 — day 20) for this reduction was considered, rats only in the Methotrexate group showed statistically signiﬁcant 93.8% reduction in paw edema compared to the vehicle-treated CIA group (Table 41). A t reduction of 69.3% in paw edema with P- value of 0.058, was observed for rats treated with AP composition, compared to the vehicle-treated CIA rats (Table 41) Table 41. Changes in paw thickness for CIA rats treated with composition AP Paw thickness Groups (mg/kg) Boost Day 12 Day 14 Day 16 Day 18 Day 20 Normal .06 2.99: AP 200 2.92::0.03 2.89::0.02 29920.09“< 3.45::0.61T 3.77::0.59T 4.14::0.81T 4.08::0.83T *PSO05, >“*PSO001, TPS0.0001 Example 54. Arthritis index, ankle er and area under the response curve (AUC) for paw thickness of CIA rats treated with composition AP As seen in Table 42, below, rats treated with AP showed 69.3%, 60.7% and 54.9% inhibition in paw thickness, ankle diameter and arthritis severity index during the course of the study period when compared to vehicle treated CIA rats, respectively. These reductions were more than 50% for each parameter, indicating the signiﬁcance of composition AP in reducing arthritis- associated symptoms. In comparison, the Methotrexate-treated rats showed 93.8%, 93.6% and 78.8% ion in paw thickness, ankle diameter and tis severity index, respectively.

Finlayson Reference No.: 23 Example 55. Reduction of the ssion-induced pain by composition AP in CIA rats, indicating its symptom relief activity Response to pressure as a e of pain sensitivity was measured using the Randall— Salitto probe attached to an electronic monitor on priming day, boost day, and days 12, 14, 16, 18 and 20. Both the left and right hind legs were monitored on those days and their averages were used for data analysis. Changes from the vehicle-treated CIA rats have been ed as pain tolerance on those days. The highest pain tolerance was ed for rats in the Methotrexate group (69.4% improvement on day 20) followed by the AP (31.5% improvement on day 18) (Table 43).

This reduction in pain sensitivity was statistically signiﬁcant at all time points as of day-12 for both groups when compared to vehicle-treated CIA rats (Table 43). Rats treated with composition AP showed ranges of 8.25 - 31.5% reduction in pain sensitivity compared to vehicle treated CIA rats. The rexate group showed 8.39 - 69.4% reduction in pain sensitivity in the same duration.

Example 56. Catabolic cytokines, matrix degrading enzymes and cartilage synthesis biomarker changes by composition AlpiniazPepper (AP) in CIA rats At the completion of the study, blood from cardiac puncture was collected from each animal. Blood was spun at 3000 rpm for 15 min. About 0 ul of serum was isolated from each rat. Samples were kept at -80°C until use.

The presence of catabolic cytokines IL-6/TNF-d was measured using the Rat IL-6/TNF-d Quantikine ELISA kit from RandD Systems as follows: undiluted serum was added to a microplate coated with polyclonal NF-d antibody and allowed to bind for 2 hours at room temperature.

The microplate was washed thoroughly to remove unbound serum, and then a polyclonal enzyme- conjugated IL-6/TNF-d dy was added and allowed to bind for 2 hours at room temperature.

Washing was repeated, enzyme substrate was added, and the plate was developed for 30 minutes at room temperature. After the on of stop solution, the absorbance was read at 450 nm and the tration of IL-6/TNF-d calculated based on the absorbance readings of an IL-6/TNF-d standard curve.

Finlayson Reference No.: 838-1423 Table 42: Area under the se curve for CIA rats treated with Alpinia:Pepper (AP) AUC(419-4121) 0A) Inhibition. . . P values VS CIA + vehicle__ (Mean :1: SD) Group Paw Arthritis Paw Ankle Arthritis Paw Ankle tis thickness index thickness diameter index thickness diameter index 93.81 93.59 78.78 0.01 0.01 0.002 (0.5mg/kg) 0.12 0.02 (200mg/kg) Table 43: Anti-pain activity of Alpinia:Pepper (AP) in CIA rats Compression pain resistance vs CIA + e (Mean :|: SD) Group 83.96 :: Normal control 1 191 69.35 :: MTX (0.5mg/kg) 1.5 11 28.97 :: AP (200mg/kg) 2.811“ TPSOOOOl vs vehicle treated CIA Finlayson Reference No.: 838-1423 The ce of cartilage degradative enzyme MMP-13 was measured using the Rat Matrix Metalloproteinase 13 (MMP-13) ELISA kit from Mybiosource (product#: 702112) as s: undiluted serum was added to a microplate coated with M1VIP-13 antibody and allowed to bind for 2 hours at 37°C. The samples were removed, and then a biotin-conjugated M1VIP-13 antibody was added and allowed to bind for 1 hour at 37°C. The microplate was thoroughly washed, and an -conjugated Horse Radish Peroxidase was added and allowed to bind for 1 hour at 37°C. Enzyme substrate was then added, and the plate was developed for 30 minutes at 37°C. After the addition of stop solution, the absorbance was read at 450 nm and the concentration of MMP-13 ated based on the ance readings of an 13 standard curve.

The level of cartilage regeneration biomarker PIIANP was measured using the Rat Procollagen Type IIA N—Prop (PIIANP) ELISA kit from Mybiosource (product#: MB S93 99069) as follows: undiluted serum was added to a microplate coated with PIIANP antibody as well as an njugated PIIANP antibody and d to bind for one hour at 37°C. The microplate was thoroughly washed, and a Chromagen solution was added and allowed to bind for 15 minutes at 37°C. After the addition of stop solution, the absorbance was read at 450 nm and the concentration of PIIANP calculated based on the absorbance readings of a PIIANP standard curve.

Composition AP administered orally at 200 mg/kg for 3 weeks, signiﬁcantly reduced the serum catabolic biomarkers IL-6, TNF-d and MMP-13 levels when compared to vehicle-treated CIA rats. The most signiﬁcant inhibition in proinﬂammatory and catabolic cytokines as a result of composition AP treatment was observed in IL-6, which was reduced by 58.7% in comparison to the vehicle-treated CIA rat group. This reduction was complemented by a 43.5% reduction in matrix degrading enzyme MMP-13 for the AP-treated rats. The 1L-6 and M1VIP-13 data seem a true reﬂection of what was observed in the in-life study as far as clinical ements and hi stopathology ﬁndings for the AP-treated rats. The positive drug l rexate-treated rats experienced signiﬁcantly reduced s of IL-6 and TNF-d in the serum.

A statistically signiﬁcant decrease in serum cartilage regeneration biomarker PIIANP was observed for the CIA rats treated with vehicle compared to the control group (p=0.0017) (Table 44). The positive control Methotrexate had a signiﬁcant increase in serum PIIANP (47%, p=0.0017 compared to CIA + vehicle). AP administered orally at 200 mg/kg for 3 weeks, showed an increase in serum cartilage regeneration biomarker PIIANP (i.e. 18%), but the increase was not signiﬁcant. son Reference No.: 838-1423 These results indicated that the AP treatment still shifted the progression of arthritic rats toward cartilage regeneration/rebuilding, though to a lesser extent than the drug control. This shows that AP and drug ents contribute to the reversal of the en degradation phenotype that is characteristic of this arthritic animal model.

Table 44: Catabolic Pathways down regulated by AlpiniazPepper (AP) in CIA rats PIIANP IL-6 TNF-a MMP-13 Group (ng/mL) (pg/mL) (pg/mL) (pg/mL) Normal Control 608::0.75** l462::7.3** 9.57::0.3*** 87.l9::40.8l CIA+ 469:0.91 3583:1806 lO.68::O.38 414 (0. 5mg/mL) AP (200mg/kg) 5.44:0.66 l48::l708* lO09::0.77* :l443** 7) S 0.05 vs Vehicle; >X”le S 0.00] vs e; ***P S 0.000] vs Vehicle Example 57. Changes in histopathology readings by composition AlpiniazPepper (AP) in CIA At necropsy, the ankle joint was carefully dissected out, ﬁxed in 10% buffered formalin and sent to wide Histology (Veradale, WA, USA) for further histopathology analysis. The ﬁxed specimens were then decalciﬁed with Calci-Clear Rapid for one and a half days and embedded in parafﬁn. Standardized 5 um serial sections were obtained from each rat and stained with hematoxylin and eosin (HE) and Safranin O-fast green to enable evaluation of proteoglycan content. A modiﬁed Mankin system (Mankin et al., 1981) was used to score structural and cellular tions of articular ents as indications of disease progression and/or treatment efﬁcacy.

The histological analysis was conducted by a certiﬁed Pathologist at Nationwide Histology.

The histopathology data were in ent with the severity scores of arthritis. When compared to normal l rats, vehicle-treated CIA rats showed severe synovitis, marked cartilage degradation, synovial hyperplasia, pannus formation and bone erosion (Figure 5 and Table 45). These s for the vehicle-treated CIA rats in comparison to the normal controls were reﬂected as 17.9-fold, 7.9-fold, l8l-fold and 52.7-fold increases in cartilage degradation, Finlayson Reference No.: 838-1423 GAG loss, bone erosion and inﬂammation, respectively. In contrast, rats treated with Methotrexate had nearly normal morphology with minimal alternation in matrix integrity, a smoother articulation cartilage surface, low levels of clear cell inﬁltration and synovial hyperplasia, as well as reduced articular bone damage (Table 45). Similarly, rats treated with AP composition also showed tically signiﬁcant reductions in cartilage destruction, ation severity, bone erosion and GAG loss compared to CIA rats treated with vehicle. Cartilage protection and hence anti-catabolic activity of composition AP was found to be 57.7% with a 47.5% maintenance of matriX integrity in comparison to the vehicle-treated CIA rats. In agreement with the biomarker data (such as reduced catabolic TNF-d and IL-6), there was a 67.0% reduction in inﬂammation when compared to vehicle-treated CIA rats. There was also a 61.0% reduction in bone erosion for the CIA rats treated with AP composition. These changes from AP treatment were statistically signiﬁcant for each parameter monitored compared to vehicle-treated CIA rats.

Table 45. Histopathology s in CIA rats d with composition AlpiniazPepper (AP) Cartilage destruction GAG Loss Bone Erosion Inﬂammation Grou1’ (Mean A: SE) (Mean A: SD) (Mean :|: SE) (Mean :|: SE) 0.42:0.15*** 0.50:0.35*** 0.04:0.04*** 0.17:0.05*** Normal l (94.4%) (87.4%) (99.4%) (98.1%) MTX 0.13 0.05*** 0.21 0.17*** 0.00 * 0.00 0.00*** (0.5mg/mL) (98.3%) (94.5%) (100%) (100%) AP 3.17 144* 2.08 158* 2.83 1.65* 2.96 164* (200mg/kg) (57.7%) (47.5%) ) (67.0%) *P S 0.05 vs Vehicle; ***P S 0.00001 vs Vehicle; data in the parenthesis is percent tion against vehicle treated disease model. Data in the parenthesis ispercent inhibition t vehicle treated disease model. Cartilage destruction (0—6): Cartilage thickness/thinning, irregular surface frayed/ issure loss, degeneration, ulcerative necrosis/ﬁagmentation, severe disorganization/chaotic; Bone damage (0—6): Subchondral bone thickness/volume and density, osteoclastic ty, subchondral bone damage; Inﬂammation/Cellular inﬁltration (0—6): Cellular Infiltration/Inflammation and Proliferation, ellular, cluster/hypocellular; Matrix GAGs loss (0—6): Matrix GAG reduction: radial, erritorial to pericellular loss ofstaining, l condyle/tibial plateau integrity, and thickness of articular Cartilage. Data expressed as Mean :: SE.

Finlayson Reference No.: 838-1423 Figure 6 shows HE and Safranin O staining histology for CIA rats treated with AP (HE stains (40x): a= normal control + Vehicle, b=CIA + Vehicle, c=CIA + Methotrexate, d= CIA + AP, Safranin O stain (40x): e= normal l + vehicle, f=CIA + e, g=CIA + Methotrexate, h= CIA + AP, C = cartilage, SB = subchondral bone, I = inﬂammation) Example 58. Implications of the cartilage protection and symptom relief activities of azPepper (AP) and Alpinia:Magnolia:Kochia (AMK) in collagen-induced arthritis (CIA) The CIA model in rats is the most commonly studied autoimmune model of RA with several pathological features resembling the -mediated polyarthritis in humans (Miyoshi et al., 2018). Its short duration between zation and disease manifestation makes the model feasible for therapeutic efﬁcacy evaluations. Following inoculation of heterogenic type II en (CII), rats mount both humoral and cellular responses to the antigen (Brand et al., 2003). This sensitization subsequently leads to the host animal attacking its own type II collagen, which is predominantly present in the joint cartilage and hence s in erosive or non-erosive joint destruction. The pathophysiology of the disease is highly orchestrated and complex. Upon ion, rats experience inﬂammatory pain and swelling, cartilage degradation, synovial hyperplasia, pannus formation, mononuclear cell inﬁltration, deformity, and immobility.

In the CIA studies described herein, rats started to show the pathognomonic signs of arthritis on day 9 post-priming ed by a progressive increase in severity that ched near u on days 19 to 21. These symptoms were mitigated by oral treatment of an immune suppressant—Methotrexate and also the novel l compositions - AlpiniazPepper (AP) and Alpinia:Magnolia:Kochia (AMK). All treatment groups (Methotrexate, AP and AMK) showed measurable relief in arthritis severity, swelling, ankle width, and pain sensitivity when compared to the vehicle-treated diseased rats. When data for arthritis severity, paw thickness, and ankle diameter were pooled er for the duration of the study period from day 10 to 21 (where visible signs of arthritis were observed), CIA rats treated with Methotrexate, AMK and AP showed statistically signiﬁcant reductions in all ofthe cardinal signs of arthritis suggesting their application for symptomatic relief of arthritis.

Finlayson Reference No.: 838-1423 Catabolic TNF-OL and lL-lB are the two primary cytokines involved in the initiation and ssion of arthritis (Kapoor el al.; 2011); mainly through (a) inhibition of anabolic activities of chondrocytes; leading to downregulation of extracellular matrix component biosynthesis; (Saklatvala et al.; 1986; Goldring el al.; 1994); (b) induction of additional catabolic cytokines (such as IL-6); chemokines; and extracellular matrix degrading enzymes (MlVlPs and aggrecanases) (Lefebvre et al.; 1990; Guerne el al.; 1990); (c) tion of anti-oxidant activity of the host (Mathy-Hartert;et al.; 2008); and (d) induction of reactive oxygen species (Lepetsos el al.; 2016).

These processes facilitate maintenance of the catabolic processes of tis; indicated by chronic ation and perpetual joint destruction in arthritic patients. For example; while injection of IL-lB into the knee joints of rats caused joint inﬂammation and marked proteoglycan depletion (Chandrasekhar el al.; 1992; Bolon el al., 2004); its de reversed the catabolic process en el al.; 1999; Kobayashi el al.; 2005; van de Loo el al.; 1992). Besides direct involvement in the catabolic ation process and cartilage degradation; dysregulation of IL- 6 levels is also linked to the common clinical manifestations associated with rheumatoid arthritis pathology; such as fever; fatigue; and weight loss (Wei et al.; 2015). Hence; modulating these catabolic pro-inﬂammatory cytokines at various stages of disease progression could shift the balance of arthritis away from catabolic ses while alleviating the symptoms ated with arthritis and/or helping to modify the disease. The regulation of homeostasis of chondrocytes; extracellular ; articular cartilage; and the phenotype of arthritis from AlpiniazPepper (AP) and AlpiniazMagnoliazKochia (AMK) that was observed in this CIA study and above other examples could be in part due to inhibition of these key catabolic pro-inﬂammatory cytokines.

Supplementation with AMK for three weeks resulted in a signiﬁcant reduction in the level of fundamental matrix proteolytic enzymes; such as MlVIP-13. Along with aggrecan breakdown; degradation of collagen is a central feature or phenotype of arthritis. Pro-inﬂammatory nes; such as TNF-d; lL-lB, and IL-6 are known to play ant roles in cartilage matrix degradation in lar cartilage through a cascade of catabolic events that leads to stimulation of aggrecanase and matrix metalloproteinase production (Kapoor el al.; 2011). During the course of disease pathology; the major ompatibility complex presents these fragments to T cells and promotes the activation and release of large amounts of inﬂammatory cytokines; such as IL-lB and 1L-6; which in turn ses expression levels of other MlVlPs in the chondrocytes and synovial Finlayson Reference No.: 23 ﬂbroblasts. Consequentially, these catabolic processes result in the phenotype of arthritis with augmented collagenase activity and worsening ofjoint inﬂammation. MMP-l3 has been found in increased levels at the sites of cartilage erosion in cases of rheumatoid arthritis and osteoarthritis (Rose el al., 2016). Previous studies have shown that these MIVIP levels in OA patient’s blood and synovial ﬂuid were higher than in healthy people and the level was consistent with the extent of cartilage damage (Yamanaka el al., 2000, Galil el al., 2016). In fact, MIVIPs ed into the synovial ﬂuid can directly degrade the cartilage and bone composition, leading to enhanced damage of surrounding articular structures (Ma el al., 2015). In our study, there was signiﬁcant suppression of MMP-l3 levels by AMK and AP, which provided protection of cartilage from degradation, improved pain relief and suppression of the phenotype of tis. The reduction in MIVIPs ob served in this study could partially be explained by (a) the effect of treatment materials in reducing the catabolic pro-inﬂammatory cytokines and/or (b) the activity of ent materials directly suppressing expression of these matrix degrading enzymes.

Urine C-terminal telopeptide oftype II collagen (uCTX-II) has been by far the most studied and frequently referred to biomarker of age degradation that could be used for the purpose of diagnosis, determining the severity of disease or extent of disease progression, prognosis, and monitoring efﬁcacy of treatment rgaard et al., 2006). In clinical studies, high levels of uCTX-II are a good predictor of increased risk of joint destruction (Garnero el al., 2001).

Degradation and loss of articular cartilage are ental phenotypes of arthritis, whereby increased CTX-II levels directly correlated with the time course of paw swelling and arthritis severity indicated by the narrowing of joint space and loss of total cartilage volume. Our s were in accord with previous s (Oestergaard el al., 2006, Siebuhr el al., 2012). In the current study, substantiating the beneﬁcial effects of azPepper (AP) and Alpinia:Magnolia:Kochia (AMK) on reduction of paw swelling, paw thickness, tis severity, and decrease of proinﬂammatory cytokines and matrix degrading enzymes, rats treated with AP and AMK showed signiﬁcantly reduced levels of uCTX-II. These ﬁndings indicated that cartilage protection activity is one of the primary functions of AP and AMK, suggesting their usage in regulating homeostasis of chondrocytes, extracellular matrix, lar cartilage, and phenotype of arthritis.

Together with symptoms and biomarkers, histopathological es of articular age, synovial ne, and subchondral bone have been used to evaluate arthritis disease progression Finlayson Reference No.: 838-1423 and outcomes of therapeutic interventions (Chen et al., 2017). In these CIA studies, signiﬁcant improvements in maintenance of the articular structural integrity of rats d with AMK, AP and Methotrexate were observed. These effects were demonstrated in the athology data as exhibited by limited loss, ration, or is of ocytes, smoother articular cartilage surface, deeper and uniform stain of intracellular matriX, and close to normal contour of the ndral bone. The changes in magnitude of histopathological severity scores for: 1. cartilage degradation, 2.bone damage, 3. inﬂammation, and 4. matriX integrity were computed and it was found that AMK and AP treatment resulted in 65.1% and 57.7%, 73.1% and 61.0%, 8.2% and 67.0%, and 61.9% and 47.5% inhibition, respectively, for each e, when compared to vehicle-treated CIA rats.

Collectively, in these CIA studies, AMK and AP orally administered produced (a) reduced catabolic inﬂammation as reﬂected by reduced arthritis index, paw ess, paw edema, and reduced catabolic cytokines (IL-13, IL-6, and TNF-d), (b) decreased pain sensitivity, (c) increased cartilage sparing activity and maintenance of articular structure as indicated by lower uCTX-II and cartilage degrading enzymes (MMP-13) and (d) improved cartilage synthesis and repair (as documented in the increased level of PIIANP). These properties of AMK and AP suggest their ial applications as ative natural therapies for arthritis management by maintaining the normal homeostasis of cartilage and enhancing anabolic phenotype of arthritis.

Example 59. odoacetate induced experimental osteoarthritis model induction and AMK treatment The MIA-induced OA disease model in rats is a standardized model most frequently used to mimic human OA (Lee el al., 2014). The model involves inoculation ofMIA into a femorotibial joint pocket that induces pain ses in the ipsilateral limb accompanied by progressive age degradation. Intra-articular injection of MIA disrupts chondrocyte glycolysis by inhibiting glyceraldehydephosphatase dehydrogenase and s in chondrocyte death, neovascularization, subchondral bone necrosis and collapse, as well as inﬂammation (Guzman et al., 2003). These phenotypic characteristics make the model very attractive to evaluate compounds for their anti-inﬂammatory, analgesic and/or potential disease-modifying activities as it shares similar disease pathology to the human 0A. As a result, we selected this validated in vivo model Finlayson Reference No.: 838-1423 to investigate the effect of AMK in mitigating pain ivity, regulating the phenotype of joint tissue and maintaining articular structural ity after being administered orally for 6 weeks.

Treatment started a week before MIA injection. Animals were randomized into ﬁve groups of 10 rats per group as G1 = normal, G2 = vehicle (0.5% CMC-Na solution), G3 = enac (10 mg/kg, Lot # W08BO43, Ward Hill, MA), G4 = AMK (100 mg/kg) and G5 = AMK (300 mg/kg), were orally gavaged with respective treatment. On the induction day, isoﬁurane (Lot #B66H15A, l Enterprise Ltd. Andhra Pradesh, India) etized rats were injected with 0.8 mg ofMIA (Lot # AO352046, Acros Organics, New Jersey, USA) in 50 uL saline solution into the intra-articular pocket of left femorotibial (knee) j oint using 26 G needle an hour after treatment.

Normal l rats were injected with an equal volume of saline. Paw withdrawal thresholds as a result of constant pressure applied to the affected joint as a measure of pain sensitivity were taken once a week using Randall-Salitto Anesthesiometer (IITC, USA) and treatment lasted for 6 weeks.

Body s were measured once a week to calculate the tive weekly dosage of each group.

Urine was collected at the end of study using metabolic cages. Blood samples were collected to isolate serum for biomarker analysis. At necropsy, animals were asphyxiated with C02 and the femorotibial joint was lly ted out, ﬁxed in 10% buffered formalin and sent to Nationwide Histology (Veradale, WA, USA) for further histopathology analysis. The ﬁxed specimens were then decalciﬁed with Calci-Clear Rapid for 1 and a half days and embedded in parafﬁn. Standardized 5 um serial sections were obtained at the medial and lateral ndylar level in the sagittal plane and were stained with hematoxylin and eosin (HE) and Safranin O-fast green to enable evaluation of proteoglycan t. A modiﬁed Mankin system (Mankin et al., 1981) was used to score structural and cellular alterations of articular components as indications of disease progression and/or treatment efﬁcacy. The histological is was conducted by a certiﬁed Pathologist at Nationwide Histology.

Example 60. Anti-pain sensitivity activity of ition AMK in MIA-induced 0A model Pain, one of the main cardinal symptoms of 0A, was evidenced a week following model induction. As seen in Table 46, rats with an intra-articular injection of MIA without treatment showed a progressive increase in pain sensitivity as exhibited by the mean pain sensitivity values.

Compared to the vehicle-treated normal control animals, rats with intra-articular O. 8 mg/joint MIA showed 34.6, 37.3, 41.4, 41.9 and 42.7% increases in pain sensitivity from week-1 to week-5, Finlayson Reference No.: 838-1423 respectively. In contrast, all treatment groups showed tically signiﬁcant inhibition in pain sensitivity for all the weeks (Table 46). The highest inhibition in pain sensitivity was observed for rats treated with 300 mg/kg of the composition AMK. These reductions were compared against the vehicle-treated group and found to be 21.8%, 28.3%, 35.0%, 39.4% and 43.9% from week 1 to week-5, tively, for rats treated with AMK composition at oral doses of 300 mg/kg/day.

Rats administered with AMK at 100 mg/kg experienced 14.1%, 15.9%, 22.1%, 24.0% and 23.5% reductions in pain sensitivity from week 1 to week-5, respectively, when ed to vehicle- treated MIA rats. The observed pain relief was statistically signiﬁcant at each data point examined for both the dosages. enac, the positive control, showed 19.7%, 24.1%, 28.3%, 30.8% and 31.1% reduction in pain sensitivity from week 1 to week-5, respectively, when compared to vehicle-treated MIA rats.

Table 46. Compression threshold for MIA-injected rats treated with AMK composition Knee ssion ivity (Mean i SD) Grou1’ (mg/kg) Wk—0 Wk—l Wk—2 Wk—3 wk—S Normal 243.9:22 243.0: 242.1:4.2* Control (0.05) (74.4) MIA 0 138.8:14 182.0::1.1* D.IC 0 e1 f nac (311) 171.4:3.1* (23.5) 199.8::3.7* (43.9) *P£0.00001. Values in the parenthesis are percent inhibition against vehicle treated MIA rats Example 61. Cartilage protection and a reduction in proinflammatory cytokine activity by composition AMK in MIA-induced rat arthritis model ELISA assays for the detection of urinary CTX-II and IL-6 were described in the above examples. In this duced rat arthritis model, rats treated with AMK at 300mg/kg orally resulted in statistically signiﬁcant reductions in the cartilage degradation biomarker urinary CTX- son Reference No.: 838-1423 11 and the catabolic cytokine IL-6. When compared to vehicle-treated MIA rats, these reductions were found to be 31.9% and 22.5% for the AMK-treated rats at 300 mg/kg, respectively. At the lower dose of AMK (i.e. 100 mg/kg), there was a statistically signiﬁcant reduction in serum lL-6.

The Diclofenac-treated group (the positive control used for this model), followed a similar pattern to the lower dose of AMK (i.e. signiﬁcant reduction in IL-6 with no impact on the urinary CTX- Table 47. Changes in ne and cartilage degradation marker after AMK treatment in MIA model CTX-II Group (ng/g protein) Normal 282.3 :: 39.8 Control :3l.0 P S 0.05 vs Vehicle; >X”le S 0.00] vs Vehicle Example 62. Improved histological findings as a result of composition AlpiniazMagnoliazKochia (AMK) in MIA-induced 0A model Complementing the pain sensitivity reduction data, statistically signiﬁcant improvements in lar cartilage matrix integrity were shown as reﬂected by the modiﬁed total Mankin score for animals treated with composition AMK at both the dosages. Structural abnormalities and ﬁbrovascular proliferation were also cantly reduced in AMK . When the l structural abnormalities ( cartilage thickening or thinning, surface irregularity, ﬁssure loss, degeneration, ulcerative necrosis, sever anization and chaotic appearance) were assessed, reductions of 41 . l%, 33 . l%, and 87.0% were observed for rats treated with Diclofenac (10 mg/kg), AMK (100 mg/kg) and AMK (300 , respectively, (Table 48). The highest inhibition (72.5%) in catabolic inﬂammation and inﬁltration of inﬂammatory cells was observed for rats treated with AMK at 300 mg/kg as compared to the 42.8% from the Diclofenac group.

Finlayson Reference No.: 838-1423 The extent of osteoclast ties and ndral bone damage were minimal in MIA rats treated with AMK and the positive control drug. In contrast, various degrees of histopathological changes, including cellular degeneration and disorganization of the articular cartilage chondrocytes, depletion and collapse of the intracellular matrix, articular surface irregularities, osteophyte remodeling, and ﬁbrillation of the ndral bone, were ed for MIA-injected rats treated with vehicle. These changes in MIA rats were similar to the most common ﬁndings in human OA biology (Loeser el al., 2013). In Safranin -O staining, articular cartilage of AMK- treatment groups revealed minimum loss of staining intensity, indicating its ability to spare cartilage degradation. For instance, reductions of 34.6%, 31.0%, and 70.7% were observed in matrix GAG loss for Diclofenac (10 mg/kg), AMK (100 mg/kg), and AMK (300 , respectively. Rats in the normal control groups treated with vehicle t MIA showed negligible s in all the parameters examined. Closer to normal structure of the articular cartilage, subchondral bone of both tibia plateaus and femoral bone, and the surrounding joint structure appeared intact in this group of rats.

Table 48. Modiﬁed Mankin scores from histopathological ﬁndings for MIA-induced rats treated with azMagnoliazKochia (AMK) Cartilage . GAG Loss Bone Erosion Inﬂammation destruction (Mean i SE) (Mean i SE) (Mean i SE) :0.45*** 0.50::0.26*** 0.50::0.l6*** (89.4) (90.4) 4.71:: 0.07 5.20 :: 0.28 : 057* 3.08 :: 050* (34.6) (40.8) 4.54 0.42** 3.25 0.32** 3.42 038* (33.1) (31.0) (34.2) 0.88::0.35*** 1.38::0.25*** 0.54:0.29*** (70.7) (89.6) *P s 0. 05,- **P s 0. 001,- 7P 5 0.00001 Example 63. Significance of outcome from the MIA model for Composition AlpiniazMagnoliazKochia (AMK) and its implication in 0A Finlayson Reference No.: 838-1423 It is believed that at various stages of OA, all the three major structures of the joint (cartilage, ndral bone and synovium) could be involved in the pathophysiology of the disease, which complicates the identiﬁcation of a single biomarker that is tive of a need for immediate therapeutic intervention at the early stage of the disease. Nevertheless, among all the major joint biomarkers observed, C-terminal telopeptide of type II collagen (CTX-II) has been by far the most studied and frequently referred to ker of cartilage degradation, and could be used for the purposes of diagnosis, determining the severity of disease or extent of disease progression, prognosis and monitoring the efﬁcacy of treatment. CTX-II is primarily generated by matrix metalloproteinase activity during cartilage degradation in OA. It is known to show a close link with the catabolic/anabolic homeostasis and progression of lar cartilage degradation in OA patients. The direct correlation of CTX-II levels increased in serum, urine or synovial ﬂuid level and articular cartilage degradation were reported both in pre-clinical and clinical studies (Oestergaard el al., 2006, Garnero el al., 2001), suggesting that plant extracts with inherent teristics of reducing uCTX-II levels changed the phenotype of tis toward reduced catabolic degradation and increased anabolic regeneration and rebuilding by regulating homeostasis of chondrocytes, extracellular matrix, and lar age.

Coupled with symptoms and biomarkers, histopathological analyses of articular cartilage, synovial membrane, and subchondral bone have been used to evaluate OA disease progression or to measure outcome of therapeutic interventions (Goldring el al., 2000). In the current disclosure, signiﬁcant ements to maintenance of the articular ural integrity of rats treated with the example, but not limited to, AMK composition were ed. These effects were trated in the histopathology data as exhibited by limited loss, degeneration, or necrosis of chondrocytes, er articular cartilage surface, deeper and uniform stain of intracellular matrix, and close to normal contour of the subchondral bone. For obvious reasons, this l cartilage degradation was also supported by the signiﬁcant reductions in pain sensitivity whereby the AMK composition achieved maximum pain relief. rmore, as demonstrated by the urine CTX-II ker data, a statistically cant reduction in the level of uCTX-II was also observed for rats treated with the composition AMK. Substantiating this statement in human clinical studies, urine CTX-II levels were well aligned with cartilage degradation and associated pain in OA patients. For example, urinary CTX-II concentrations were found elevated and associated with knee pain and function in subjects who underwent anterior cruciate ligament son nce No.: 838-1423 reconstruction. In these ts, sed uCTX-II concentrations were correlated with decreased knee pain and improved on, providing meaningful prognosis (Chmielewski et al., 2012). Similarly, in a cross-sectional evaluation of biochemical markers of bone, cartilage, and synovial tissue metabolism in patients with knee osteoarthritis, uCTX-II was found signiﬁcantly increased corresponding to disease severity and was correlated with changes in joint space narrowing (Garnero el al., 2001).

Considering the multifactorial nature of OA, it has previously been suggested that the ability to slow the progression of articular cartilage degeneration is more likely with a combination therapy than with any single component alone (Lippiello el al., 2000). The composition of bioactive standardized extracts from special blending ratios of Alpinia galanga, Magnolia aﬁcinalis, Piper nigrum, and Kochia scoparia may suit very well in this application. In fact, when the merit of formulating these two or three plant extracts was tested in the carrageenan-induced rat paw edema model, unexpected synergy in alleviating pain sensitivity was observed from the ation of these two or three plant extracts, exceeding the ted result based on simply summing the effects observed for each of its constituents. Clinical and pre-clinical literature searches failed to predict the current sure of these plant extracts blended together as the compositions described in this patent. This signiﬁes the y of the composition in maintaining articular structural integrity as reﬂected by the reduced uCTX-II levels accompanied by minimal pain sensitivity here again in this MIA-induced arthritis model. We believe that these medicinal plants may have complementary effects in regulating homeostasis of chondrocytes, extracellular matrix, lar cartilage, and phenotype of tis that lead to the prevention of articular cartilage degradation and the tion of associated symptoms, which could be translated to improved joint integrity, mobility and function. e 64. Anti-pain activity of topically d plant extracts in a hot plate test Repeated application of anti-inﬂammatory compounds or ts topically at the site of thermal contact (noxious stimulus) may cause itization of the peripheral afferent pain receptors to produce a delay in response time. A longer change in reaction time could be interpreted as an anti-nociceptive effect of the applied compound. To evaluate whether prepared plant extracts and compositions could provide anti-nociceptive activity, rats received orally-active anti- inﬂammatory extracts formulated in 2% aloe vera gel at 5% concentration topically on their hind Finlayson Reference No.: 838-1423 paws. The d preparations on each paw were massaged at least 60 times in a circular motion into the skin until the d content appeared visually absorbed. The procedure was repeated 3 times, every 30 minutes, before g the animals on a preheated hot plate set to 53°C. The paw withdrawal y was calculated as the time elapsed from the l placement of the rat onto the hotplate to the withdrawal (or licking or shaking) of the hind paw in response to the thermal stimulus. Animals were immediately removed when this response was observed. Those animals that did not display a response within 30 seconds were removed from the heated plate to prevent any tissue damage.

The anti-pain activity of medicinal plant extracts was tested on a hot plate set at 53°C. Test materials at 5% concentrations were topically applied at 20ul/paw to the hind paws of both right and left paws of Sprague Dawley rats (n=10 per group). Applications of these extracts were carried out every 30 minutes for a total of 90 minutes. Within these 90 minutes, rats received a total of 60ul/paw of the test e per rat. At 5% concentration, each rat ed 3mg/paw of the test articles. Due to the solubility characteristics of the compounds, two types of vehicles, Vl= Dimethyl sulfoxide (DMSO) + propylene glycol (PG) + Aloe (2%), and V2 = DMSO + OIL + PG, were used. Percent changes and P-values for statistical signiﬁcance were determined using tive vehicles for each test material. The vehicle used for each material has been indicated in the parenthesis next to the test material. As depicted in Table 49, below, rats topically given pure Piperine showed 32.6% increase in paw withdrawal latency as compared to vehicle. This increase in anti-pain activity was similar to what was observed for the 5% ibuprofen (i.e. 22.4% increase in paw y with 0.018 P-value). These increases in anti-pain activity were statistically signiﬁcant.

Alpinia a from ethanol extract and ritical ﬂuid extract- treated s showed 17.1% and 32.8% increase in paw withdrawal latency with P-values 0.063 and 0.02, respectively. The Capsaicin-treated rats experienced 36.7% decrease in paw withdrawal latency. This percent change was statistically signiﬁcant when compared to its respective vehicle. Those rats that received topical preparations ofMagnolia lis showed 13.6% increase in sensitivity as compared to the respective vehicle controls.

These s indicate that fen (positive control) and Alpinia galanga extract ted signif1cant anti-nociceptive activities as evidenced by increased paw withdrawal latency in the hot plate test. Capsaicin (negative control) signiﬁcantly decreased the paw withdrawal Finlayson nce No.: 838-1423 latency, as expected. Alpim'a galcmga extract could be utilized for topical pain relief for various indications.

Table 49: Paw awal threshold as a measure of anti-pain activity of medicinal plants in a hot plate test Group Dose (%) N Mean :: SD % Change C es e-l (V1) DMSO+PG+Aloe (2%) 10 7.13::1.25 - - Vehicle-2 (V2)-R1 DMSO OILb PG 10 6.01::0.74 - - Vehicle-2 (V2)-R2 DMSO OILb PG 10 4.88::0.96 - - Ibuprofen (V1) 5% 10 8.732137 -22.4 0.018 Ibuprofen (V2)-R2 5% 10 6.052198 -23.98 0.03 Capsaicin (V1) 0.5 10 4.512112 36.7 0.0002 Diclofenac (V1) 1 10 50 2.8 0.763 Menthol (V1) 5 10 6.052170 15.1 0.144 Ben-Gay OTCa 10 7.002193 1.8 0.868 ia oﬁ’lcinalis (V1) 5 10 6.162137 13.6 0.135 Alpim'a galanga (V1) 5 10 8.352136 -17.1 0.063 Alpim'a galanga (C02 ext) (V2)-R2 5 10 6.48:: -32.79 0.02 Piperine (V2)-R1 5 8 7.9722186 -32.6 0.011 a OTC = over-the-counter product that contains Camphor, menthol and methyl salicylate at 5%, %, and 30% concentrations, respectively. b OIL = Medium chain triglyceride (MCT) oil derived from coconut oil C While the negative percent changes in the table are indications of increased paw awal latency and hence increase pain relief, the ve percent changes reﬂect increased sensitivity. run l /run2 Example 65. A 7-day repeated oral acute Maximum Tolerable Dose (MTD) Study of AP Purpose-bred male and female CD-1 mice were purchased from Charles River at 8 weeks of age and used for the Maximum Tolerable Dose study. Following acclimation, mice were Finlayson nce No.: 838-1423 randomly assigned based on their body weight to the following respective groups: Gl=Vehicle control (0.5% CMC), G2=Alpinia + pepper at 500 mg/kg and G3=750 mg/kg. Ten mice were placed in each group for this study. The test compound was suspended in 0.5% CMC and administered to mice at a volume of mouse. The vehicle group received 0.5% CMC. At baseline, the average body weights were 36.1 :: 2.5 and 28.2 :: 2.1 grams, for male and female mice, respectively. Body weights were monitored for a total of 4 measurements (i.e. baseline, 2, 3- and 7-days post nge) after gavaging. Each group of mice were monitored for their physical activity and behavior after gavaging every day in both studies.

Table 50: Body weight measurements of mice treated with AP for 7-days Male (Mean =3 SD) Female (Mean :: SD) Group N (mg/kg) Vehicle 36.5:25 37.2:23 37.6::2.6 281:_2l 29.1:19 6 AP 500 10 35.7:23 35.3:39 36.8::3.8 28.2:_23 27.5:2.1 26.9:24 AP 750 10 36.3::2.2 37.2::2.6 35.7:37 28.2::1.7 28.3:20 2.2 Mice received these dosages for 7 consecutive days. No death was observed for the females in either of the AP dosage groups. However, 3 deaths occurred in male mice at the 750 mg/kg AP group on 2, 3- and 7-days post challenge. Gastric irritation and hage were observed in the deceased animals at \Iecropsy. At the end of the study, there were no cant body weight changes for the surviving males in the 750 mg/kg and 500 mg/kg AP groups (i.e. e BL=36.5 :: 2.5 vs 7dpc=37.6 :: 2.6, 500 mg/kg AP BL=35.5 :: 2.8 vs 7dpc=36.8 :: 3.8, 750 mg/kg AP BL=36.3 :: 2.2 vs 35.7 :: 3.7). In contrast, for the females, after 7-days of daily oral AP treatment, the t body weight changes from the baseline were found decreased by 5.18 and 6.07% for the 500 and 750 mg/kg AP, respectively (i.e. i.e. Vehicle BL=28.l :: 2.1 vs 7dpc=28.8 :: 1.6, 500 mg/kg AP BL=28.2 :: 2.3 vs 7dpc=26.9 :: 2.4, 750 mg/kg AP BL=28.2 :: 1.7 vs 7dpc=26.7 :: 2.2).

These body weight changes were statistically signiﬁcant when compared to the vehicle group.

Table 51: Percent body weight changes of mice in a 7-day repeated daily oral MTD study son Reference No.: 838-1423 Study % Bodyweight change at end of study* duration 7-days Male Female p-values values Vehicle 10 7-days 2.83 7-days 3.09 0.91 -5.18 0.02 >X<Negative numbers indicate percent reduction in body weight from baseline.

P-values were compared to vehicle The surviving mice physically appeared normal after each gavage for both s. The mice continued normal exploratory activity and behavior. These normal behaviors were ued for the remaining doses for both genders. These mice showed no changes in behavior or ty for the whole duration of treatment. At sy, once the abdominal cavity was opened, the organs were subjected to gross examination for the surviving animals. No macroscopic (grossly visible) ions from normal were observed. The appearance and Necropsy ﬁndings were comparable to the vehicle group.

According to the global pharmaceutical initiatives for MTD (Chapman et al., 2013), a 10% body weight loss at the end of a 7-day daily oral treatment from baseline would be considered a warning sign of toxicity. At the end of the current study, male and female CD-1 mice treated with oral doses of 500 mg/kg and 750 mg/kg AP showed less than 10% changes in their body weight from the baseline, while there were 3 animal deaths in the 750 mg/kg groups. As a result, we believe the MTD of AP composition is between 500 — 750 mg/kg.

Example 66. A 7-day repeated oral acute Maximum ble Dose (MTD) Study ofAMK Purpose-bred male and female CD-1 mice were purchased from Charles River at 8 weeks of age and used for the Maximum Tolerable Dose study. Following ation, mice were randomly assigned based on their body weight to two experiments. The ﬁrst experiment included Finlayson nce No.: 838-1423 the following groups: icle control (5% DMSO + 0.5% CMC), and G2: AlpiniazMagnoliazKochia (AMK) at 2000 mg/kg. Eight mice were placed in each group for this study. The test compound was suspended in 5% DMSO + 0.5% CMC and administered to mice at a volume of 350ul/mouse. At ne, the average body weights were 36.7 :: 3.5 and 30.4 :: 2.5 grams, for male and female mice, respectively. Body weights were monitored for a total of 3 ements (i.e. baseline, 3 days post challenge and 7 days post challenge) after gavaging. Each group of mice was monitored for their al activity and behavior after gavaging every day in both studies.

Both male and female mice were observed daily for 7 days for their physical appearances and behavior in both studies. Daily examination of mice for their physical condition and ing showed no signs suggestive of toxicity or abnormality throughout the study period. Mice physically appeared normal after each gavage for both genders. The mice continued normal exploratory activity and or. These normal behaviors were continued for the remaining doses for both genders. The mice showed no changes in behavior or activity for the whole duration of treatment.

Table 52: Body weight measurements of mice treated with AMK for 7-days Male (Mean : Female (Mean :: SD) -"n37.0::3.6 37.8::3.6 37.7::3.6 3.0 30.1:23 30.7:30 2000 “366:4.2 36.8::4.4 37.0:45 30.4:20 30.2:13 30.7:13 As seen above, a similar pattern of body weight gain was observed for both genders and treatment groups. The rate of body weight gain was similar for both treatment groups for both genders. There were no statistically signiﬁcant differences in body weight gain for either group.

All mice in each group continued to maintain body weight for the duration of the study. By the end of the 7th day, the ence in body weight measurements between the baseline and the 7th day was insignif1cant (i.e. Male BL: 36.58 :: 4.2 vs day7:36.96 :: 4.5, Female BL: 30.37 :: 2.0 vs day7:30.66 :: 1.3).

Finlayson Reference No.: 838-1423 Table 53: Percent body weight changes of mice in a 7-day repeated daily oral MTD study Study % ight change Group duration at end of study (mg/kg) —eM_aleFemale 7-days Male Female Vehicle 7-days -0. 03 M III! No morbidity or mortality was observed for the AMK treated mice. At Necropsy, once the abdominal cavity was opened, the organs were subjected to gross examination. No macroscopic (grossly visible) deviations from the normal were observed. The appearance and Necropsy ﬁndings for this groups were able to the vehicle group.

According to the global ceutical initiatives for MTD (Chapman et al., 2013), a 10% body weight loss at the end of a 7-day daily oral treatment from baseline would be considered as a warning sign of toxicity. At the end of the current study, male and female CD-1 mice in the AMK group showed a comparable and insigniﬁcant body weight change to that of the e group.

Therefore, considering the normal physical ty, behavior and Necropsy ﬁndings in conjunction with maintenance of body weight at the end of the 7th day, it can be concluded AMK administered orally at 2000mg/kg was tolerated through the course of a 7-day treatment in CD-1 mice. Hence, MTD for AMK is considered greater than 2000 mg/kg.

Example 67. Human clinical study of the compositions from the individual extracts of Alpinia, , Magnolia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to, compositions AlpiniazPepper (AP) and AlpiniazMagnoliazKochia (AMK) In a clinical trial such as “A Double-blind Randomized o and Positive Comparator Controlled Trial”, the Efﬁcacy and Safety of etary itions at 10 - 2000 mgs per dose, 2-3 times per day in Osteoarthritic patients will be evaluated. The study will evaluate symptom son Reference No.: 838-1423 relief in pain severity on a 0-10 numeric Visual ue Scale (VAS); changes in pain severity; stiffness and joint function on the WOMAC scale by a subjective questionnaire. Objective measures of symptom improvement will be evaluated at baseline and at the end of the study for the range of motion by BIODEX and the distance walked in six minutes; and safety evaluations are also included. Biomarker measurements will also be d on from the serum; synovial ﬂuid and joint tissues before and after the treatment. The duration of the treatment shall be 1-12 weeks or 6-24 months according to the objective of the clinical output.

Before screening; the subjects must read and sign the IRB-approved Informed Consent Form. The study population consists of male and female ts older than 18 and younger than 75 years, and in general good health as determined by a medical history. Female subjects of childbearing potential must have a negative urine pregnancy test at baseline. The goal of the study is to enroll at least 40 subjects per arm for meaningful statistical power.

The trial will have deﬁned Inclusion criteria as follows: Male/Female healthy adults at 18 to 75 years of age; meet pain entry criteria; a history of knee joint pain for r than 6 months; medial or l tibiofemoral joint line tenderness; eral knee pain 6/10 or greater; on average; on the visual analog scale (VAS); that interferes with function most days per week; Kellgren grade II or III radiographic changes of osteoarthritis; and willing to discontinue use of all analgesic medications (including he-counter [OTC] analgesics) except those provided as the study treatment and rescue medication cally for study purposes.

Primary Objective and Safety Evaluations: 0 Change in Pain Severity on 0-10 cm VAS 0 Change in pain severity; joint stiffness; and joint function on WOMAC Subscale (0-100); Change in WOMAC Total Score of all subscales. o Biomarkers ofuCTX-II for cartilage degradation/protection; anabolic biomarkers ACAN; Sox- 9; PIIANP and TGFB; catabolic nes such as IL-1; IL-6; Na and MMP-13 from the serum and also synovial ﬂuid will be measured. The global gene expression and protein expression proﬁles of cells/tissues from synovial ﬂuid; synovial membrane; and cartilage for changes of catabolic and anabolic markers will be measured.

Finlayson Reference No.: 838-1423 0 The joint space narrowing and total joint space area for ultimate proof of disease-modifying effects will also be measured. 0 Patient global assessment of response to treatment, Physician global assessment of response to treatment Improvement. 0 Change in joint function as measured by active and passive range of , distance walked in the 6-minute walk test. QOL: generic health status measure, the SF-36 and speciﬁc health status measures, the WOMAC 0 Complete Blood Count, Chemistry Panel with liver function tests, PT/INR, HCG and AE assessments.

Data Analysis In this study 10-200 subjects per group, ized equally to receive single or multiple doses of individual extracts of Alpinia, Pepper, ia and Kochia and/or at various combinations of 2 to 3 of those extracts with examples, but not limited to AlpiniazPepper (AP) and Alpinia:Magnolia:Kochia (AMK), a positive control (either NTHE or dietary supplement active), and/or Placebo. If the attrition rate is 30% from the otocol population over the course of the 12-week study, there should be approximately more analyzable subjects per group. A power analysis was d out to determine the effect size (difference between products in mean 12- week changes of efﬁcacy endpoints) that would provide an 80% chance of obtaining a signiﬁcant result of p3005 with total analyzable subjects per group.

The tical design parameters for this study are: 0 Alpha Level: 0.05 (p3005 considered statistically signiﬁcant) 0 Power: 0.8 (an 80% chance of obtaining signiﬁcant p value) 0 Primary Null Hypothesis: Mean treatment duration changes for any supplement will equal the same duration for positive control and/or o 0 Alternate esis: Changes are not equal between products 0 Statistical Test: Analysis of Covariance (power ations based on unpaired Student t test) 0 Sample Size: 120 enrolled subjects, 40 in each product group Finlayson nce No.: 838-1423 Table 54. Study ures Visits mm was Vim -14 0 14:|:1 30 :|:1 60:|:2 90:|:2 Continuance Criteria _- X X Medicat History —->< —--Demography ><>< Height X X X X X X —Chemistry panel with LFT x x CBC with differential, PT/INR Collect blood s for X X Cytokines B-HCG Pregnancy Test WOMAC pain subscale (5 items) Complete WOMAC 3 subscales X X 100 mm VAS Scale Daily Assessment Maximum Distance (feet) X X walked in 6 minutes.

—Concomitant Medications X Adverse Events/ Intercurrent X X X Illness Return Rescue Medication X X X Dispense Test Product X X —Return Test Product _ X Finlayson Reference No.: 838-1423 References 1. Alford JW, Cole BJ. Cartilage restoration, part 1: basic science, historical perspective, patient evaluation and treatment options. Am J Sports Med. 2005;33:295-306 2. Al-Snaﬁ, Ali Esmail, A review on pharmacological activities of Kochia scoparia- a review, Indo American Journal of Pharmaceutical Sciences (2018), 5(4), 2213-2221.

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Embodiments of the ion are described in the ing paragraphs (corresponding to the PCT claims as published). 1. According to a first embodiment of the invention, there is provided a composition for joint health, comprising a combination of an Alpinia t enriched for one or more phenylpropanoids; a Magnolia extract enriched for one or more bisphenolic lignans; and a Kochia extract enriched for one or more triterpenoid saponins. 2. According to a second embodiment of the invention, there is provided the composition as described in aph 1, wherein the Alpinia extract, or Magnolia extract or Kochia extract in the composition are in a range of 1% - 98% by weight of each extract with the optimized weight ratio of Alpinia:Magnolia:Kochia (AMK) at 2:4:3 (22.2%:44.4%:33.3%) or 4:3:3 (40%:30%:30%) or 5:4:4 :30.8%:30.8%). 3. According to a third embodiment of the invention, there is provided the composition as described in paragraph 1, wherein the Alpinia extract is from Alpinia galanga, the Magnolia extract is from Magnolia officinalis and Kochia extract is from Kochia scoparia. 4. According to a fourth embodiment of the invention, there is ed the composition as described in paragraph 1, wherein the a extract is comprised of 0.01% to 99.9% of phenylpropanoids.

. According to a fifth embodiment of the invention, there is provided the composition as described in paragraph 1, wherein the Magnolia extract is comprised of 0.01% to 99.9% of bisphenolic lignans. 6. ing to a sixth embodiment of the ion, there is provided the composition as bed in paragraph 1, wherein the Kochia extract is comprised of 0.01% to 99.9% of triterpenoid saponins. 7. According to a seventh embodiment of the invention, there is ed the composition as bed in aph 1, wherein the one or more phenylpropanoids from the Alpinia extract is 1’-acetoxychavicol acetate, or galangal acetate, or p-hydroxy cinnamaldehyde, or hydroxystilbene or any combination thereof. 8. According to an eighth embodiment of the invention, there is provided the composition as described in paragraph 1, wherein the one or more bisphenolic lignans from the Magnolia extract is magnolol or honokiol, or a combination thereof.

[Link] https://en.wikipedia.org/wiki/Alpinia_galanga [Link] https://en.wikipedia.org/wiki/Alpinia_galanga [Link] https://en.wikipedia.org/wiki/Alpinia_officinarum [Link] https://en.wikipedia.org/wiki/Alpinia_officinarum [Link] https://en.wikipedia.org/wiki/Boesenbergia_rotunda [Link] https://en.wikipedia.org/wiki/Boesenbergia_rotunda [Link] https://en.wikipedia.org/wiki/Boesenbergia_rotunda [Link] https://en.wikipedia.org/wiki/Boesenbergia_rotunda [Link] https://en.wikipedia.org/wiki/Kaempferia_galanga [Link] https://en.wikipedia.org/wiki/Kaempferia_galanga [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_abundiflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_abundiflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_acrostachya&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_acrostachya&action=edit&redlink=1 [Link] //en.wikipedia.org/wiki/Alpinia_caerulea [Link] https://en.wikipedia.org/wiki/Alpinia_caerulea [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_calcarata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_calcarata&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_conchigera [Link] https://en.wikipedia.org/wiki/Alpinia_conchigera [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_javanica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_javanica&action=edit&redlink=1 [Link] //en.wikipedia.org/w/index.php?title=Alpinia_melanocarpa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_melanocarpa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_mutica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_mutica&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_nigra [Link] https://en.wikipedia.org/wiki/Alpinia_nigra [Link] //en.wikipedia.org/wiki/Alpinia_nutans [Link] https://en.wikipedia.org/wiki/Alpinia_nutans [Link] https://en.wikipedia.org/wiki/Alpinia_purpurata [Link] https://en.wikipedia.org/wiki/Alpinia_purpurata [Link] //en.wikipedia.org/w/index.php?title=Alpinia_pyramidata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_pyramidata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_rafflesiana&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_rafflesiana&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_speciosa [Link] https://en.wikipedia.org/wiki/Alpinia_speciosa [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_vittata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_vittata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_vittata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_vittata&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_zerumbet [Link] https://en.wikipedia.org/wiki/Alpinia_zerumbet [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_zingiberina&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_zingiberina&action=edit&redlink=1 9. According to a ninth embodiment of the invention, there is provided the composition as described in aph 1, wherein the one or more triterpenoid saponins from the Kochia extract is Bassiasaponin A; or Bassiasaponin B; or Kochioside A; or Kochioside B; or Kochioside C; or Kochianoside I; or Scoparianos A; or Scoparianoside B; or ianoside C; or in Ic; or Kochianoside I; or Kochianoside II ; or Kochianoside III; or Kochianoside IV; or 2'-O-glucopyranosyl momordin Ic; or 2'-OGlucopyranosylmomordin IIc, or a combination thereof.

. According to a tenth embodiment of the invention, there is provided the composition as described in paragraph 1, wherein the phenylpropanoids are enriched from a plant species selected from the group consisting of Alpinia galanga, Alpinia officinarum, Boesenbergia a, Kaempferia a, Alpinia oxyphylla, Alpinia abundiflora, Alpinia acrostachya, Alpinia caerulea, Alpinia calcarata, Alpinia conchigera, Alpinia globosa, Alpinia javanica, Alpinia melanocarpa, Alpinia mutica, Alpinia nigra, Alpinia nutans, a petiolate, Alpinia purpurata, Alpinia pyramidata, Alpinia rafflesiana, Alpinia speciosa, Alpinia vittata, Alpinia zerumbet, Alpinia zingiberina, or a combination thereof. 11. ing to an th embodiment of the invention, there is provided the composition as described in aph 1, wherein the bisphenolic lignans are enriched from a plant s selected from the group consisting of Magnolia officinalis, Magnolia acuminate, Magnolia biondii, Magnolia coco, Magnolia denudate, ia fargesii, Magnolia garrettii, Magnolia grandiflora, Magnolia henryi, Magnolia liliflora, Magnolia kachirachirai, ia Kobus, ia obovata, Magnolia praecocissima, Magnolia pterocarpa, Magnolia pyramidata, Magnolia rostrate, Magnolia salicifolia, Magnolia sieboldii, ia soulangeana, Magnolia stellate, Magnolia iana, prod. of degradation of birch lignin, Acanthus ebracteatus, Aptosimum spinescens, Aralia bipinnata, Araucaria angustifolia, Araucaria araucana, Artemisia absinthium, Haplophyllum acutifolium, Haplophyllum perforatum, Liriodendron tulipifera, Krameria cystisoides, Perilla cens, Lawsonia inermis Myristica fragrans (nutmeg), Parakmeria yunnanensis (preferred genus name Magnolia), Persea japonica, Piper futokadsura, Piper wightii, Rollinia mucosa, Sassafras randaiense, Scrophularia albida-colchica, Stellera jasme, Syringa velutina, Syzygium cumini, Talauma gloriensis, Virola elongate, Urbanodendron verrucosum, Wikstroemia sikokiana or a combination thereof. 12. According to a twelfth embodiment of the invention, there is provided the composition as described in paragraph 1, wherein the triterpenoid saponins are enriched from a plant [Link] https://en.wikipedia.org/w/index.php?title=Bassia_angustifolia&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_angustifolia&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_angustifolia&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_dinteri&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_eriophora&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Bassia_hyssopifolia [Link] https://en.wikipedia.org/wiki/Bassia_hyssopifolia [Link] https://en.wikipedia.org/wiki/Bassia_hyssopifolia [Link] https://en.wikipedia.org/w/index.php?title=Bassia_indica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_indica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_laniflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_laniflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_lasiantha&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_lasiantha&action=edit&redlink=1 [Link] //en.wikipedia.org/w/index.php?title=Bassia_littorea&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_littorea&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_muricata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_muricata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_muricata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_muricata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_odontoptera&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_odontoptera&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_pilosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_pilosa&action=edit&redlink=1 [Link] //en.wikipedia.org/wiki/Bassia_prostrata [Link] https://en.wikipedia.org/wiki/Bassia_prostrata [Link] https://en.wikipedia.org/w/index.php?title=Bassia_salsoloides&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_salsoloides&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_stellaris&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_stellaris&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_stellaris&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_stellaris&action=edit&redlink=1 [Link] //en.wikipedia.org/w/index.php?title=Bassia_tianschanica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_tianschanica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_tomentosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_tomentosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_villosissima&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Bassia_villosissima&action=edit&redlink=1 species selected from the group consisting of Kochia scoparia, Bassia scoparia, Bassia angustifolia, Momordica cochinchinensis, Bassia dinteri, Bassia eriophora, Bassia hyssopifolia, Bassia indica, Bassia ora, Bassia lasiantha, Bassia littorea, Bassia ta, Bassia odontoptera, Bassia pilosa, Bassia prostrata, Bassia salsoloides, Bassia ris, Bassia tianschanica, Bassia tomentosa, Bassia villosissima or a combination thereof. 13. According to a thirteenth embodiment of the invention, there is ed the composition as described in paragraph 1, wherein the phenylpropanoids, bisphenolic lignans, and triterpenoid saponins. are enriched from a plant part selected from the group consisting of leaves, bark, trunk, trunk bark, stem, stem bark, twigs, tubers, root, rhizome, root bark, bark surface, young shoots, seed, fruit, androecium, gynoecium, calyx, stamen, petal, sepal, carpel (pistil), flower, or any combination thereof. 14. According to a fourteenth ment of the invention, there is provided the composition as described in paragraph 1, wherein the Alpinia t, the ia extract and the Kochia extract in the composition are extracted with any suitable solvent, including supercritical fluid of CO2, water, methanol, ethanol, alcohol, a water-mixed solvent or a combination thereof.

. According to a fifteenth embodiment of the invention, there is provided the ition as described in paragraph 1, wherein one or more phenylpropanoids; one or more bisphenolic lignans; and one or more triterpenoid saponins are enriched individually or in combination by solvent partition, precipitation, distillation, evaporation, column chromatograph with silica gel, XAD, HP20, LH20, C-18, alumina oxide, polyamide and CG161 resins. 16. According to a nth embodiment of the invention, there is provided the composition as described in paragraph 1, wherein the composition further comprises a pharmaceutically or nutraceutically acceptable active, adjuvant, carrier, diluent, or excipient, wherein the pharmaceutical or eutical formulation ses from about 0.1 weight t (wt%) to about 99.9 wt% of active compounds from the 3-extracts composition. 17. According to a eenth embodiment of the invention, there is provided the composition as described in aph 16, n the active, adjuvant, excipient or carrier is selected from one or more of Cannabis sativa oil or C, turmeric extract or curcumin, terminalia extract, willow bark extract, Devil’s claw root extract, Cayenne Pepper extract or capsaicin, Prickly Ash bark extract, philodendra bark extract, hop extract, Boswellia extract, Morus alba extract, Acacia catechu extract, Scutellaria baicalensis extract, rose hips extract, ry extract, green tea extract, Sophora extract, Mentha or Peppermint extract, ginger or black ginger t, green tea or grape seed polyphenols, bakuchiol or Psoralea seed extract, fish oil, glucosamine sulfate, glucosamine hydrochloride, N- acetylglucosamine, chondroitin chloride, chondroitin sulfate, methylsulfonyl methane (MSM), hyaluronic acid, undenatured or denatured collagen, Omega-3 or Omega-6 Fatty Acids, Krill oil, Egg Shell ne (ESM), gamma-linolenic acid, Perna Canaliculus (Green-Lipped Mussel), SAMe, avocado/soybean unsaponifiable (ASU) t, citrus bioflavonoids, Acerola trate, astaxanthin, pycnogenol, vitamin C, vitamin D, vitamin E, vitamin K, vitamin B, vitamin A, L-lysine, calcium, manganese, Zinc, mineral amino acid chelate(s), amino acid(s), boron and boron glycinate, silica, probiotics, Camphor, l, calcium-based salts, silica, histidine, copper gluconate, CMC, betacyclodextrin , cellulose, dextrose, saline, water, oil, shark and bovine cartilage. 18. According to a eighteenth embodiment of the invention, there is provided the composition as described in paragraph 1, wherein the composition is formulated as a tablet, hard capsule, soft gel e, powder, or granule, compressed tablet, pill, chewing gum, sashay, wafer, bar, or liquid form, tincture, aerial spread, semi solid, semi , solution, on, cream, lotion, ointment, gel base or like form. 19. According to a nineteenth embodiment of the invention, there is provided the method as described in paragraph 1, wherein the route of the administration is selected from the group consisting of oral, topical, suppository, enous, intradermic, intragastric, intramuscular, intraperitoneal, and intravenous.

. According to a twentieth embodiment of the invention, there is provided the joint health composition as described in aph 1, comprising a method for treating, managing, promoting joint health in a mammal, comprising administering an effective amount of a composition from 0.01 mg/kg to 500 mg/kg body weight of the mammal. 21. According to a twenty-first embodiment of the invention, there is provided the joint health composition as described in paragraph 1, comprising a method for maintaining lic/anabolic biomarker homeostasis by reducing or controlling lic biomarkers TNF-α, IL-1β, IL-6, anase and matrix metalloproteinase (MMP) - MMP13, MMP9, MMP3, MMP1, uCTX-II and ADAMTS4; and by increasing or enhancing or promoting anabolic biomarkers: SOX 9, TGF-β1, ACAN, , and PIIANP of a mammal. 22. According to a twenty-second embodiment of the ion, there is provided the joint health composition as described in paragraph 1, comprising a method for maintaining cartilage homeostasis, inducing cartilage synthesis (and hence, anabolic effect) and inhibiting the catabolic process of degradation and broken down, protecting extracellular matrix integrity, and joint cartilage, minimizing cartilage degradation, alleviating cartilage breakdown, and initiating or promoting or enhancing cartilage synthesis, cartilage renewal and cartilage rebuild, repairing damaged cartilage, maintaining, rebuilding and repairing extra cellular matrix of joint tissue, revitalizing joints ure, ining steady blood flow to joints, promoting health joints by ting cartilage integrity, balancing anabolic and catabolic processes, maintaining synovial fluid for joint lubrication in a , diminishing the action of enzymes and proinflammatory nes that affect joint health of a mammal. 23. According to a twenty-third embodiment of the invention, there is provided the joint health composition as described in paragraph 1, comprising a method for improving joint movement or physical function, maintaining joint health and mobility into old age, supporting, protecting or promoting joint comfort, alleviating joint pain, reducing joint friction, alleviating joint stiffness, improving joint range of motion or flexibility, promoting ty, reducing inflammation, reducing ive stress, reducing and protecting joint wear and tear, managing or treating osteoarthritis or rheumatoid arthritis, preventing osteoarthritis or toid arthritis, or reversing the progression of osteoarthritis or rheumatoid arthritis; Preventing and treating juvenile rheumatoid arthritis, Still's disease, psoriatic tis, reactive arthritis, septic arthritis, Reiter's syndrome, Behcet's syndrome, or Felty's syndrome or the like of a mammal. 24. According to a twenty-fourth embodiment of the invention, there is provided a composition for joint health, sing a combination of an Alpinia extract enriched for one or more phenylpropanoids; and a Piper t enriched for one or more alkaloids.

. According to a twenty-fifth embodiment of the ion, there is provided the composition as described in paragraph 24, wherein the Alpinia extract, and the Piper extract in the composition is 99:1 to 1:99 in weight . 26. According to a twenty-sixth embodiment of the invention, there is provided the composition as described in paragraph 24, wherein the Alpinia t is from a a, Piper extract is from Piper nigrum.

[Link] https://en.wikipedia.org/wiki/Alpinia_galanga [Link] https://en.wikipedia.org/wiki/Alpinia_galanga [Link] https://en.wikipedia.org/wiki/Alpinia_officinarum [Link] https://en.wikipedia.org/wiki/Alpinia_officinarum [Link] https://en.wikipedia.org/wiki/Boesenbergia_rotunda [Link] https://en.wikipedia.org/wiki/Boesenbergia_rotunda [Link] https://en.wikipedia.org/wiki/Kaempferia_galanga [Link] https://en.wikipedia.org/wiki/Kaempferia_galanga [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_abundiflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_abundiflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_acrostachya&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_acrostachya&action=edit&redlink=1 [Link] //en.wikipedia.org/wiki/Alpinia_caerulea [Link] https://en.wikipedia.org/wiki/Alpinia_caerulea [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_calcarata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_calcarata&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_conchigera [Link] https://en.wikipedia.org/wiki/Alpinia_conchigera [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_javanica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_javanica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_melanocarpa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_melanocarpa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_mutica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_mutica&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_nigra [Link] https://en.wikipedia.org/wiki/Alpinia_nigra [Link] https://en.wikipedia.org/wiki/Alpinia_nutans [Link] https://en.wikipedia.org/wiki/Alpinia_nutans [Link] https://en.wikipedia.org/wiki/Alpinia_nutans [Link] https://en.wikipedia.org/wiki/Alpinia_nutans [Link] https://en.wikipedia.org/wiki/Alpinia_purpurata [Link] https://en.wikipedia.org/wiki/Alpinia_purpurata [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_pyramidata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_pyramidata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_rafflesiana&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_rafflesiana&action=edit&redlink=1 [Link] //en.wikipedia.org/wiki/Alpinia_speciosa [Link] https://en.wikipedia.org/wiki/Alpinia_speciosa [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_vittata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_vittata&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_zerumbet [Link] https://en.wikipedia.org/wiki/Alpinia_zerumbet [Link] //en.wikipedia.org/w/index.php?title=Alpinia_zingiberina&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_zingiberina&action=edit&redlink=1 27. According to a twenty-seventh embodiment of the invention, there is provided the composition as described in paragraph 24 wherein the Alpinia extract is comprised of 0.01% to 99.9% of phenylpropanoids. 28. According to a twenty-eigthth embodiment of the invention, there is provided the ition as bed in paragraph 24 wherein the Piper extract is comprised of 0.01% to 99.9% of alkaloids. 29. According to a twenty-ninth embodiment of the invention, there is provided the composition as described in aph 24, wherein the one or more phenylpropanoids from the Alpinia extract is 1’-acetoxychavicol acetate, or galangal acetate, or p-hydroxy aldehyde, or 3,5-Dihydroxystilbene or any combination thereof.

. According to a thirtieth embodiment of the invention, there is provided the composition as described in paragraph 24, wherein the one or more piperidine alkaloids from the Piper t is Piperine, or ine or isochavicine, or isopiperine, or coumaperine, or Feruperine, or Piperanine, or Piperettine, or Pipersintenamide, or ardine, or Pipernonaline, or Pipertipine or a combination thereof. 31. According to a thirty-first ment of the invention, there is provided the composition as described in paragraph 24, wherein the phenylpropanoids are enriched from a plant species selected from the group consisting of Alpinia a, Alpinia officinarum, Boesenbergia rotunda, Kaempferia galanga, Alpinia oxyphylla, Alpinia abundiflora, Alpinia achya, Alpinia caerulea, Alpinia calcarata, Alpinia conchigera, Alpinia globosa, Alpinia javanica, Alpinia melanocarpa, a mutica, Alpinia nigra, Alpinia , Alpinia petiolate, Alpinia purpurata, Alpinia pyramidata, Alpinia rafflesiana, Alpinia sa, Alpinia vittata, Alpinia zerumbet, Alpinia zingiberina, or a combination thereof. 32. According to a thirty-second ment of the invention, there is provided the composition as described in paragraph 24, wherein the one or more piperidine alkaloids are ed from Piper nigrum, Piper longum, Piper amalgo, Piper aurantiacum, Piper chaba, Piper capense, Piper crassinervium, Piper guineense, Piper methysticum, Piper novaehollandiae , Piper peepuloides, Piper ponapense, Piper lum, Piper retrofractum, Piper ense, Piper tuberculatum, , Piper hancei, Glycine max, Petrosimonia monandra, Mentha ta, silocaulon le, and Ulocladium sp or a combination thereof. 33. According to a thirty-third embodiment of the invention, there is ed the composition as described in aph 24, wherein the phenylpropanoids, and alkaloids are ed from a plant part selected from the group consisting of , bark, trunk, trunk bark, stem, stem bark, twigs, tubers, root, rhizome, root bark, bark surface, young shoots, seed, fruit, androecium, gynoecium, calyx, stamen, petal, sepal, carpel (pistil), , or any combination thereof. 34. According to a thirty-fourth embodiment of the invention, there is provided the composition as described in paragraph 24, wherein the Alpinia extract, the Piper extract in the ition are extracted individually or in combination with any suitable solvent, including supercritical fluid of CO2, water, methanol, ethanol, alcohol, a water-mixed solvent or a combination thereof.

. According to a thirty-fifth embodiment of the invention, there is provided the composition as described in paragraph 24, wherein one or more phenylpropanoids; one or more alkaloids are enriched individually or in combination by solvent partition, precipitation, distillation, evaporation, column chromatograph with silica gel, XAD, HP20, LH20, C-18, a oxide, polyamide, CG161 and ion exchange resins. 36. According to a thirty-sixth embodiment of the invention, there is provided the composition as described in paragraph 24, wherein the composition further comprises a ceutically or nutraceutically acceptable active, adjuvant, carrier, diluent, or excipient, n the ceutical or nutraceutical formulation comprises from about 0.1 weight percent (wt%) to about 99.9 wt% of active compounds from Alpinia and Piper extract ition. 37. According to a thirty-seventh ment of the invention, there is provided the composition as described in aph 36, wherein the active, or adjuvant, or excipient or carrier is selected from one or more of Cannabis sativa oil or CBD/THC, turmeric extract or curcumin, alia extract, willow bark extract, Devil’s claw root extract, Cayenne Pepper extract or capsaicin, Prickly Ash bark extract, philodendra bark extract, hop extract, Boswellia extract, Morus alba extract, Acacia catechu extract, Scutellaria baicalensis extract, rose hips extract, ry extract, green tea extract, Sophora extract, Mentha or Peppermint extract, ginger or black ginger extract, green tea or grape seed polyphenols, bakuchiol or Psoralea seed extract, fish oil, glucosamine sulfate, glucosamine hydrochloride, N-acetylglucosamine, chondroitin chloride, chondroitin sulfate, methylsulfonyl methane (MSM), hyaluronic acid, undenatured or red collagen, Omega-3 or Omega-6 Fatty Acids, Krill oil, Egg Shell Membrane (ESM), gamma-linolenic acid, Perna Canaliculus (Green-Lipped Mussel), SAMe, avocado/soybean unsaponifiable (ASU) extract, citrus bioflavonoids, Acerola trate, astaxanthin, pycnogenol, vitamin C, n D, vitamin E, vitamin K, vitamin B, vitamin A, ne, calcium, manganese, Zinc, mineral amino acid chelate(s), amino acid(s), boron and boron glycinate, silica, probiotics, Camphor, Menthol, calcium-based salts, silica, histidine, copper gluconate, CMC, yclodextrin, cellulose, dextrose, saline, water, oil, shark and bovine cartilage. 38. According to a -eightth embodiment of the invention, there is provided the composition as described in paragraph 24, wherein the composition is formulated as a tablet, hard capsule, soft gel capsule, powder, granule, ssed tablet, pill, chewing gum, sashay, wafer, bar, or liquid form, re, aerial spread, semi solid, semi liquid, solution, emulsion, cream, lotion, ointment, gel base or like form. 39. According to a thirty-ninth embodiment of the invention, there is provided the method as described in paragraph 24, wherein the route of the administration is selected from the group consisting of oral, topical, suppository, intravenous, intradermic, intragastric, intramuscular, intraperitoneal, and intravenous. 40. According to a fortieth embodiment of the invention, there is provided the joint health composition as bed in paragraph 24, comprising a method for treating, managing, promoting joint health in a mammal, comprising administering an ive amount of a composition from 0.01 mg/kg to 500 mg/kg body weight of the mammal. 41. According to a first embodiment of the ion, there is provided the joint health composition as described in paragraph 24, comprising a method for maintaining catabolic/anabolic biomarker homeostasis by reducing or controlling catabolic biomarkers TNF-α, IL-1β, IL-6, anase and matrix metalloproteinase (MMP) - MMP13, MMP9, MMP3, MMP1, uCTX-II and ADAMTS4; and by enhancing and promoting anabolic biomarkers: SOX 9, , ACAN, COL2A1, and PIIANP of a mammal. 42. According to a forty-second embodiment of the invention, there is provided the joint health composition as described in paragraph 24, comprising a method for maintaining cartilage homeostasis, inducing cartilage synthesis (and hence, anabolic effect) and inhibiting the lic process of degradation and broken down, protecting extracellular matrix integrity, and joint cartilage, minimizing cartilage degradation, alleviating cartilage breakdown, and [Link] https://en.wikipedia.org/wiki/Alpinia_galanga [Link] https://en.wikipedia.org/wiki/Alpinia_galanga [Link] https://en.wikipedia.org/wiki/Alpinia_officinarum [Link] https://en.wikipedia.org/wiki/Alpinia_officinarum [Link] https://en.wikipedia.org/wiki/Boesenbergia_rotunda [Link] https://en.wikipedia.org/wiki/Boesenbergia_rotunda [Link] https://en.wikipedia.org/wiki/Kaempferia_galanga [Link] https://en.wikipedia.org/wiki/Kaempferia_galanga [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_abundiflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_abundiflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_acrostachya&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_acrostachya&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_caerulea [Link] https://en.wikipedia.org/wiki/Alpinia_caerulea [Link] //en.wikipedia.org/w/index.php?title=Alpinia_calcarata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_calcarata&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_conchigera [Link] https://en.wikipedia.org/wiki/Alpinia_conchigera [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] //en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_javanica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_javanica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_melanocarpa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_melanocarpa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_mutica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_mutica&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_nigra [Link] https://en.wikipedia.org/wiki/Alpinia_nigra [Link] https://en.wikipedia.org/wiki/Alpinia_nutans [Link] https://en.wikipedia.org/wiki/Alpinia_nutans [Link] https://en.wikipedia.org/wiki/Alpinia_nutans initiating or promoting or enhancing cartilage sis, cartilage renewal and age rebuild, ing damaged cartilage, maintaining, rebuilding and ing extra cellular matrix of joint tissue, revitalizing joints structure, maintaining steady blood flow to joints, promoting health joints by ting cartilage integrity, balancing anabolic and catabolic processes, maintaining synovial fluid for joint lubrication in a mammal, diminishing the action of enzymes and proinflammatory cytokines that affect joint health of a mammal. 43. According to a forty-third embodiment of the invention, there is provided the joint health composition as described in paragraph 24, comprising a method for improving joint movement or physical function, maintaining joint health and mobility into old age, ting, protecting or promoting joint comfort, alleviating joint pain, reducing joint friction, alleviating joint stiffness, improving joint range of motion or flexibility, promoting mobility, reducing inflammation, reducing oxidative stress, reducing and protecting joint wear and tear, managing or treating osteoarthritis or rheumatoid arthritis, preventing osteoarthritis or rheumatoid arthritis, or reversing the progression of rthritis or rheumatoid arthritis; ting and treating juvenile rheumatoid arthritis, Still's disease, psoriatic arthritis, reactive arthritis, septic arthritis, Reiter's syndrome, Behcet's syndrome, or Felty's syndrome or the like of a mammal. 44. ing to a fourth embodiment of the invention, there is provided acomposition for joint health, comprising an Alpinia extract enriched for one or more phenylpropanoids. 45. According to a forty-fifth embodiment of the invention, there is provided the composition according to claim 44, wherein the Alpinia extract is comprised of 0.01% to 99.9% of phenylpropanoids. 46. According to a forty-sixth embodiment of the invention, there is provided the the composition as described in paragraph 44, wherein the one or more phenylpropanoids from the Alpinia extract is 1’-acetoxychavicol acetate, or galangal acetate, or p-hydroxy cinnamaldehyde, or 3,5-dihydroxystilbene or any combination thereof. 47. According to a forty-seventh embodiment of the invention, there is provided the composition as described in paragraph 44, wherein the phenylpropanoids are enriched from a plant species selected from the group consisting of Alpinia a, a officinarum, Boesenbergia rotunda, Kaempferia galanga, a lla, Alpinia abundiflora, a acrostachya, a caerulea, Alpinia calcarata, Alpinia gera, Alpinia globosa, a javanica, Alpinia melanocarpa, Alpinia , Alpinia nigra, Alpinia [Link] https://en.wikipedia.org/wiki/Alpinia_nutans [Link] https://en.wikipedia.org/wiki/Alpinia_nutans [Link] https://en.wikipedia.org/wiki/Alpinia_purpurata [Link] https://en.wikipedia.org/wiki/Alpinia_purpurata [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_pyramidata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_pyramidata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_rafflesiana&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_rafflesiana&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_speciosa [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_vittata&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_zerumbet [Link] //en.wikipedia.org/w/index.php?title=Alpinia_zingiberina&action=edit&redlink=1 nutans, Alpinia petiolate, Alpinia purpurata, Alpinia pyramidata, Alpinia rafflesiana, Alpinia speciosa, Alpinia vittata, Alpinia zerumbet, Alpinia zingiberina, or a combination thereof. 48. According to a forty-eightth embodiment of the invention, there is provided the composition as bed in paragraph 44, wherein the phenylpropanoids are enriched from a plant part ed from the group consisting of leaves, bark, trunk, trunk bark, stem, stem bark, twigs, tubers, root, rhizome, root bark, bark surface, young shoots, seed, fruit, androecium, gynoecium, calyx, stamen, petal, sepal, carpel (pistil), flower, or any ation thereof. 49. ing to a ninth embodiment of the invention, there is provided the composition as described in paragraph 44, wherein the Alpinia extract in the composition are extracted with any suitable t, including supercritical fluid of CO2, water, methanol, ethanol, alcohol, a water-mixed solvent or a combination thereof. 50. According to a th embodiment of the invention, there is provided the composition as described in paragraph 44, wherein one or more phenylpropanoids are enriched by solvent ion, precipitation, distillation, evaporation, column chromatograph with silica gel, XAD, HP20, LH20, C-18, alumina oxide, polyamide, CG161 and ion exchange resins. 51. According to a fifty-first embodiment of the ion, there is provided the composition as described in paragraph 44, wherein the composition r comprises a pharmaceutically or nutraceutically acceptable active, adjuvant, carrier, diluent, or excipient, wherein the pharmaceutical or nutraceutical ation comprises from about 0.1 weight percent (wt%) to about 99.9 wt% of active compounds from the Alpinia extract composition. 52. According to a fifty-second embodiment of the invention, there is provided the composition as described in paragraph 51, wherein the active, adjuvant, excipient or carrier is selected from one or more of Cannabis sativa oil or CBD/THC, turmeric t or curcumin, terminalia extract, willow bark extract, Devil’s claw root extract, Cayenne Pepper extract or capsaicin, Prickly Ash bark extract, philodendra bark extract, hop t, lia extract, Morus alba extract, Acacia catechu extract, Scutellaria ensis extract, rose hips extract, rosemary extract, green tea extract, Sophora extract, Mentha or Peppermint extract, ginger or black ginger extract, green tea or grape seed polyphenols, bakuchiol or Psoralea seed extract, fish oil, glucosamine sulfate, glucosamine hydrochloride, N- glucosamine, chondroitin chloride, oitin sulfate, methylsulfonyl methane (MSM), hyaluronic acid, undenatured or denatured collagen, Omega-3 or Omega-6 Fatty Acids, Krill oil, Egg Shell Membrane (ESM), gamma-linolenic acid, Perna Canaliculus (Green-Lipped Mussel), SAMe, avocado/soybean unsaponifiable (ASU) extract, citrus bioflavonoids, Acerola concentrate, astaxanthin, pycnogenol, vitamin C, n D, vitamin E, vitamin K, vitamin B, n A, L-lysine, calcium, manganese, Zinc, mineral amino acid chelate(s), amino acid(s), boron and boron glycinate, silica, probiotics, r, Menthol, m-based salts, silica, histidine, copper gluconate, CMC, betacyclodextrin , ose, se, saline, water, oil, shark and bovine cartilage. 53. According to a fifty-third embodiment of the invention, there is provided the composition as bed in paragraph 44, wherein the composition is formulated as a tablet, hard capsule, soft gel capsule, powder, granule, compressed tablet, pill, chewing gum, sashay, wafer, bar, or liquid form, tincture, aerial spread, semi solid, semi liquid, on, emulsion, cream, lotion, ointment, gel base or like form. 54. ing to a fifty-fourth embodiment of the invention, there is provided the method as described in paragraph 44, wherein the route of the administration is selected from the group consisting of oral, topical, suppository, intravenous, intradermic, intragastric, intramuscular, intraperitoneal, and intravenous. 55. According to a fifty-fifth embodiment of the invention, there is provided the joint health composition as described in paragraph 44, comprising a method for treating, managing, promoting joint health in a mammal, comprising administering an ive amount of a ition from 0.01 mg/kg to 500 mg/kg body weight of the mammal. 56. According to a fifty-sixth embodiment of the invention, there is provided the joint health ition as described in paragraph 44, comprising a method for maintaining catabolic/anabolic biomarker homeostasis by reducing or controlling catabolic biomarkers TNF-α, IL-1β, IL-6, aggrecanase and matrix metalloproteinase (MMP) - MMP13, MMP9, MMP3, MMP1, uCTX-II and ADAMTS4; and by enhancing and promoting anabolic biomarkers: SOX 9, TGF-β1, ACAN, COL2A1, and PIIANP of a mammal. 57. According to a fifty-seventh embodiment of the invention, there is provided the joint health composition as described in paragraph 44, comprising a method for maintaining cartilage homeostasis, inducing cartilage synthesis (and hence, anabolic effect) and inhibiting the catabolic s of degradation and broken down, protecting extracellular matrix integrity, and joint cartilage, minimizing cartilage degradation, alleviating cartilage breakdown, and initiating or promoting or enhancing cartilage synthesis, cartilage renewal and cartilage rebuild, repairing damaged cartilage, maintaining, rebuilding and ing extra ar matrix of joint , revitalizing joints structure, maintaining steady blood flow to joints, promoting health joints by protecting cartilage integrity, balancing anabolic and catabolic processes, maintaining synovial fluid for joint lubrication in a mammal, diminishing the action of enzymes and proinflammatory cytokines that affect joint health of a mammal. 58. According to a fifty-eightth embodiment of the invention, there is provided the joint health composition as described in paragraph 44, comprising a method for improving joint movement or physical function, maintaining joint health and mobility into old age, supporting, protecting or promoting joint comfort, alleviating joint pain, reducing joint friction, ating joint stiffness, improving joint range of motion or flexibility, promoting mobility, reducing mation, reducing oxidative stress, reducing and protecting joint wear and tear, managing or treating osteoarthritis or rheumatoid arthritis, preventing osteoarthritis or rheumatoid arthritis, or reversing the progression of osteoarthritis or toid arthritis; Preventing and treating juvenile rheumatoid arthritis, Still's disease, psoriatic arthritis, reactive arthritis, septic arthritis, Reiter's syndrome, Behcet's me, or Felty's syndrome or the like of a mammal. 59. According to a fifty-ninth embodiment of the invention, there is ed the joint health composition as described in paragraph 1, comprising a method for improving the health of joints of hand, elbow , wrist joints, axillary articulations, sternoclavicular joints, ral articulations, temporomandibular joints, sacroiliac joints, hip joints, knee joints and articulation of foot. 60. According to a th embodiment of the invention, there is provided the joint health composition as described in paragraph 24, comprising a method for improving the health of joints of hand, elbow joints, wrist joints, axillary lations, clavicular joints, vertebral articulations, temporomandibular joints, sacroiliac joints, hip joints, knee joints and articulation of foot. 61. ing to a sixty-first embodiment of the invention, there is provided the joint health composition as described in paragraph 44, sing a method for improving the health of joints of hand, elbow joints, wrist , axillary articulations, sternoclavicular joints, vertebral articulations, temporomandibular joints, sacroiliac joints, hip , knee joints and articulation of foot.

[Link] //en.wikipedia.org/wiki/Alpinia_galanga [Link] https://en.wikipedia.org/wiki/Alpinia_galanga [Link] https://en.wikipedia.org/wiki/Alpinia_officinarum [Link] https://en.wikipedia.org/wiki/Alpinia_officinarum [Link] https://en.wikipedia.org/wiki/Alpinia_officinarum [Link] https://en.wikipedia.org/wiki/Alpinia_officinarum [Link] https://en.wikipedia.org/wiki/Boesenbergia_rotunda [Link] //en.wikipedia.org/wiki/Boesenbergia_rotunda [Link] https://en.wikipedia.org/wiki/Kaempferia_galanga [Link] https://en.wikipedia.org/wiki/Kaempferia_galanga [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_abundiflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_abundiflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_abundiflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_abundiflora&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_acrostachya&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_acrostachya&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_caerulea [Link] https://en.wikipedia.org/wiki/Alpinia_caerulea [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_calcarata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_calcarata&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_conchigera [Link] https://en.wikipedia.org/wiki/Alpinia_conchigera [Link] https://en.wikipedia.org/wiki/Alpinia_conchigera [Link] https://en.wikipedia.org/wiki/Alpinia_conchigera [Link] //en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_globosa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_javanica&action=edit&redlink=1 [Link] //en.wikipedia.org/w/index.php?title=Alpinia_javanica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_melanocarpa&action=edit&redlink=1 [Link] //en.wikipedia.org/w/index.php?title=Alpinia_melanocarpa&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_mutica&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_mutica&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_nigra [Link] https://en.wikipedia.org/wiki/Alpinia_nigra [Link] https://en.wikipedia.org/wiki/Alpinia_nutans [Link] //en.wikipedia.org/wiki/Alpinia_nutans [Link] https://en.wikipedia.org/wiki/Alpinia_purpurata [Link] https://en.wikipedia.org/wiki/Alpinia_purpurata [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_pyramidata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_pyramidata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_pyramidata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_pyramidata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_rafflesiana&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_rafflesiana&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_speciosa [Link] //en.wikipedia.org/wiki/Alpinia_speciosa [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_vittata&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_vittata&action=edit&redlink=1 [Link] https://en.wikipedia.org/wiki/Alpinia_zerumbet [Link] https://en.wikipedia.org/wiki/Alpinia_zerumbet [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_zingiberina&action=edit&redlink=1 [Link] https://en.wikipedia.org/w/index.php?title=Alpinia_zingiberina&action=edit&redlink=1 What is d: 1. A composition for joint health, comprising an Alpinia extract enriched for one or more phenylpropanoids. 2. The composition according to claim 1, wherein the Alpinia extract is comprised of 0.01% to 99.9% of propanoids. 3. The composition according to claim 1, wherein the one or more phenylpropanoids from the Alpinia extract is 1’-acetoxychavicol acetate, or galangal acetate, or p-hydroxy cinnamaldehyde, or 3,5-dihydroxystilbene or any combination thereof. 4. The composition ing to claim 1, wherein the phenylpropanoids are enriched from a plant species selected from the group consisting of a galanga, Alpinia narum, Boesenbergia rotunda, Kaempferia galanga, Alpinia oxyphylla, Alpinia abundiflora, Alpinia acrostachya, Alpinia caerulea, Alpinia calcarata, Alpinia conchigera, Alpinia globosa, Alpinia ca, Alpinia melanocarpa, Alpinia mutica, Alpinia nigra, a nutans, Alpinia petiolate, Alpinia purpurata, a pyramidata, Alpinia rafflesiana, a speciosa, Alpinia vittata, Alpinia zerumbet, Alpinia zingiberina, or a combination thereof.

. The ition according to claim 1, wherein the phenylpropanoids are enriched from a plant part selected from the group consisting of leaves, bark, trunk, trunk bark, stem, stem bark, twigs, tubers, root, rhizome, root bark, bark surface, young shoots, seed, fruit, androecium, gynoecium, calyx, stamen, petal, sepal, carpel l), , or any combination thereof. 6. The composition according to claim 1, wherein the Alpinia extract in the composition are extracted with any suitable solvent, including supercritical fluid of CO2, water, methanol, ethanol, alcohol, a water-mixed solvent or a combination thereof. 7. The composition according to claim 1, wherein one or more phenylpropanoids are enriched by solvent partition, precipitation, distillation, evaporation, column chromatograph with silica gel, XAD, HP20, LH20, C-18, alumina oxide, polyamide, CG161 and ion exchange resins. 8. The composition according to claim 1, n the composition further comprises a pharmaceutically or nutraceutically acceptable active, adjuvant, carrier, diluent, or excipient, wherein the pharmaceutical or nutraceutical formulation comprises from about 0.1 weight percent (wt%) to about 99.9 wt% of active compounds from the Alpinia extract ition. 9. The ition ing to claim 8, wherein the active, nt, excipient or carrier is selected from one or more of Cannabis sativa oil or CBD/THC, turmeric extract or curcumin, terminalia extract, willow bark extract, Devil’s claw root extract, Cayenne Pepper extract or capsaicin, Prickly Ash bark extract, philodendra bark extract, hop extract, Boswellia extract, Morus alba extract, Acacia catechu extract, Scutellaria baicalensis extract, rose hips extract, rosemary extract, green tea extract, Sophora extract, Mentha or Peppermint extract, ginger or black ginger extract, green tea or grape seed polyphenols, bakuchiol or Psoralea seed extract, fish oil, glucosamine e, glucosamine hloride, N-acetylglucosamine, chondroitin chloride, chondroitin sulfate, methylsulfonyl methane (MSM), hyaluronic acid, undenatured or denatured collagen, Omega-3 or Omega-6 Fatty Acids, Krill oil, Egg Shell Membrane (ESM), linolenic acid, Perna Canaliculus (Green-Lipped ), SAMe, avocado/soybean unsaponifiable (ASU) extract, citrus bioflavonoids, Acerola concentrate, astaxanthin, pycnogenol, vitamin C, vitamin D, vitamin E, vitamin K, n B, n A, L-lysine, calcium, manganese, Zinc, mineral amino acid chelate(s), amino acid(s), boron and boron glycinate, silica, probiotics, Camphor, Menthol, calcium-based salts, silica, histidine, copper gluconate, CMC, betacyclodextrin , cellulose, se, saline, water, oil, shark and bovine cartilage.

. The composition according to claim 1, wherein the composition is formulated as a tablet, hard capsule, soft gel capsule, , e, compressed tablet, pill, chewing gum, sashay, wafer, bar, or liquid form, tincture, aerial spread, semi solid, semi liquid, solution, emulsion, cream, lotion, ointment, gel base or like form. 11. The method according to claim 1, wherein the route of the administration is selected from the group consisting of oral, topical, suppository, intravenous, ermic, intragastric, intramuscular, intraperitoneal, and intravenous. 12. The joint heath composition according to claim 1, comprising a method for treating, managing, promoting joint health in a mammal, comprising administering an effective amount of a composition from 0.01 mg/kg to 500 mg/kg body weight of the . 13. The joint heath composition ing to claim 1, comprising a method for maintaining catabolic/anabolic biomarker homeostasis by reducing or controlling catabolic biomarkers TNF-α, IL-1β, IL-6, anase and matrix metalloproteinase (MMP) - MMP13, MMP9, MMP3, MMP1, uCTX-II and ADAMTS4; and by enhancing and promoting anabolic biomarkers: SOX 9, TGF-β1, ACAN, COL2A1, and PIIANP of a mammal. 14. The joint heath composition according to claim 1, comprising a method for maintaining cartilage tasis, inducing cartilage sis (and hence, anabolic effect) and inhibiting the catabolic process of degradation and broken down, protecting extracellular matrix integrity, and joint age, minimizing cartilage degradation, alleviating age breakdown, and initiating or promoting or enhancing cartilage synthesis, cartilage renewal and cartilage d, repairing damaged age, maintaining, rebuilding and repairing extra cellular matrix of joint tissue, revitalizing joints structure, maintaining steady blood flow to joints, ing health joints by protecting age integrity, balancing anabolic and catabolic processes, maintaining al fluid for joint lubrication in a mammal, diminishing the action of enzymes and proinflammatory cytokines that affect joint health of a mammal.

. The joint heath composition according to claim 1, comprising a method for improving joint movement or physical function, maintaining joint health and mobility into old age, supporting, protecting or promoting joint comfort, alleviating joint pain, reducing joint friction, alleviating joint ess, improving joint range of motion or flexibility, promoting mobility, reducing inflammation, reducing oxidative stress, reducing and protecting joint wear and tear, managing or treating rthritis or rheumatoid arthritis, preventing osteoarthritis or rheumatoid arthritis, or reversing the progression of rthritis or rheumatoid arthritis; Preventing and treating juvenile rheumatoid arthritis, Still's disease, psoriatic arthritis, reactive arthritis, septic arthritis, Reiter's me, Behcet's syndrome, or Felty's syndrome or the like of a mammal. 16. The joint health composition according to claim 1, comprising a method for improving the health of joints of hand, elbow joints, wrist joints, axillary articulations, sternoclavicular joints, vertebral articulations, temporomandibular joints, sacroiliac joints, hip joints, knee joints and articulation of foot.

EMENT FIGURES FIGURES Figure 1 EMENT FIGURES EMENT FIGURES Figure 3 EMENT FIGURES Figure 4 EMENT FIGURES Figure 5 Figure 6