ES2927794A1 - IN VITRO METHOD TO PREDICT AND/OR FORECAST THE ABILITY TO INDUCE TISSUE REGENERATION BY A BIOMATERIAL (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

In vitro method to predict and/or predict the ability of a biomaterial to induce tissue regeneration. The present invention relates to a set of markers, preferably proteins, that are particularly useful for predicting and/or predicting the ability of a biomaterial to induce tissue regeneration, from an isolated biological sample obtained from a subject and differentially adhered to the surface of said biomaterial, such as, for example, joint prostheses, dental prostheses, valves, stents, percutaneous devices, etc. Additionally, the present invention comprises an in vitro method to predict and/or predict the regeneration capacity of the biomaterial by determining the peptide profile described in the invention, as well as a kit to carry out said method. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

In vitro method to predict v/o predict the ability of a biomaterial to induce tissue regeneration

TECHNIQUE SECTOR

The present invention refers to a set of proteins that is particularly useful for predicting and/or prognosticating the induction capacity of tissue regeneration by a biomaterial. In the invention, the biomaterial to be studied is put in contact with an isolated biological sample obtained from a subject and the peptide profile proposed herein and differentially adhered to the surface of said biomaterial is analyzed, where said biomaterial is used as an implantable medical device. , such as any type of prosthesis, such as stents, cannulas, pacemakers, dental implants, percutaneous medical devices, etc. In addition, the present invention comprises an in vitro method to predict and/or predict the ability to induce tissue regeneration by said biomaterial by determining and quantifying the peptide profile from an isolated biological sample adhered to it, as well as a kit to carry out this method.

STATE OF THE ART

The success of an implant depends on its biological acceptability, that is, that it produces minimal damage and a minimal immune reaction in the implanted subject. One of the essential requirements that said implant must meet is biocompatibility with the tissue of the subject receiving the implant, and, therefore, the absence of an immunological reaction to a foreign body. In addition, the success of said implant depends directly on the regenerative capacity of the tissue that differentially adheres to the implant.

In this sense, the tests that the biomaterial has to pass to be used as an implant are multiple and complicated, including in vitro tests against different cell lines (those of the tissue that will be in contact with the implant), to determine its cytotoxicity, cell proliferation, etc., to in vivo tests with those prototypes that have shown good in vitro properties. In addition, preclinical studies and human clinical trials are necessary. All this process involves a long period of completion, in addition to the sacrifice of a significant number of animals, and an enormous economic cost. Additionally, clinical trials are not exempt from problems and risks for patients who give their consent. consent to participate in them.

Currently, in clinical practice, there is no type of personalized test that makes it possible to predict and/or forecast the success or failure of an implant, whatever it may be (for example, dental implant, knee, hip or various screws in contact with bone, such as spine stabilizers or joint plates for broken bones, stents, heart valves, skin implants...). In the same way, there is currently no accelerated test that is capable of predicting and/or prognosticating the regeneration capacity of tissue adhered differentially to the surface of a biomaterial, which is being developed by manufacturers of implants and / or biomaterials, having to carry out all the tests described above to bring said material to the market. Additionally, there is increasing pressure to reduce the number of experimental animals for ethical reasons, but the option of selecting the biomaterial through in vitro experimentation is complex, due to the non-existence of a good correlation between both types of experimentation,/ in vitro vs in vivo.

It must be taken into account that, in order to carry out a regeneration process, preferably bone regeneration or soft tissue regeneration, certain conditions are required, such as cell signaling, the presence of progenitor cells, as well as the processes of vascularization, healing, and, in the case of bone tissue, osteoinduction. The interaction of the biomaterial-implant surface with biological systems determines the success or failure of the implant in the subject. The surface properties of the implant (hydrophilicity, roughness, or surface energy) affect the interaction of the implant with the individual's body fluids. Thus, this interaction can be positive and promote the integration of the biomaterial-implant (direct interaction between the surface of the biomaterial and the tissue without mediating fibrous tissue), or negative, giving rise to chronic and acute inflammation, high production of macrophages that constitute a response called foreign body reaction, which in most cases involves implantation failure. Understanding the sequence of biological events that take place after implantation, such as blood coagulation processes, the development of infections, the immune response to the foreign body, and finally the rejection of the implant, is crucial to determine the compatibility of a biomaterial, and therefore of the prosthesis per se. In this sense, the first layer of proteins adsorbed on the biomaterial and/or implant is responsible for triggering the cellular response to it.

Different in vitro tests can be found in the literature in which the implant is placed in contact with a sample obtained from an individual and the pattern of proteins adsorbed on the surface of the implants is analyzed to determine their compatibility in the subject. as well as the regeneration capacity of certain tissues.

Patent application WO2018/115553 describes an in vitro method to predict and/or predict the compatibility of biomaterials in a subject. Said method describes a set of markers, preferably proteins, which are particularly useful for predicting and/or prognosticating the in vitro compatibility of a biomaterial. However, the method is not designed to predict and/or determine the ability of a biomaterial to induce tissue regeneration; furthermore, certain markers discovered by the inventors and described herein are not considered.

US2009/258002 describes methods for the diagnosis and monitoring of cancer and tissue damaged by ischemia, as well as therapeutic methods and drug screening for said therapeutic methods. The document describes a method for qualifying the state of a tissue in a subject, comprising the measurement of at least one marker in a sample of the subject, where the marker is selected from a list of 1325 genes whose expression varies depending on the tissue condition in Table 9, and the correlation of the measurement with the tissue condition. Listed genes include C03, C1QB, C1QC, TENT, CLUS, PLAK and APOE.

With respect to the tissue to be diagnosed, it is selected among risk of cancer, tissue regeneration/repair, acute organ failure, organ transplantation, presence or absence of diseases, stage of the diseases, and efficacy of the treatment of the diseases. However, there are no specific references to tissue regeneration or any other type of biological sample in contact with biomaterials.

W02015/110989 describes methods for predicting the probability of mucosal recovery in individuals with inflammatory bowel disease, including those with Crohn's or ulcerative colitis. The method comprises measuring the concentrations or levels of liver growth factor (HGF), beta cellulin (BTC), vascular cell adhesion molecule (VCAM-1) and anti-TNF a compounds in a sample obtained from the subject. The present invention differs from W02015/110989 in the marker panel that is used; Furthermore, in the method of In the present invention, the biological sample is adhered to the surface of a biomaterial.

W02016/074068 describes chemical compounds that promote tissue regeneration in organs. These compounds can stimulate the production of certain molecular markers, including metalloproteinases (MMP1, MMP2, MMP9, MMP13), liver growth factor (HGF), lysyl oxidase (LOX), and E1 and A1 serpins. However, the document does not describe any of the markers of the present invention and neither does it describe methods for determining the ability of a biomaterial to induce tissue regeneration.

Taking into account the above, there is a need in the state of the art to develop reliable, rapid in vitro methods that are comparable with the results obtained at the in vivo level, which make it possible to determine and predict the induction capacity of tissue regeneration by a biomaterial for transfer to the clinic.

DESCRIPTION OF THE INVENTION

The inventors of the present invention have identified a profile of markers, preferably protein markers, the determination and/or quantification of which is capable of predicting and/or predicting the ability of a biomaterial to induce tissue regeneration. To do this, an isolated biological sample obtained from a subject is placed in contact with the biomaterial and said profile of markers adhered differentially to the surface of the biomaterial is analyzed, where the biomaterial is preferably an implantable biomaterial, and more preferably , an implantable medical device, such as prostheses, stents, cannulas, pacemakers, dental implants, percutaneous medical devices, etc.

In particular, the inventors have identified and quantified markers selected from the list consisting of: C-reactive protein (CRP); serum amyloid P component (SAMP); C subunit of the C1q subcomponent of complement (C1QC); complement subcomponent C1q subunit B (C1QB); complement component C7 (C07); complement component C5 (C05); C1 inhibitor (IC1); complement component C3 (C03); C1 s complement subcomponent (C1S); Complement factor H (CFAH); C4b binding protein a chain (C4BPA); complement subcomponent C1r (C1R); complement component C8 a chain (C08A); Ficolin-2 (FCN2); Vitronectin (VTNC); and Clusterin (CLUS); as protein markers associated with the prediction and/or prognosis of the ability to induction of tissue regeneration by a biomaterial. In other words, these proteins are markers of a biomaterial's ability to induce tissue regeneration when they are attached to it. The in vitro identification and quantification of the presence of this set of markers represents a substantial improvement on the current state of the art, since up to now no type of protein pattern has been identified that can be determined and quantified in vitro and that predict what result will be obtained in vivo once the biomaterial is implanted.

Thus, the first aspect of the invention refers to an in vitro method ("method of the invention") to predict and/or predict the induction capacity of tissue regeneration by a biomaterial under study from a biological sample. isolate obtained from a subject and differentially adhered to the surface of said biomaterial, which comprises determining and quantifying the presence of at least one of the markers adhered to the biomaterial under study, where said marker is selected from the list consisting of: CRP (UniProtKB P02741; entry version 234); SAMP (UniProtKB P02743; entry version 224); C1QC (UniProtKB P02747; entry version 210); C1QB (UniProtKB P02746; entry version 216); C07 (UniProtKB P10643; entry version 209); C1S (UniProtKB P09871; entry version 245); VTNC (UniProtKB P04004; entry version 241); C05 (UniProtKB P06684; entry version 185); IC1 (UniProtKB P05155; entry version 240); C03 (UniProtKB P01024; entry version 250); CFAH (UniProtKB P06909, entry version 166); C4BPA (UniProtKB P04003; entry version 199); C1R (UniProtKB P00736; entry version 238); C08A (UniProtKB P07357; entry version 213); FCN2 (UniProtKB Q15485; entry version 181); CLUS (UniProtKB P10909; entry version 234); to predict and/or predict the induction capacity of tissue regeneration by the biomaterial that has been in contact with the isolated biological sample of the subject.

Specifically, the in vitro method to predict and/or predict the ability to induce tissue regeneration by a biomaterial under study from an isolated biological sample obtained from a subject and differentially adhered to the surface of said biomaterial, comprises the following stages:

a. Incubate the biomaterial under study with the isolated biological sample;

b. Determine and quantify the presence of at least one of the markers adhered to the biomaterial under study, where said marker is selected from the list consisting in: CRP; SAMP; C1QC; C1QB; C07; C1S; VTNC; C05; IC1; C03; CFAH; C4BPA; C1R; C08A; FCN2; and CLUS; Y

c. Compare the value obtained in stage b. with a reference value obtained from a reference biomaterial;

where the biomaterial under study is intended for the regeneration of bone or soft tissue, and where:

(i) a value of the SAMP markers; C07; C1QB; C1S; C1R; C05; FCN2; C03; and C1QC up to 1.5 times higher than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration;

(ii) a CRP marker value lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration;

(iii) ratios between the values of the C4BPA markers; CFAH; IC1; VTNC; CLUS, and the values of the C1QB markers; C1S; C1R; C1QC; and C03 equal to or greater than the reference values obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration;

(iv) a value of the SAMP markers; C05; C03; C1S; CRP; C07; C1QB; C1QC; C1R; C08A; and FCN2; lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for soft tissue regeneration; and/or (v) a value of the IC1 markers; CFAH; C4BPA; VTNC; and CLUS lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for soft tissue regeneration,

they are indicative of a good capacity for induction of tissue regeneration by the biomaterial under study.

In certain embodiments, the method of the invention is characterized in that it comprises the simultaneous determination and quantification of one; two; three; four; five; six; seven; eight; nine; ten; eleven; twelve; thirteen; fourteen; fifteen or sixteen markers selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; VTNC; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; and CLUS.

In certain specific embodiments of the invention, the presence of markers: CRP; SAMP; C1QC; C1QB; C07; C1S; VTNC; C05; IC1; C03; CFAH; C4BPA; C1R; C08A; FCN2; and CLUS.

In certain embodiments of the method of the invention, it is characterized in that it comprises the determination and quantification of at least one of the ratios between the IC1 markers; C4BPA; CFAH; VTNC; and CLUS, regarding the C1QB markers; C1S; C1R; C1QC; C05 and C03. In a more particular embodiment, at least one of the ratios selected from any of the following list is determined: IC1/C1QB; IC1/C1QC; IC1/C1S; IC1/C1R; CFAH/C03; C4BPA/C03; VTNC/C05; CLUS/C05. Values of these ratios equal to or higher than the values obtained in the reference biomaterial would indicate that the biomaterial has a good regeneration capacity when the sample is adhered to the biomaterial of interest or biomaterial problem.

In certain embodiments of the first aspect of the invention, this is characterized in that the marker(s) that are identified and quantified are adsorbed to the biomaterial, once it has been in contact with the biological sample isolated from a subject, particularly of a subject to whom the biomaterial is to be implanted. Said markers are preferably markers present in the biological sample isolated from the subject. In addition, the presence of said markers adsorbed to the surface of the biomaterials analyzed will determine the regeneration capacity of the biomaterial.

In the present invention, the term "adsorption" or "adhesion" and variants refers to a process by which atoms, ions or molecules are trapped or retained on the surface of a material.

In the present invention, the term "regeneration" refers to any tissue repair process consisting of the new formation of pre-existing tissue. The term can be used for any type of tissue, including bone and soft tissue, connective tissue, epithelial tissue, muscle tissue, and nervous tissue. Connective tissue supports and binds other tissues such as bone, blood, and lymphatics. The epithelial tissue serves as a cover; These include the skin and the lining of various ducts within the body. Muscle tissue consists of striated or voluntary muscles that move the skeleton and smooth muscle, such as that surrounding the stomach. Nervous tissue is made up of nerve cells, or neurons, and serves to carry "messages" to and from various parts of the body.

The term "bone tissue" or "bone tissue" refers to any type of tissue that gives strength and structure to bones, including compact tissue and spongy or trabecular tissue.

A direct consequence of the loss of bone tissue quality (for example, in menopausal women, patients with systemic diseases, irradiated patients) is the increase in the failure rate of both orthopedic (hip or knee) and dental implants, which is It is also aggravated by problems derived from the higher incidence of other diseases such as periodontitis in this population. These factors are also considerably exacerbated with age. Thus, both menopause and the progressive increase in life expectancy lead to a greater number of patients requiring the use of bone prostheses, including hip, knee, and maxillofacial prostheses, or the replacement of teeth lost due to failures in their system. bone anchorage. Age conditions and hormonal deficits in women aggravate the problem and will condition the response to an implant.

It is therefore necessary to continue making progress in obtaining prostheses/implants/bone substitutes that can improve their osseointegration, that is, that can contribute to generating new quality bone, more easily and in less time. It is also necessary to continue progressing towards a design of personalized implants for each patient according to the characteristics of their clinical history and particular circumstances, such as the lack of bone or the presence of osteoporotic bone, circumstances that are particularly frequent in postmenopausal women.

Thus, the study of the biological processes that take place at the interface between prostheses/implants/substitutes and the cellular environment is key, processes that determine the acceptance/rejection of prostheses, as well as the regeneration and osseointegration times that are necessary. .

The in-depth study of the biological processes that occur at the interface between prostheses and implants will require an interdisciplinary and very powerful experimental design.

The improvement of the osseointegration capacity of bone prostheses depends on the physicochemical characteristics of the surfaces to be developed. The different physicochemical properties of the newly developed surfaces will regulate the proteins adsorbed on the surface in contact with blood. Proteins adsorbed on the surfaces of the materials will regulate the main regenerative processes that will lead to the formation of new bone and ultimately to achieve optimal osseointegration of the implant.

The term "soft tissue" refers to muscle tissue, fibrous tissue, blood vessels, or any other supporting tissue of the body.

Percutaneous medical devices are being used more and more, for a wide variety of conditions, and in various medical fields. They can be defined as foreign bodies that cross the epithelial barrier and thus connect the external environment with the internal structure of the body. Examples of percutaneous devices include catheters and other long-term intubation systems or bone anchored implants (eg, dental and orthopedic implants), where the device is permanently implanted in the body.

Soft tissue sealing is imperative for stable osseointegration and long-term survival of implants. The goal of strategies to optimize soft tissue sealing around osseointegrated implants is to achieve implant surface properties that can promote soft tissue adhesion around percutaneous/permucosal implants, which would not only provide the implant with some stability , but would also establish a permanent barrier against the invasion of bacteria and, therefore, infection.

New research in wound healing focuses on the regulation of fibroblast activity. Thus, in wounds without chronic inflammation, fibroblasts produce collagen that serves to increase the mechanical resistance of the secreted extracellular matrix. However, fibroblasts under stress conditions have the capacity to form pro-inflammatory environments (through expression of cytokines), produce reactive oxygen species (ROS) and decrease levels of type I collagen and fibronectin, preventing tissue regeneration.

Therefore, the response of fibroblasts to percutaneous implants (such as dental implants) can help tissue regeneration and wound healing (chronic inflammation-free environments), or, conversely, the formation of non-regenerative microenvironments. , characterized by profiles of abnormal growth factors, inflammatory states and generation of ROS (environments with inflammation chronicle). In this last state, NF-kp will be activated, as well as the expression of IL-ip type cytokines, and there will be a recruitment of neutrophils and macrophages.

The improvement of the sealing of the soft tissues with the abutments depends on the physicochemical characteristics of the surfaces to be developed. The different physicochemical properties of the newly developed surfaces will regulate the proteins adsorbed on the surface in contact with blood. The proteins adsorbed on each of the surfaces of the material will regulate the main initial regenerative processes and, in particular, inflammation.

In a first stage (stage a), the in vitro method of the invention comprises the incubation of an isolated biological sample from a subject, preferably in which the biomaterial under study will be implanted, with a biomaterial whose capacity is to be determined. of regeneration.

Any biological sample can be used to practice the method of the invention. The term "biological sample" refers to any biological material from a subject or several subjects. The sample is preferably a sample of tissue and/or a biological fluid. Such a tissue sample may comprise, for example, kidney tissue, joint tissue, vascular tissue, and/or heart tissue, among others. Biological fluid includes, but is not limited to, lymph, cerebrospinal fluid (CSF), amniotic fluid, pleural effusion, bone marrow, lymph node, lymphatic fluid, synovial fluid, a single cell suspension prepared from solid tissue or cell lines, urine, saliva , sweat, tears, blood, serum and blood plasma. The sample can be, and preferably is, peripheral blood, blood, plasma or serum. In certain specific embodiments of the invention, the sample is serum.

Typically, the sample is human in origin, but it can also come from any other animal. In certain specific embodiments, the sample is derived from a mammal, including, without limitation, domestic, farm, and primate animals.

For the purposes of the present invention, the terms "subject", "individual" or "patient", used interchangeably throughout this document, refer to any mammalian animal and include, but are not limited to, domestic, farm, primates and humans, preferably humans. These terms are not intended to be limiting in any way, and they can be of any age, sex and physical condition.

In a particular embodiment, the subject is a subject suffering from a pathology that can be treated by implanting a biomaterial, as described in this document.

Once the biological sample is isolated from the subject, said sample is incubated with the test biomaterial to determine in a later stage of the method (stage b) the markers that adhere to said biomaterial. In a preferred embodiment, the test biomaterial is incubated with the biological sample isolated from the subject for a 2-10 hour interval, preferably a 3-6 hour interval, more preferably a 3-4 hour interval.

Next, once the biological sample has been incubated with the test biomaterial, the method of the invention comprises step b where the presence of the markers described herein, which have adhered to the test biomaterial in contact with the test, are identified, or determined and quantified. with the isolated biological sample.

As previously mentioned, the determination of the profile of markers described in the present invention is carried out by identifying and determining the values of said markers that have remained adhered to the test biomaterial once it has been in contact with the biological sample of the biomaterial. subject to whom said biomaterial is preferably to be implanted.

Once the incubation period of the subject's biological sample with the biomaterial has elapsed, it is preferably subjected to a series of washes to eliminate markers that are not strongly adhered to the biomaterial. In a preferred embodiment, said washings are carried out preferably with bidistilled water and more preferably, a final washing with a buffer solution that preferably comprises sodium chloride at a concentration of between 50-500 mM.

In another more particular embodiment, the markers adhered to the test biomaterial are collected or eluted from said biomaterial, preferably by treating the surface of the biomaterial with a buffer solution, preferably where the buffer solution is a triethylammonium bicarbonate solution, although it can be use any buffer solution known to the person skilled in the art and useful for obtaining the proteins or markers adhered to said biomaterial.

Next, in another particular embodiment, in said eluates that comprise the markers adhered to the biomaterial, the markers that form the protein profile of the invention are determined and quantified.

The determination and quantification of the presence of the markers of the invention is carried out, preferably by determining the amount of marker adhered to the material in contact with the biological sample, preferably in the eluates obtained as previously described, and also alternatively, by determining the protein expression levels of said markers, by any method known in the state of the art. The authors of the present invention have shown that the detection of the amount and/or concentration of these expression products in a semi-quantitative or quantitative manner makes it possible to differentiate between a biomaterial with a greater or lesser regenerative capacity for a certain type of tissue. The presence, as well as the quantity, of the detected marker establishes a differential profile between biomaterials with greater or lesser efficiency in terms of regeneration.

The measurement of the amount or concentration, preferably semi-quantitatively or quantitatively, can be carried out directly or indirectly. Direct measurement refers to the measurement of the amount and/or concentration of the proteins or markers of the invention. Said signal - which we can also refer to as an intensity signal - can be obtained, for example, by measuring an intensity value of a chemical or physical property of said markers. Indirect measurement includes measurement obtained from a secondary component or biological measurement system (eg, measurement of cellular responses, ligands, "tags" or enzymatic reaction products).

The term "amount" as used in the description refers to, but is not limited to, the absolute or relative amount of the markers of the invention, but also refers to any other value or parameter related to them. or that may derive from them. Said values or parameters comprise signal intensity values obtained from any of the physical or chemical properties of said markers, obtained by direct measurement. Additionally, said values or parameters include all those obtained by indirect measurement, for example, any of the measurement systems described elsewhere in this document.

The detection and quantification of the markers of the present invention, associated with the determination of the regenerative capacity of a biomaterial, can be carried out by quantifying the levels of the proteins or peptides by conventional methods, known to those skilled in the art, including, but not limited to, chemoluminescent methods, immunohistochemical staining or biochemical detection (erg., immunohistochemical assays), immunological techniques, flow cytometry, immunoprecipitation (or their equivalents for non-antibody reagents), high performance liquid chromatography (HPLC), mass spectrometry (MS), plasma resonance absorbance measurement, etc. In a particular embodiment, the quantification of the levels of the markers identified in the present invention associated with the regeneration induction capacity of a biomaterial is performed using immunological techniques, such as ELISA (" Enzyme-Linked Immunosorbent Assay ''), Western -blot, RIA (radioimmunoassay), competitive EIA (competitive enzyme immunoassay), DAS-ELISA ( "Double Antibody Sandwich ELISA"), mass spectroscopy, immunocytochemical and immunohistochemical techniques, techniques based on the use of protein biochips or microarrays that include specific antibodies or colloidal precipitation-based assays in formats such as dipsticks.

Preferably, the proteins are detected by Western-blot, ELISA, a protein array or matrix or by two-dimensional electrophoresis, more preferably the detection of the protein profile described in the present invention is carried out by ELISA. Likewise, the person skilled in the art will recognize that the present invention relates not only to the markers described in the invention, but also to fragments thereof that could be generated, for example, by alternative processing or splicing phenomena, proteolytic cleavage of said peptides or proteins, etc. Said fragments retain the ability to be used as markers for the determination of the regenerative efficiency of a medical material as described herein. The markers of the invention, as well as their fragments, can include post-translational modifications, such as phosphorylation, glycosylation, acetylation, isoprenylation, myristoylation, proteolytic processing, etc.

In the next step of the method of the invention, (step c), the determination and quantification value of the markers of the invention obtained in step b are compared with the reference values obtained for said markers in a reference biomaterial, who has also come into contact with an isolated biological sample from the subject, where

(i) a value of the SAMP markers; C07; C1QB; C1S; C1R; C05; FCN2; C03; and C1QC of up to 1.5 times higher than the reference value obtained for the biomaterial of reference when the biomaterial under study is intended for bone tissue regeneration;

(ii) a CRP marker value lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration;

(iii) ratios between the values of the C4BPA markers; CFAH; IC1; VTNC; CLUS, and the values of the C1QB markers; C1S; C1R; C1QC; and C03 equal to or greater than the reference values obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration;

(iv) a value of the SAMP markers; C05; C03; C1S; CRP; C07; C1QB; C1QC; C1R; C08A; and FCN2 lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for soft tissue regeneration; I

(v) a value of the IC1 markers; CFAH; C4BPA; VTNC; and CLUS lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for soft tissue regeneration,

they are indicative of a good capacity for induction of tissue regeneration by the biomaterial under study.

For the purposes of the present invention, the term "biological sample" refers to a sample or set of isolated samples obtained from a subject or a group of subjects, whether it is a fluid or a tissue, as explained above.

The term "problem biomaterial" or "biomaterial of interest" or "biomaterial under study" refers to a biomaterial in which it is intended to determine the regeneration capacity of a biological sample.

For the purposes of the present invention, the term "reference biomaterial" refers to a biomaterial in which the regenerative capacity of a biological sample has been previously determined.

In certain embodiments of the invention, the reference biomaterial is titanium.

In certain embodiments of the invention, the reference biomaterial is medical grade titanium.

In certain specific embodiments of the invention, the reference biomaterial is grade 4 smooth titanium.

In the present invention, the reference amount or value is obtained from a reference biomaterial. The term "reference quantity" or "reference value", used interchangeably throughout this document, is obtained from the values, preferably quantity values of the markers of the invention, analyzed in a reference biomaterial, of the that its compatibility with a subject is known. As mentioned herein, for the purposes of the present invention, and by way of example, a biocompatible material from which to obtain the reference amount for the markers of the invention, can be titanium, preferably medical grade.

The term "comparison", as used in the description, refers to, but is not limited to, the comparison of the amount of markers as described in the invention, adhered to the test biomaterial that is cultured or incubated. together with a biological sample from a subject, relative to the amount of the same markers that have adhered to a cultured reference biomaterial also together with a biological sample obtained from the same subject.

The reference biomaterial can be analyzed, for example, simultaneously or sequentially, together with the test biomaterial. The comparison described in step c of the method of the present invention can be performed manually or assisted by a computer.

In certain embodiments of the method of the invention, it is characterized in that in step c the value obtained for at least one of the markers adhered to the problem biomaterial is compared, where said marker is selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; and CLUS.

As already indicated, the biological sample of the invention is preferably a sample of tissue and/or a biological fluid. In certain embodiments of the invention, the sample is a biological fluid. In certain embodiments of the invention the sample is a commercial biological fluid. In certain embodiments of the invention, the sample is a biological fluid obtained from a cell culture. In certain embodiments of the invention, the sample is a biological fluid obtained from a tissue. In certain specific embodiments of the invention, the sample is a biological fluid obtained from bone tissue. In certain specific embodiments of the invention, the sample is a biological fluid obtained from soft tissue.

In certain specific embodiments of the invention, the sample is blood serum, more preferably from the subject to which the biomaterial under study is to be implanted.

In those embodiments of the invention in which the biomaterial is intended for bone tissue regeneration, the following parameters are considered as indicative of a good bone tissue regeneration capacity: a level of SAMP markers; C07; C1QB; C1S; C1R; C05; FCN2; C03; and C1QC up to 1.5 times higher than the reference value obtained for the reference biomaterial; a CRP marker value lower than the reference value obtained for the reference biomaterial; and ratios between the values obtained for the IC1 markers; C4BPA; CFAH; VTNC; and CLUS, and C1QB markers; C1S; C1R; C1QC; and C03 equal to or higher than the reference values obtained in the reference biomaterial.

In those embodiments of the invention in which the biomaterial is intended for soft tissue regeneration, the following parameters are considered to be indicative of good soft tissue regeneration ability: a value of SAMP markers; C05; C03; C1S; CRP; C07; C1QB; C1QC; C1R; C08A; and FCN2; lower than the reference value obtained for the reference biomaterial; and a value of the IC1 markers; CFAH; C4BPA; VTNC; and CLUS equal to or less than the reference value obtained for the reference biomaterial.

In the context of the present invention, it is said that the amount and/or level of the marker(s) of the invention "is(are) increased" with respect to the amount and/or level of said(s) marker(s) in the reference biomaterial”, when the quantity and/or level of expression of said marker(s) is elevated (or higher) in the test biomaterial with respect to the quantity and/or level expression of said marker(s) in the reference biomaterial. In accordance with the present invention, it is considered that the amount and/or level of the marker(s) in a test biomaterial is increased with respect to the amount and/or level of said marker(s) in the biomaterial. reference when the amount and/or level of said marker(s) in the test biomaterial is increased by at least 1.01, 1.02, 1.03, 1.04, 1.05, 1.06, 1.07, 1.08, 1.09, 1.1, 1.2, 1.3, 1.4, 1.5, 1.6, 1.7, 1.8, 1.9, 2, 2.5, 3, 3.5, 4, 4.5, 5, 6, 7, 8, 9, 10, 15, 20, 25, 30, 35, 40, (n) times with respect to the amount and/or the level of expression of said marker(s) in the reference biomaterial.

Likewise, in the context of the present invention, it is said that the amount and/or the level of a marker(s) "is decreased" with respect to the amount and/or level of said marker(s) in the reference biomaterial when the amount and/or level of said marker(s) ) is reduced (or lower) with respect to the amount and/or level of said marker(s) in the reference biomaterial. In accordance with the present invention, it is considered that the amount and/or level of a marker(s) in a biomaterial under study is decreased with respect to the amount and/or level of said marker(s) in the biomaterial. reference when the amount and/or level of said marker(s) in the test biomaterial is decreased by at least 1.01, 1.02, 1.03, 1.04, 1.05, 1.06, 1.07, 1.08, 1.09, 1.1, 1.2, 1.3, 1.4 , 1.5, 1.6, 1.7, 1.8, 1.9, 2, 2.5, 3, 3.5, 4, 4.5, 5, 6, 7, 8, 9, 10, 15, 20, 25, 30, 35, 40, (n) times, with respect to the amount and/or expression level of said marker(s) in the reference biomaterial.

In the present invention the terms "predict" or "predict" refer to the assessment of the probability according to which a biomaterial is capable of inducing regeneration in a tissue of a subject that is going to be implanted with said biomaterial.

As will be understood by those skilled in the art, such an assessment, while preferred, may not typically be 100% correct for biomaterials to be predicted for regenerative ability. The term, however, requires that a statistically significant portion of the biomaterials be identifiable as being capable of inducing regeneration or available to do so. Whether a part is statistically significant can be determined without further ado by the person skilled in the art using various well-known statistical evaluation tools, eg determination of confidence intervals, determination of p-values, Student 's t-test, Mann-Whitney test , etc. Preferred confidence intervals are at least 50%, at least 60%, at least 70%, at least 80%, at least 90%, at least 95%. The p values are preferably 0.2, 0.1, 0.05.

For purposes of the present invention, the term "osseointegration" refers to the ability of the biomaterial or implant to provide a direct structural and functional bond with bone tissue through the formation of new bone or a new bone-like structure in close proximity. of the biomaterial/tissue interface. Osteogenesis refers here to the process of formation and growth of new bone. It can also assume the respective formation of other tissues such as fibrous tissue or cartilage. For purposes of the present invention, the term soft tissue regeneration refers to the ability of the biomaterial, implant, or medical device to allow there is a scar between the percutaneous device and the adjacent tissue that closes, for example, the possible entry of bacteria.

For the purposes of the present invention, the term "compatible", "compatibility", "biocompatibility" or "biocompatible", used interchangeably throughout this document, refers to the ability of a material to be in contact with a living system without generate an adverse, toxic or harmful effect, and additionally develop a specific positive and beneficial activity in the body. The compatibility analysis of a system made up of a biomaterial and the tissue with which it is in contact includes a large number of different in vitro and in vivo tests that are included in ISO10993.

For the purposes of this invention, the terms "biomaterial", "medical material", "medical device", "implant" or "prosthesis" are used interchangeably throughout this document, and refer to any biomaterial and/or device which is surgically implantable. Generally, implants are used in combination with bodily tissues or organs temporarily, permanently, or semi-permanently to remedy a problem and may optionally be surgically removed or biodegradable within the body. Examples of implants include bandages, sutures, staples, braces, cloth, mesh, netting, artificial bones, screws, bone plates, orthopedic rods, nails, hip implants, knee implants, artificial hearts, teeth, dental implants, catheters, and the like. .

The terms "marker", "markers", are used interchangeably throughout this document, and refer to a molecule, or to the expression product of a gene, preferably proteins, or to fragments and variants of these that show substantial changes in a certain condition and that can be used both for the detection and for the diagnosis and/or prognosis of a state and/or condition of an object or individual. Said terms refer particularly to the detection and quantification of said markers, to predict and/or predict the induction capacity of tissue regeneration by biomaterials, as described herein.

In certain embodiments, the changes in the marker are changes in the amount thereof, as well as, alternatively, changes in the expression levels thereof, relative to a reference value. The term "expression" as used herein is it relates particularly to the determination of the amount of each marker with respect to a reference value. It will be appreciated that the amount and/or levels of a marker can be established by determining the levels of the corresponding polypeptide, or of polypeptides generated after their digestion if proteomic means are used for their determination. Alternatively, the peptide markers can be variants resulting from post-translational modifications, including fragments thereof.

In certain embodiments, step b of the method of the invention further comprises determining and quantifying at least one of the markers selected from the list consisting of: Prothrombin (THRB; UniProtKB P00734); Antithrombin (ANT3; UniProtKB P01008; entry version 252); Kininogen 1 (KNG1; UniProtKB P01042; entry version 231);; Factor XII (FA12; UniProtKB P00748; entry version 238); Vitamin K dependent protein C (PROC; UniProtKB P04070); Vitamin K dependent protein S (PROS; UniProtKB P07225); Platelet factor 4 (PF4V; UniProtKB P10720); and Factor X (FA10; UniProtKB P00742; entry version 265); where:

(vi) a value of the THRB markers; PROC; PROS; and ANT3 at least 1.5 times higher than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration;

(vii) a value of the KNG1 markers; PF4V; FA12; and FA10 at least 2 times higher than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration;

(viii) a value of the THRB markers; PF4V; KNG1; FA12; and FA10 lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for soft tissue regeneration; I

(ix) a value of the marker ANT3, PROC; and PROS at least 1.5 times lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for soft tissue regeneration;

they are indicative of a good capacity for induction of tissue regeneration by the biomaterial under study.

Thus, in certain embodiments, step b of the method of the invention comprises the identification and quantification of the presence of at least one of the markers selected from any of the list comprising: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; KNG1; PF4V; ANT3; PROC; PROS; FA10; and FA12.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list comprising THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; and FA12.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; and FA12.

Similarly, in certain embodiments, step b of the method of the invention may also comprise the determination and quantification of at least one of the markers selected from the list consisting of: Filaggrin-2 (FILA2; UniProtKB G5D862; entry version 140 ); Desmoplakin (DESP; UniProtKB P15924; entry version 246); Fibronectin (FINC; UniProtKB P02751; entry version 266); Desmocolina 1 (DSC1; UniProtKB 008554; entry version 180); tetranectin (TETN; UniProtKB P05452; entry version 198); and placoglobin (PLAK; UniProtKB P14923; entry version 214); where a value of the markers DESP; ROW2; TETN; PLAK; DSC1; and FINC at least 1.5 times higher than the reference value obtained for the reference biomaterial is indicative of a good bone regeneration induction capacity of the biomaterial under study.

Therefore, in certain embodiments of the method of the invention, step b of the method of the invention comprises the identification and quantification of the presence of at least one of the markers selected from any of the list comprising: CRP; SAMP; C1CC; C1CB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1;TETN; END; and PLAK.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of ROW2; DESP; DSC1;TETN; END; and PLAK.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; and PLAK.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; and of at least one of the markers selected from any of the list consisting of ROW2; DESP; DSC1; TETN; END; and PLAK.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; and PLAK. Additionally, in certain embodiments, step b of the method of the invention may also comprise the determination and quantification of at least one of the markers selected from the list consisting of: pigment epithelium-derived factor (PEDF; UniProtKB P36955; entry version 209); leucine-rich alpha-2-glycoprotein (A2GL; UniProtKB P02750; entry version 189); angiopoietin-1 (ANG-1; UniProtKB 015389; entry version 185); and hypoxia-inducible factor 1-a (HIF—a; UniProtKB 016665; entry version 239), where a value of PEDF markers; A2GL; ANG-1; and HIF- at least 1.5 times higher than the reference value obtained for the reference biomaterial is indicative of a good capacity for induction of tissue regeneration by the biomaterial under study.

Therefore, in certain embodiments of the method of the invention, step b comprises the identification and quantification of the presence of at least one of the markers selected from any of the list comprising: CRP; SAMP; C1GC; C1CB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; and HIF-a.

In certain embodiments of the invention, step b of the method of the invention includes the identification and quantification of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of PEDF; A2GL; ANG-1; and HIF-a.

In certain embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; and HIF— a.

In certain embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; and HIF-a.

In other embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12;ydeat least one of the markers selected from any of the list consisting of: ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; and HIF-a.

In other embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1;TETN; END; PLAK; and of at least one of the markers selected from any of the list consisting of: PEDF; A2GL; ANG-1; and HIF-a.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; and HIF-a.

In certain embodiments, step b of the method of the invention further comprises the determination and quantification of at least one of the markers selected from the list consisting of: Plasminogen (PLMN; UniProtKB P00747; entry version 255); fibrinogen a chain (FIBA; UniProtKB P02671; entry version 251); plasminogen activator inhibitor-1 (PAI2; UniProtKB P05120; entry version 212); histidine-rich glycoprotein (HRG; UniProtKB Q6P1K1; entry version 116); and kallikrein (KLKB1; UniProtKB P03952; entry version 218), where a value of the PLMN markers; FIBA; PAI2; HRG and KLKB1 at least 1.5 times higher than the reference value obtained for the reference biomaterial is indicative of a good capacity for induction of tissue regeneration by the biomaterial under study.

Therefore, in certain embodiments of the method of the invention, step b comprises the identification and quantification of the presence of at least one of the markers selected from any of the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL;ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; and KLKB1.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of PLMN; FIBA; PAI2; HRG; and KLKB1.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; and KLKB1.

In certain embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; and KLKB1.

In certain embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12;; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL;ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; and KLKB1.

In other embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12;; and of at least one of the markers selected from any of the list consisting of: ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; and KLKB1.

In other embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1;TETN; END; PLAK; and of at least one of the markers selected from any of the list consisting of: PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; and KLKB1.

In other embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; and of at least one of the markers selected from any of the list consisting of: PLMN; FIBA; PAI2; HRG; and KLKB1.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; and KLKB1.

In certain embodiments of the method of the invention, the biomaterial under study is intended for bone tissue regeneration and step b also comprises the determination and quantification of at least one of the selected markers of the list consisting of: Apolipoprotein E (APOE; UniProtKB P02649); Lactotransferrin (TRFL; UniProtKB P02788); Statherin (STATH; UniProtKB P02808); and Peptidyl-prolyl cis-trans isomerase B (PPIB; UniProtKB P23284), where a value of APOE markers; TRFL; STATH; PPIB; and VTNC at least 2 times higher than the reference value obtained for the reference biomaterial is indicative of a good capacity for induction of tissue regeneration by the biomaterial under study.

Therefore, step b of the method of the invention may comprise the determination and quantification of at least one of the markers selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: APOE; TRFL; STATH and PPIB.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In certain embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In certain embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the bookmarks selected from any of the list consisting of: ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In certain embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a ; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In other embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12;ydeat least one of the markers selected from any of the list consisting of: ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In other embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1;TETN; END; PLAK; and of at least one of the markers selected from any of the list consisting of: PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In other embodiments of the method of the invention, step b of the method of the invention comprises identifying and quantifying the presence of: CRP; SAMP; C1GC; C1CB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; and of at least one of the markers selected from any of the list consisting of: PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF—a; PLMN; FIBA; PAI2; HRG; KLKB1; and of at least one of the markers selected from any of the list consisting of: APOE; TRFL; STATH and PPIB.

In certain embodiments of the invention, step b of the method of the invention the identification and quantification of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In certain embodiments of the method of the invention, the biomaterial under study is intended for soft tissue regeneration and step b also comprises the determination and quantification of at least one of the markers selected from the list consisting of: Cathepsin B (CATB; UniProtKB P07858; entry version 234); and Calistatin (SERPINA4; UniProtKB P29622; entry version 178), where a CATB value lower than the reference value obtained for the reference biomaterial, and a SERPINA4 value lower than the reference value obtained for the reference biomaterial is indicative of a good induction capacity of tissue regeneration by the biomaterial under study.

Therefore, step b of the method of the invention may comprise the determination and quantification of at least one of the markers selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: CATB; and SERPINA4.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In certain embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In certain embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In certain embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; and of at least one of the markers selected from any of the list consisting of: THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF—a; PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In other embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12;ydeat least one of the markers selected from any of the list consisting of: ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In other embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1;TETN; END; PLAK; and of at least one of the markers selected from any of the list consisting of: PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In other embodiments of the method of the invention, step b comprises identifying and quantifying the presence of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; and of at least one of the markers selected from any of the list consisting of: PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; and of at least one of the markers selected from any of the list consisting of: CATB; and SERPINA4.

In certain embodiments of the invention, step b of the method of the invention comprises the identification and quantification of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

A second aspect of the invention relates to the in vitro use ("use of the invention") for the determination and quantification of the presence of at least one marker selected from the list consisting of: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; in an isolated biological sample obtained from a subject and differentially adhered to the surface of a medical biomaterial, to predict and/or predict the ability of said biomaterial to induce tissue regeneration.

In certain specific embodiments, the use of the invention comprises the determination and quantification of the markers: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; and CLUS.

In certain embodiments, the use of the invention comprises the determination and quantification of at least one marker that is selected from the list consisting of: CRP; SAMP; C1CC; C1CB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12.

In certain specific embodiments, the use of the invention comprises the determination and quantification of the markers: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12.

In certain embodiments, the use of the invention comprises the determination and quantification of at least one marker that is selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1;TETN; END; and PLAK.

In certain specific embodiments, the use of the invention comprises the determination and quantification of the markers: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1;TETN; END; and PLAK.

In certain embodiments, the use of the invention comprises the determination and quantification of at least one marker that is selected from the list consisting of: CRP; SAMP; C1CC; C1CB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1;TETN; END; PLAK; PEDF; A2GL; ANG-1; and HIF-a.

In certain specific embodiments, the use of the invention comprises the determination and quantification of the markers: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; and HIF—a.

In certain embodiments, the use of the invention comprises the determination and quantification of at least one marker that is selected from the list consisting of: CRP; SAMP; C1CC; C1CB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; and KLKB1.

In certain specific embodiments, the use of the invention comprises the determination and quantification of the markers: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; and KLKB1.

In certain embodiments, the use of the invention comprises the determination and quantification of at least one marker that is selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In certain specific embodiments, the use of the invention comprises the determination and quantification of the markers: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In certain embodiments, the use of the invention comprises the determination and quantification of at least one marker that is selected from the list consisting of: CRP; SAMP; C1CC; C1CB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In certain specific embodiments, the use of the invention comprises the determination and quantification of the markers: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In certain embodiments, the use of the invention comprises the determination and quantification of at least one marker that is selected from the list consisting of: CRP; SAMP; C1CC; C1CB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; ApoE; TRFL; STATH; PPIB; CATB; and SERPINA4.

A third aspect of the invention refers to a kit ("kit of the invention") to predict and/or predict the regeneration induction capacity of a biomaterial that comprises the antibodies, the reagents, or any combination of the above, capable of to detect and quantify the presence of at least one marker that is select from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; and CLUS.#

In certain specific embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of the markers: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; and CLUS.

In certain embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of at least one marker selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; and FA12.

In certain specific embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of the markers: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; and FA12.

In certain embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of at least one marker selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; and PLAK.

In certain specific embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of the markers: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; and PLAK.

In certain embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of at least one marker selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; and HIF-a.

In certain specific embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of the markers: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; and HIF-a.

In certain embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of at least one marker selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; and KLKB1.

In certain specific embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of the markers: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; and KLKB1.

In certain embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of at least one marker selected from the list consisting of: CRP; SAMP; C1CC; C1CB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In certain specific embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of the markers: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH and PPIB.

In certain embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of at least one marker selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF—a; PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In certain specific embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of the markers: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; CATB; and SERPINA4.

In certain embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of at least one marker selected from the list consisting of: CRP; SAMP; C1CC; C1CB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH; PPIB; CATB; and SERPINA4.

In certain specific embodiments, the kit of the invention comprises the antibodies, the reagents, or any combination of the above, capable of detecting and quantifying the presence of the markers: CRP; SAMP; C1GC; C1GB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; APOE; TRFL; STATH; PPIB; CATB; and SERPINA4.

In certain specific embodiments, the determination and quantification of the markers of the invention by means of the kit of the invention is carried out after contacting the test biomaterial with a biological sample isolated from a subject, as described herein, preferably being the isolated biological sample a serum sample.

In other specific embodiments, the kit of the invention may further include, without limitation, buffers, protein extraction solutions, contamination prevention agents, protein degradation inhibitors, etc. On the other hand, the kit can include all the supports and containers necessary for its commissioning. run and optimization. Preferably, the kit further comprises instructions for carrying out the methods of the invention.

Throughout the description and claims the word "comprises" and its variants are not intended to exclude other technical characteristics, additives, components or steps.

BRIEF DESCRIPTION OF THE FIGURES

Fig.lA . L929 fibroblasts cultured for 3 days on surface A (left) and on surface B (right). B. Cell area occupied by fibroblasts on a control surface when cultured on surface A and surface B for 3 days.

Fig. 2. ALP activity of MC3T3-E1 cells at 7 and 14 days.

EXAMPLES

The invention will be illustrated below by means of some tests carried out by the inventors, which show the effectiveness of the method of the invention.

Materials and methods

Materials. Two samples have been selected: A (reference sample of grade 4 smooth titanium) and B (sample with combined treatment that causes roughness), as materials with very different physicochemical properties and which can serve as the basis for the production of different types of implants. percutaneous

The materials are prepared in the shape of a 12 mm diameter disc to be able to carry out in vitro cultures by being arranged at the bottom of the wells of a culture plate with similar dimensions.

Cell cultures. Cell culture was performed with mouse fibroblasts (line L-929) in a culture medium composed of DMEM (Gibco, Life Technologies, Thermo Fisher Scientific, NY, USA) supplemented with 1% penicillin/streptomycin (Gibco) and 10% % FBS (Gibco).

Organization of the cytoskeleton of fibroblasts. To study the effect of the materials on the organization of the cytoskeleton of the L-929 cell line, the cells were seeded on the materials at a density of 1 x 104 cells per cm'2. After 24 hours, the samples were washed with PBS and fixed with 4% paraformaldehyde (PFA) for 20 min at room temperature. Cells were then permeabilized with 0.1% Triton X-100 for 5 min and incubated with Phaloidin (1:100; Abcam, Cambridge, UK) diluted in 0.1% w/v bovine serum albumin (BSA)-PBS for 1 h at room temperature. . Nuclei were stained with DAPI medium (Abcam). Fluorescence detection was performed with a Leica TCS SP8 Confocal Laser Scanning Microscope at 20x magnification. Images were analyzed with LAS X software (Leica) and with Image J software (National Institutes of Health).

Proteomic analysis of the adsorbed protein layer. For the proteomic analysis of the adsorbed protein layer, the protocol established by Romero-Gavilán et al. [F. Romero-Gavilan, AM Sánchez-Pérez, N. Araújo-Gomes, M. Azkargorta, I. lloro, F. Elortza, M. Gurruchaga, I. Goñi, J. Suay, Proteomic analysis of silica hybrid sol-gel coatings: a potential tool for predicting the biocompatibility of implants in vivo, Biofouling. 33 (2017) 676-689. doi:10.1080/08927014.2017.1356289] and described in this patent. Materials were incubated for 3 hours (37 °C, 5% CO ² ) in a 24-well plate (Thermo Fisher Scientific) with 1 mL of human AB plasma serum (Sigma-Aldrich). To remove non-adsorbed proteins, materials were washed 5 times with ² µ ddH and then with buffer (100 mM NaCI, 50 mM Tris-HCI, pH 7.0). The protein layer adsorbed to the surface was obtained with a buffer (Thiourea 2M, Urea 7M, 4% Chaps, DTT 200 mM).

Four independent replicates of each surface were analyzed and each replicate obtained a set of 4 layers of proteins adsorbed on their respective discs. Total serum protein concentration was calculated with a Pierce BCA assay kit (Thermo Fisher).

Protein analysis was performed using a tandem of equipment: mass spectrometer with nanoACQUITY UPLC (Waters, Milford, MA, USA) coupled with an Orbitrap XL (Thermo Electron, Bremen, Germany) as described by Romero-Gavilán et al . to [same reference]. Each sample was analyzed in quadruplicate. The analysis of the protein differences was performed using the PEAKS software (Bioinformatics Solutions Inc., Waterloo, Canada).

Statistic analysis. In the in vitro characterization, the data from the trials were treated considering a normal distribution and an equivalent variance, using the ANOVA software with the Tukey post hoc test. To confirm the results after the test ANOVA student t-analysis was performed. The data are expressed with the mean value ± the standard error (SE).

For the analysis of the proteomics data, the t-student test was performed to assess the differences in adsorbed proteins using the Progenesis software. The differences were considered statistically significant with a p < 0.05.

Results.

Soft tissue.

Table 1 presents the proteins found differentially more adsorbed on surface B compared to surface A:

Table 1. Name and description of the differentially adsorbed proteins with statistical significance, ratio between the amounts found between the samples (B versus A) and ratio of interest in the invention. Proteins linked to the activation of the inflammation cascade (SAMP and C1QC), regulators of inflammation (VTNC and C4BPA), related to coagulation (THRB), linked to oxidative stress (CATB) and linked to fibromyalgia (PAI2) appear. .

As can be seen in the table, surface B is less susceptible to proteins linked to inflammation being adsorbed on its surface. Additionally, the main protein linked to oxidative stress is adsorbed significantly less on the B surface. Likewise, the proteins linked to the coagulation and fibrinolysis processes are adsorbed less.

The evaluation of the influence of the two types of material (A and B) on the organization of the cytoskeleton is performed by staining the cells with phalloidin (green) and staining the nuclei with DAPI (blue), after one day of culture. cell (Figure 1A). It can be observed that the cytoskeleton of the fibroblasts cultured on material A has a globular shape without any type of adhesion to the substrate due to the absence of lamellipodia. On the contrary, fibroblasts cultured on material B do have multiple lamellipodia and an enlarged appearance, very different from the globular one found on surface A. The presence of these lamellipodia in cells cultured on B is essential for multiple biological processes, and specifically due to the capacity of fibroblasts with this conformation to produce collagen and achieve wound healing (and in particular in gingival sealing).

In Figure 1B the area of fibroblast cells has been calculated for both surface A and surface B (cells contained in a control area). It can be clearly observed how the area occupied by fibroblasts cultured on surface B is significantly higher than that found in fibroblasts cultured on surface A.

As described in the literature, soft tissue regeneration depends on fibroblasts' ability to generate collagen. Collagen generation is only possible if the fibroblast is located on a surface where a cellular stress process is not triggered, there is a low inflammatory response, as well as regulated coagulation and fibrinolysis.

Surface B presents the markers that, according to the patent, reduce oxidative stress and inflammation, as well as give rise to a contained coagulation and fibrinolysis response. It is this surface B that has a broadened, non-globular morphology, with greater focal adhesions and greater area. It will be these fibroblasts cultivated on surface B that generate collagen and manage to regenerate the soft tissue and the consequent healing.

Woven bone.

The following table presents the proteins found differentially more adsorbed on surface B compared to surface A:

Table 2. Name and description of the differentially adsorbed proteins with statistical significance, ratio between the amounts found between the samples (X versus Y) and the ratio established in the present invention. Proteins linked to the activation of the inflammation cascade (C08A, C05, C1R, C1S), inflammation regulators (C4BPA, VTNC, CLUS, IC1), related to coagulation (A2MG, KNG1, THRB, FA11, PROC, PF4V), and linked to osteogenesis (APOE, VTNC).

As can be seen in the table, surface Y is less susceptible to proteins linked to inflammation being adsorbed on its surface. Additionally, there is a greater adsorption of proteins linked to osteogenesis and coagulation.

The evaluation of the influence of the two types of material (X and Y) on ALP activity, a widely used marker to measure osteogenic potential in in vitro studies, is shown in Figure 2.

Figure 2 shows how the type Y sample gives rise to a greater ALP secretion at both 7 and 14 days. This higher ALP activity observed in samples Y can be related to a higher osteogenic capacity and a higher mineralization capacity compared to sample X (reference Ti).

The greater adsorption of markers that, according to the patent, increase the osteogenic properties in the Y samples justify this greater ALP activity.

Claims (11)

1. In vitro method to predict and/or predict the ability to induce tissue regeneration by a biomaterial under study from an isolated biological sample obtained from a subject and differentially adhered to the surface of said biomaterial, which comprises the following stages: a. Incubate the biomaterial under study with the isolated biological sample; b. Determine and quantify the presence of at least one of the markers adhered to the biomaterial under study, where said marker is selected from the list consisting of: C-reactive protein (CRP); serum amyloid P component (SAMP); C subunit of the C1q subcomponent of complement (C1QC); complement subcomponent C1q subunit B (C1QB); complement component C7 (C07); complement component C5 (C05); C1 inhibitor (IC1); complement component C3 (C03); C1 s complement subcomponent (C1S); Complement factor H (CFAH); C4b binding protein a chain (C4BPA); complement subcomponent C1r (C1R); complement component C8 a chain (C08A); Ficolin-2 (FCN2); Vitronectin (VTNC); and Clusterin (CLUS); Y c. Compare the value obtained in stage b. with a reference value obtained from a reference biomaterial; where the biomaterial under study is intended for the regeneration of bone or soft tissue, and where: (i) a value of the SAMP markers; C07; C1QB; C1S; C1R; C05; FCN2; C03; and C1QC up to 1.5 times higher than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration; (ii) a CRP marker value lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration; (iii) ratios between the values of the C4BPA markers; CFAH; IC1; VTNC; CLUS, and the values of the C1QB markers; C1S; C1R; C1QC; and C03 equal to or greater than the reference values obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration; (iv) a value of the SAMP markers; C05; C03; C1S; CRP; C07; C1QB; C1QC; C1R; C08A; and FCN2; lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for soft tissue regeneration; I (v) a value of the IC1 markers; CFAH; C4BPA; VTNC; and CLUS lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for soft tissue regeneration, they are indicative of a good capacity for induction of tissue regeneration by the biomaterial under study. 2. The method of claim 1, wherein step b further comprises determining and quantifying at least one of the markers selected from the list consisting of: Prothrombin (THRB); Antithrombin (ANT3); Kininogen 1 (KNG1); Factor XII (FA12); Vitamin K dependent protein C (PROC); Vitamin K dependent protein S (PROS); platelet factor 4 (PF4V); and FactorX (FA10); and where: (vi) a value of the THRB markers; PROC; PROS; and ANT3 at least 1.5 times higher than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration; (vii) a value of the KNG1 markers; PF4V; FA12; and FA10 at least 2 times higher than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for bone tissue regeneration; (viii) a value of the THRB markers; PF4V; KNG1; FA12; and FA10 lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for soft tissue regeneration; I (ix) a value of the marker ANT3, PROC; and PROS at least 1.5 times lower than the reference value obtained for the reference biomaterial when the biomaterial under study is intended for soft tissue regeneration; they are indicative of a good capacity for induction of tissue regeneration by the biomaterial under study. 3. The method of claims 1 or 2, wherein step b further comprises determining and quantifying at least one of the markers selected from the list consisting of: Filaggrin-2 (FILA2); Desmoplakin (DESP); Fibronectin (FINO); Desmocholin 1 (DSC1); Tetranectin (TETN); and Plakoglobin (PLAK); where a value of the markers DESP; ROW2; PLAK; DSC1; TETN; and FINC at least 1.5 times higher than the reference value obtained for the reference biomaterial is indicative of a good capacity for induction of tissue regeneration by the biomaterial under study. 4. The method of any of claims 1 to 3, wherein step b further comprises determining and quantifying at least one of the markers selected from the list consisting of: Pigment epithelium-derived factor (PEDF); Alpha-2-leucine-rich glycoprotein (A2GL); Angiopoietin-1 (ANG-1); and Hypoxia-inducible factor 1-a (HIF-a); where a value of the PEDF markers; A2GL; ANG-1; and HIF- at least 1.5 times higher than the reference value obtained for the reference biomaterial is indicative of a good capacity for induction of tissue regeneration by the biomaterial under study. 5. The method of any of claims 1 to 4, wherein step b further comprises determining and quantifying at least one of the markers selected from the list consisting of: Plasminogen (PLMN); Fibrinogen a chain (FIBA); Plasminogen activator inhibitor-1 (PAI2); Histidine-rich glycoprotein (HRG); and Kallikrein (KLKB1); where a value of the PLMN markers; FIBA; PAI2; HRG; and KLKB1 at least 1.5 times higher than the reference value obtained for the reference biomaterial is indicative of a good capacity for induction of tissue regeneration by the biomaterial under study. 6. The method of any of claims 1 to 5, where the biomaterial under study is intended for bone tissue regeneration and where step b further comprises the determination and quantification of at least one of the markers selected from the list consisting of : Apolipoprotein E (APOE); Lactotransferrin (TRFL); Statherin (STATH); and Peptidyl-prolyl cis-trans isomerase B (PPIB); where a value of APOE markers; TRFL; STATH; PPIB; and VTNC at least 2 times higher than the reference value obtained for the reference biomaterial is indicative of a good capacity for induction of tissue regeneration by the biomaterial under study. 7. The method of any of claims 1 to 5, where the biomaterial under study is intended for soft tissue regeneration and where step b further comprises the determination and quantification of at least one of the markers selected from the list consisting of: Cathepsin B (CATB); and Callistatin (SERPINA4); where a CATB value lower than the reference value obtained for the reference biomaterial, and a SERPINA4 value lower than the reference value obtained for the reference biomaterial is indicative of a good ability to induce tissue regeneration by the biomaterial in study. The method of any of claims 1 to 7, wherein the reference biomaterial is titanium. The method of any of claims 1 to 8, wherein the biological sample is serum. 10. In vitro use of the determination and quantification of the presence of at least one marker that is selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF—a; PLMN; FIBA; PAI2; HRG; KLKB1; ApoE; TRFL; STATH; PPIB; CATB; and SERPINA4; in an isolated biological sample obtained from a subject and differentially adhered to the surface of a medical biomaterial, to predict and/or predict the ability of said biomaterial to induce tissue regeneration. 11. Kit for predicting and/or prognosticating the induction capacity of tissue regeneration by a biomaterial that includes antibodies, reagents, or any combination of the above, capable of detecting and quantifying the presence of at least one marker that is selected from the list consisting of: CRP; SAMP; C1QC; C1QB; C07; C05; IC1; C03; C1S; CFAH; C4BPA; C1R; C08A; FCN2; VTNC; CLUS; THRB; ANT3; PROC; PROS; KNG1; PF4V; FA10; FA12; ROW2; DESP; DSC1; TETN; END; PLAK; PEDF; A2GL; ANG-1; HIF-a; PLMN; FIBA; PAI2; HRG; KLKB1; ApoE; TRFL; STATH; PPIB; CATB; and SERPINA4.