KR20220113856A - Hyaluronic acid hydrogel based on supramolecular chemistry and covalent bond - Google Patents

Abstract

Provided in the present invention are: an HA-dopamine-PEG conjugate in which dopamine and PEG are bound to hyaluronic acid (HA); cyclodextrin; and a hydrogel composition containing a cation of a pharmaceutically usable salt, and a drug delivery system such as a hypodermic injection containing the hydrogel composition. A hyaluronic acid hydrogel composition and a drug delivery system such as a hypodermic injection containing the hyaluronic acid hydrogel composition, of the present invention, exhibits immediate gelation, injectability through a single syringe, self-healing ability, shear thinning behavior, sustained release of a drug, and slow biodegradation characteristics after hypodermic injection, thereby being injected into the subcutaneous tissue in a minimally invasive manner in the fields of medicine, pharmaceuticals, and skin treatment and being usefully applied as a formulation that can improve patient compliance by reducing a drug dosing frequency by sustained release of a drug.

Description

Hyaluronic acid hydrogel based on supramolecular chemistry and covalent bond

The present invention relates to a hyaluronic acid hydrogel based on supramolecular chemistry and covalent bonding, and more particularly, a HA-dopamine-PEG conjugate in which dopamine and PEG are bonded to hyaluronic acid (HA); cyclodextrins; And it relates to a hydrogel composition comprising a cation of a pharmaceutically usable salt, and a drug delivery system comprising the same.

Hydrogels are defined as three-dimensional (3D) networks of polymers capable of absorbing water, which can be used to prepare various types of formulations (e.g. films, microparticles and nanoparticles). Hydrogels enable loading of hydrophilic drugs due to their high water content. The cross-linked polymer network can control the rheological and mechanical properties of the hydrogel, and thus can contribute to the controlled release of drugs (ie, small molecule compounds, nucleic acids, peptides, proteins and cells) with various molecular weight ranges. Several physical and chemical crosslinking strategies are being introduced to prevent rapid degradation of the hydrophilic polymer chains in the hydrogel and to control the immediate drug release from the hydrogel. It is known that chemical crosslinking methods (ie, addition reactions, condensation reactions, enzymatic reactions and radical polymerization) and physical crosslinking methods (ie hydrogen bonding, ionic interactions and protein interactions) each have their own advantages and disadvantages.

Among the various substances used as hydrogel matrix, hyaluronic acid (HA) (mostly composed of D-glucuronic acid and N -acetyl-D-glucosamine [ N -acetyl-D-glucosamine]) Silver is widely used as a biodegradable matrix due to the biocompatibility of the hydrogel system. HA is one of the components of epithelial and connective tissue and is a major component of the extracellular matrix (ECM). HA can be degraded by hyaluronic acid degrading enzymes and can be degraded in the liver and lymphatic vessels in the body. In addition to the widespread application of HA in drug delivery systems, it is also used commercially as dermal fillers and wound dressings due to its biocompatibility and biodegradability.

International Publication WO2020/032056 (2020.02.13.)

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The problem to be solved by the present invention is a hydrogel system that can prevent the rapid decomposition of the hydrophilic polymer chain in the hydrogel and control the immediate drug release from the hydrogel more efficiently in the controlled release of drugs having various molecular weight ranges is to provide

The problem to be solved by the present invention is not limited to the above-mentioned problems, and other technical problems not mentioned can be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. There will be.

In order to achieve the above object, according to an aspect of the present invention, HA-dopamine-PEG conjugate in which dopamine and PEG are coupled to hyaluronic acid (HA); cyclodextrins; and a cation of a pharmaceutically usable salt, and a hydrogel composition having a pH of 7 to 11 is provided.

In one embodiment, the hyaluronic acid may have an average molecular weight of 10 to 3000 kDa.

In one embodiment, the PEG may have a molecular weight of 100 to 100000 Da.

In one embodiment, the cation of the pharmaceutically usable salt may be one cation selected from the group consisting of sodium ion, potassium ion, calcium ion, magnesium ion, barium ion, aluminum ion, and mixtures thereof, preferably sodium hydroxide (NaOH), potassium phosphate monobasic (KH ₂ PO ₄ ), potassium phosphate dibasic (K ₂ HPO ₄ ), potassium chloride (KCl), sodium phosphate monobasic (NaH ₂ PO ₄ ), sodium phosphate dibasic (Na ₂ HPO ₄ ), sodium chloride (NaCl), and may be a cation of one salt selected from the group consisting of mixtures thereof.

In one embodiment, the hydrogel composition may further include a poorly soluble drug, wherein the poorly soluble drug is donepezil, amphotericin B, curcumin, phloretin, paclitaxel, docetaxel, dexamethasone, budesonide, cyclo It may be one selected from the group consisting of sporin, tacrolimus, rapamycin, fenofibrate, prednisolone, itraconazole, insulin (neutral pH), indomethacin, and mixtures thereof, and the poorly soluble drug is encapsulated in microspheres. it could be

According to another aspect of the present invention, a drug delivery system comprising the hydrogel composition is provided.

According to another aspect of the present invention, there is provided an injection for subcutaneous injection comprising the hydrogel composition.

According to another aspect of the present invention, a filler comprising the hydrogel composition is provided.

According to another aspect of the present invention, there is provided a dressing comprising the hydrogel composition.

According to another aspect of the present invention, the method comprising: conjugating dopamine and PEG to hyaluronic acid (HA) to obtain a HA-dopamine-PEG conjugate; And after mixing the HA-dopamine-PEG conjugate and cyclodextrin, a method for preparing a hydrogel composition comprising the step of adjusting the pH to 7 to 11 by mixing a pharmaceutically usable salt is provided.

In one embodiment, the HA-dopamine-PEG conjugate comprises a carboxylic acid group of hyaluronic acid and an amine group of dopamine; and an amide bond formed between the carboxylic acid group of hyaluronic acid and the amine group of PEG.

In one embodiment, the method for preparing the hydrogel composition may further include mixing the poorly soluble drug after mixing the HA-dopamine-PEG conjugate and the cyclodextrin.

According to the present invention, HA-dopamine-PEG conjugate in which dopamine and PEG are bonded to hyaluronic acid (HA); cyclodextrins; And a hydrogel composition comprising a cation of a pharmaceutically usable salt exhibits immediate gelation, injectability through a single syringe, self-healing ability, shear thinning behavior, sustained release properties of the drug and slow biodegradation properties after subcutaneous injection. It has been found that it can be developed into a sustained-release drug formulation (such as a subcutaneous injection formulation) that can more efficiently control the immediate drug release from the gel.

Therefore, the hyaluronic acid hydrogel composition of the present invention, and a drug delivery system such as a subcutaneous injection containing the same can be injected into the subcutaneous tissue with minimal invasiveness in the fields of medicine, pharmaceuticals, and skin procedures, and the frequency of administration by sustained release of the drug It can be usefully used as a formulation that can improve patient compliance by reducing

The effects of the present invention are not limited to the above-described effects, and it should be understood to include all effects that can be inferred from the configuration of the invention described in the description or claims of the present invention.

1 is a schematic view of the synthesis and properties of HDP [HA-dopamine-PEG], (A) the process of synthesizing HDP from HA. (B) ¹ H-NMR spectrum of HDP, where the proton NMR chemical shifts for the N -acetyl group of HA (shift 1), dopamine (shift 2-4) and methylene group of PEG (shift 5 and 6) are in the spectrum. is indicated. (C) Linear regression line between the weight ratio (mPEG2K-NH ₂ /HA) and the integral ratio (3.6-3.7/1.8-2.0 ppm). (D) ¹³ C-NMR spectra of HD and HDP, showing the carbon NMR chemical shifts for N -acetyl groups of HA (shift 1), dopamine (shifts 2-4) and methylene groups of PEG (shifts 5 and 6). is appearing (E) FT-IR spectra of HD, mPEG2K-NH ₂ and HDP.
2 is a particle characteristic of PDM, (A) FE-SEM image and (B) particle size distribution of PDM.
Figure 3 is the results explaining the gel crosslinking mechanism, (A) ¹ H-NMR spectrum of aCD and HDP/aCD. (B) 2D NOESY (NMR nuclear Overhauser effect spectroscopy) results of HDP/aCD. (C) UV-Vis absorbance results of HDP and HDP 8.5 groups. (D) XRD profiles of aCD, HDP and HDP/aCD samples.
4 shows the rheological properties of the hydrogel system, (A) HA/aCD, HD/aCD, HP/aCD, HP/aCD/PDM, HDP/aCD, HDP/aCD 8.5, HDP/aCD/PDM 8.5 and HDP. As a result of the reversal test of the /PDM 8.5 group, the gelation behavior was tested at 0 hours (normal position) and 6 hours (inversion position). (B) Gelation behavior according to incubation time of HDP/aCD/PDM 8.5 hydrogel. In order to measure the gelation time, an inversion test was performed for 180 minutes. (C) Result of injectability test of HDP/aCD/PDM 8.5 hydrogel (containing 0.2 mg/mL methylene blue) through a syringe needle. (D) Rheology results of HP/aCD/PDM, HDP/aCD 8.5, HDP/PDM 8.5 and HDP/aCD/PDM 8.5 specimens, strain sweep, frequency sweep, step-by-step time -Viscoelasticity and shear rate-shear stress results were measured.
Figure 5 is the physicochemical properties of the cross-linked hydrogel system, (A) FE-SEM images of HDP / aCD 8.5 and HDP / aCD / PDM 8.5 groups. Cross-sectional images of the lyophilized samples were observed, and scale bars ( The length of white) is 20 μm. (B) Drug release profiles in donepezil solution and HDP/aCD/PDM 8.5 hydrogel groups, with each measurement expressed as mean±SD (n=3). (C) In vitro degradation results of HDP/aCD/PDM 8.5 hydrogels in the presence or absence of HAase, with each measurement expressed as mean±standard deviation (n=4).
6 is an in vivo degradation characteristic in mice of the designed hydrogel system, (A) control, PDM, HDP / aCD 8.5, HDP / PDM 8.5, HDP / aCD / PDM and HDP / aCD / PDM 8.5 It is a photograph of the gel injection site incised in the group. (B) A photograph of a gel excised from HDP/aCD 8.5, HDP/aCD/PDM and HDP/aCD/PDM 8.5 groups. (C) Residual gel weights of HDP/aCD 8.5, HDP/aCD/PDM and HDP/aCD/PDM 8.5 groups, and each measured value is expressed as mean±standard deviation (n=5).

The present invention is a HA-dopamine-PEG conjugate in which dopamine and PEG are bonded to hyaluronic acid (HA); cyclodextrins; and a cation of a pharmaceutically usable salt, and provides a hydrogel composition having a pH of 7 to 11.

In the present invention, various chemical and physical crosslinking approaches were attempted to optimize the rheological and mechanical properties of HA-based hydrogels. Chemical reactions (i.e., click chemistry, disulfide bonds, enzymatic crosslinking and esterification) and physical interactions (i.e., host-guest interactions and hydrophobic interactions) are used to modulate the physicochemical and mechanical properties of hydrogels. is being used Previous studies (Lee et al., 2020; Seo et al., 2020; Yang et al., 2020) have shown that HA-dopamine conjugates and mineral or buffered salts (eg, FeSO ₄ , KH ₂ PO ₄ and Na ₂ SeO ₃ ) Hepatic coordination and catechol polymerization were introduced as major crosslinking mechanisms of the HA hydrogel system. The common objectives of these studies are control of gelation for subcutaneous or intratumoral injection, injectability through a single syringe, low biodegradability, self-healing capacity, and sustained drug release. In the present invention, the use of a crosslinking agent exhibiting high toxicity is excluded to ensure safety in the use of injections. Instead, physiologically essential minerals and buffer salts were added as reactants of HA derivatives to crosslink the hydrogel system.

In addition, in the present invention, supramolecular chemistry (physical interaction) was used to control the rheological properties of the HA-based hydrogel. In the field of supramolecular chemistry, cyclodextrin (CD) is widely used as a host moiety due to its molecular recognition properties, allowing other guest molecules to bind to form inclusion complexes. Furthermore, instead of including small hydrophobic molecules in the inner cavity of the CD, a “molecular necklace” concept based on linear polymer chains penetrating the CD intramolecular cavity (e.g., alpha-CD (aCD)-polyethylene glycol (PEG) )) to form a polyrotaxane structure. In another study, a polypseudotaxane structure, which can be easily dissociated under certain conditions, along with a polyrotaxane system in which the terminal linear chain can be restricted to large stopper molecules, was also designed for hydrogel crosslinking. In addition to using linear polymers as guest molecules, branched or grafted polymers have also been introduced as counterparts of aCDs for polypseudotaxane hydrogel structures. In particular, as a host-guest inclusion complex assembly structure, alginate, chitosan, dextran, and heparin, in which a PEG chain penetrating a CD intramolecular cavity is grafted, has also been prepared.

In the present invention, PEG (form linked to HA-dopamine-PEG (HDP) polymer) and dopamine (form attached to HDP conjugate) participate in the formation of polypseudotaxane and catechol polymerization, respectively, to form HA hydrogel cross-links provides Although hydrogel structures based on HA-PEG and aCD have been previously reported, the introduction of polydopamine linkages for chemical crosslinking of HDP hydrogels with aCD-PEG interaction is provided for the first time in the present invention. By this gel crosslinking strategy, the viscoelasticity of the designed HDP-based hydrogel was controlled to achieve immediate gelation, injectability through a single syringe, self-healing ability, shear thinning behavior and slow biodegradation after subcutaneous injection, which will be described later. In addition, donepezil encapsulated microspheres were incorporated into the cross-linked HA hydrogel to reduce the dosing frequency.

The hyaluronic acid (HA)-dopamine-PEG conjugate included in the hydrogel composition of the present invention is formed by combining dopamine and PEG to hyaluronic acid (HA). Hyaluronic acid may be used as a hyaluronic acid, preferably hyaluronic acid having an average molecular weight of 10 to 3000 kDa, more preferably from 100 to 1000 kDa, which is a low molecular weight grade.

Dopamine used in the present invention has a chemical structure of Formula 1 below, and an amine group in the chemical structure is amide-bonded with a carboxylic acid group of hyaluronic acid to form a conjugate.

<Formula 1>

Polyethylene glycol used in the present invention is a polyether compound produced by polycondensation of ethylene glycol and is usually represented by H-[O-CH ₂ -CH ₂ ] _n -OH, PEG, poly It is also referred to as ethylen oxide (polyethylene oxide, PEO), polyoxyethylene (POE), and the like. Polyethylene glycol (PEG) referred to in the present invention includes polyethylene glycol and polyethylene glycol derivatives having both ends partially modified, for example, methoxy polyethylene glycol amine (mPEG2K-NH ₂ ) and the like. may include The PEG may have a molecular weight of 100 to 100000 Da, preferably 500 to 20000 Da, more preferably 1000 to 10000 Da. The PEG may be included in an amount of 10 to 70% by weight, preferably 20 to 60% by weight, based on the total amount of the hyaluronic acid (HA)-dopamine-PEG conjugate.

The cyclodextrin used in the present invention is cycloamylose or cycloglucan formed from cyclic dextrin upon starch degradation, and 6, 7 or 8 α-1,4-linked glucose units form one cyclus. Therefore, they are referred to as α-, β- or γ-cyclodextrins. It binds within one crystal lattice to form a penetrating internal molecular channel, which can be stacked to contain variable amounts of hydrophobic guest molecules, such as alcohols or hydrocarbons, to saturation. The cyclodextrin may be included in a ratio of 0.5 to 50 times the weight of the hyaluronic acid (HA)-dopamine-PEG conjugate in the hydrogel composition, preferably in a ratio of 1 to 10 times.

In the present specification, the term "pharmaceutically usable salt" refers to a salt that can be used in pharmaceuticals in the art to which the present invention belongs, preferably a salt that can be used in formulations applied to the human body such as subcutaneous injection. alkali metal salts such as, for example, sodium salts, potassium salts and the like; alkaline earth metal salts such as calcium salts, magnesium salts and barium salts; Aluminum salts and the like may be included, but are not limited thereto. Specific examples of the pharmaceutically usable salt include sodium hydroxide (NaOH), potassium phosphate monobasic (KH ₂ PO ₄ ), potassium phosphate dibasic (K ₂ HPO ₄ ), potassium chloride (KCl), sodium phosphate monobasic (NaH ₂ PO). ₄ ), sodium phosphate dibasic (Na ₂ HPO ₄ ), sodium chloride (NaCl), and one salt selected from the group consisting of mixtures thereof may be included, but is not limited thereto. The cation of the pharmaceutically usable salt is one kind of cation selected from the group consisting of sodium ion, potassium ion, calcium ion, magnesium ion, barium ion, aluminum ion, and mixtures thereof.

As described above, when the pharmaceutically usable salt is used at a concentration showing sol-gel transition in the hydrogel composition, the hydrogel composition exhibits a characteristic of pH 7 to 11, preferably pH 7.5 to 10, more preferably indicates a characteristic of pH 8 to 9.

In one embodiment, the hydrogel composition may further include a poorly soluble drug, and the poorly soluble drug means a drug having relatively low water solubility. For example, the poorly soluble drug is donepezil, amphotericin B, curcumin, floretin, paclitaxel, docetaxel, dexamethasone, budesonide, cyclosporine, tacrolimus, rapamycin, fenofibrate, prednisolone, itraconazole, insulin (neutral pH ), may be one selected from the group consisting of indomethacin and mixtures thereof, but is not limited thereto.

In one embodiment, the poorly soluble drug may be encapsulated in microspheres. The microspheres can be prepared using commonly used emulsification and solvent evaporation methods, which are summarized as follows. After dissolving poly(lactic-co-glycolic acid) [poly( lactic-co-glycolic acid), PLGA] and a poorly soluble drug in an organic solvent, it is added to an aqueous polyvinyl alcohol solution and homogenized to obtain an emulsion. The PLGA used at this time may be PLGA commonly used in the art to which the present invention belongs, preferably lactic acid: glycolic acid (10:90 to 90:10), more preferably lactic acid: glycolic acid (40: 60 to 60:40), and may have an average molecular weight of 10 to 100 kDa, but is not limited thereto. The resulting emulsion is stirred to evaporate the organic phase, and then the microspheres are separated using an appropriate separation method (eg, centrifugation, etc.).

The microspheres prepared by the above method may have an average bulk density-associated diameter of 1 to 100 μm, preferably 5 to 50 μm, but is not limited thereto.

The present invention also provides a drug delivery system comprising the hydrogel composition. The hydrogel composition of the present invention controls the viscoelasticity of the HDP-based hydrogel by the gel crosslinking strategy as described above, such as immediate gelation, injectability through a single syringe, self-healing ability, shear thinning behavior, and slow biodegradation after subcutaneous injection. characteristics can be achieved. Therefore, depending on the drug properties, the drug-microspheres encapsulated in the microspheres can be appropriately designed to be incorporated into the HA-dopamine-PEG (HDP) polymer. have.

In addition, since the hydrogel composition of the present invention can be designed using the viscoelasticity control properties as described above, it can be used as a filler or a dressing including the hydrogel composition.

The present invention also comprises the steps of conjugating dopamine and PEG to hyaluronic acid (HA) to obtain a HA-dopamine-PEG conjugate; And after mixing the HA-dopamine-PEG conjugate and cyclodextrin, it provides a method for preparing a hydrogel composition comprising the step of adjusting the pH to 7 to 11 by mixing a pharmaceutically usable salt.

The method for preparing the hydrogel composition of the present invention includes the step of obtaining a HA-dopamine-PEG conjugate by binding dopamine and PEG to hyaluronic acid (HA). In this step, the carboxylic acid group of hyaluronic acid and the amine group of dopamine; and forming an amide bond between the carboxylic acid group of hyaluronic acid and the amine group of PEG to prepare a HA-dopamine-PEG conjugate. In the case of amide bond between hyaluronic acid and dopamine, the amide bond reaction can be performed using EDC-NHS coupling. The dispersion is mixed to activate the carboxylic acid groups of the hyaluronic acid. A hyaluronic acid-dopamine conjugate can be obtained by acidifying the pH of the mixed solution and then reacting by adding a dopamine solution. When amide bonding between hyaluronic acid and PEG, the hyaluronic acid-dopamine conjugate is dispersed in water, and then the organic solvent solution of EDC and NHS and the hyaluronic acid-dopamine conjugate dispersion are mixed to activate the carboxylic acid group of hyaluronic acid. The HA-dopamine-PEG conjugate can be obtained by acidifying the pH of the mixed solution and then reacting by adding a PEG solution having an amine group-containing structure.

The method for preparing the hydrogel composition of the present invention includes mixing the HA-dopamine-PEG conjugate and the cyclodextrin and then adjusting the pH to 7 to 11 by mixing a pharmaceutically usable salt. In this step, after preparing a dispersion by dispersing the HA-dopamine-PEG conjugate and cyclodextrin in water, it can be prepared by adding a solution of a pharmaceutically usable salt to the dispersion. In this case, a poorly soluble drug may be further added to the HA-dopamine-PEG conjugate dispersion to prepare a hydrogel composition into which the poorly soluble drug is introduced. The poorly soluble drug may be added in encapsulated form in microspheres. Poorly soluble drugs and microspheres are as described above. In addition, the pharmaceutically usable salt is as described above.

Hereinafter, the present invention will be described in more detail through examples. However, the following examples are intended to illustrate the present invention, and the scope of the present invention is not limited thereto.

<Example>

1. Substances and test methods

1.1. matter

Hyaluronic acid (hyaluronic acid [HA], 150-600 kDa; average Mw measured by gel permeation chromatography: 667 kDa) was purchased from Bioland Co., Ltd. (Cheonan, Korea). 3-Hydroxytyramine hydrochloride (dopamine) is manufactured by Tokyo Chemical Industry Co., Ltd. (Tokyo, Japan). Methoxy polyethylene glycol amine (Methoxy polyethylene glycol amine, molecular weight: 2K) (mPEG2K-NH ₂ ) was purchased from Creative PEGWorks (Chapel Hill, NC, USA). Poly(lactic-co-glycolic acid), PLGA (lactic acid:glycolic acid=50:50, M n: 45-55 kDa) is a polySciTech (Akina, Inc., West Lafayette) , IN, USA). Donepezil base was obtained from Chong Kun Dang Pharmaceutical (Seoul, Korea). Water-d ₂ (D ₂ O), hyaluronic acid degrading enzyme (hyaluronidase, HAase ; from bovine testis, 400-1000 units/mg solid), N -hydroxysuccinimide (NHS), polyvinyl alcohol (polyvinyl alcohol, PVA; MW: 67 kDa), N -(3-dimethylaminopropyl)- N ' -ethylcarbodiimide hydrochloride ( N -(3-dimethylaminopropyl)- N' -ethylcarbodiimide hydrochloride, EDC) and Tween 80 were purchased from Sigma-Aldrich (Saint Louis, MO, USA).

1.2. Synthesis and Identification of HDP Conjugates

HA-dopamine (HD) polymer derivatives were synthesized by EDC and NHS mediated amide bond formation as reported in a previous study (Lee et al., 2020). HA (100 mg) was dispersed in distilled water (DW, 10 mL) with magnetic stirring. Dimethylsulfoxide (DMSO, 10 mL) in which EDC (57.5 mg) and NHS (34.5 mg) were dissolved was mixed with the HA dispersion and 1N HCl was added to adjust the final pH to 5. Then dopamine (37.9 mg) dissolved in DMSO (5 mL) was added to the mixture of HA, EDC and NHS and stirred for one day. The resultant was transferred to a tubular dialysis membrane (molecular weight cutoff (MWCO): 7 kDa) and dialyzed against DW for 3 days. The dialyzed material was lyophilized for storage.

To prepare HDP, mPEG2K-NH ₂ was coupled to HD using an amide bond between the carboxylic acid group of HA (in HD) and the amine group of mPEG2K-NH ₂ as follows (Cho et al., 2012). First, a dispersion of HD (96 mg) dispersed in DW (10 mL) and a mixture of EDC (38.3 mg) and NHS (22.3 mg) in DMSO (10 mL) were mixed, and the resulting final mixture was pH 5 with 1N HCl was adjusted with mPEG2K-NH ₂ (200 mg) in DMSO (5 mL) was added to the reaction mixture of HD, EDC and NHS. This was stirred at room temperature for 15 hours and dialyzed against DW contained in a tubular dialysis membrane (molecular weight cutoff (MWCO): 7 kDa) for 36 hours. The dialyzed product was freeze-dried and washed with acetone to remove unreacted mPEG2K-NH ₂ . The final product was lyophilized for further storage.

To confirm that the HD polymer derivative was correctly synthesized, the proton nuclear magnetic resonance ( ¹ H-NMR) (600 MHz, JNM-ECA-600, JEOL Ltd., Akishima, Japan) spectrum of HDP was measured. To calculate the weight percentage of mPEG2K-NH ₂ in the HDP conjugate, a linear regression line was obtained from standard samples of different weight ratios (mPEG2K-NH ₂ /HA). In addition, to confirm the synthesis of the HDP polymer, carbon-13 nuclear magnetic resonance ( ¹³ C-NMR) (800 MHz, Bruker AVANCE III HD, Bruker, Billerica, MA, USA) spectra of HD and HDP were measured.

The synthesis of HDP was also verified with a Fourier-transform infrared (FT-IR) spectrometer (Frontier ™ FT-IR spectrometer, PerkinElmer Inc., Buckinghamshire, UK). Spectra of HD, mPEG2K-NH ₂ and HDP were scanned in the attenuated total reflectance (ATR) mode in the 400-4000 cm ^-1 wavenumber range.

1.3. Preparation and validation of hydrogel structures

As reported in previous studies (Lee et al., 2020; Seo et al., 2020), PLGA/donepezil microspheres (PLGA/donepezil microspheres, PDM) are oil-in-water (o/w) ) was prepared using emulsification and solvent evaporation. Donepezil base (5 mg) and PLGA (50 mg) were dissolved in dichloromethane (1.5 mL) and mixed with PVA (0.5 %, w/v) in DW (15 mL). Then, the o/w emulsion was blended at 9,500 rpm using a high-speed homogenizer. The organic phase was removed by stirring at room temperature for 30 minutes, and the particle suspension was centrifuged at 16,100 g for 5 minutes to separate the particle pellet. After removing the supernatant, the particle pellet was redispersed in DW and lyophilized.

Magnified morphological pictures of the lyophilized PDM were taken using a field-emission scanning electron microscope (FE-SEM; SUPRA 55VP, Carl Zeiss, Oberkochen, Germany). The bulk density profile of PDM was measured with a particle size analyzer (Mastersizer 3000, Malvern Instruments Ltd., Malvern, UK).

Encapsulation rate figures of donepezil in PDM were obtained using a high performance liquid chromatography (HPLC) system (1260 Infinity II, Agilent Technologies) equipped with an autosampler (1260 Vialsampler), pump (1260 Quat Pump VL) and UV-Vis detector (1260 VWD). , Santa Clara, CA, USA). The mobile phase was prepared with potassium phosphate monobasic (10 mM) and acetonitrile mixed solution (65:35, v/v), and the flow rate was maintained at 1 mL/min. An aliquot (20 μL) of the sample was injected into a reversed-phase C18 column (Kinetex, 250 mm×4.6 mm, 5 μm; Phenomenex, Torrance, CA, USA) and absorbance was detected at 268 nm.

Thereafter, a hydrogel system designed by blending and pH control methods was prepared. To prepare 1 mL of HDP/aCD/PDM 8.5 sample, HDP (20 mg) was uniformly dispersed in DW (0.79 mL) containing aCD (100 mg), and PDM dispersion (Donepezil) in DW (0.1 mL) corresponding to 1 mg). The pH value of the mixture obtained with 1N NaOH was adjusted to 8.5, and DW was added to make a final volume of 1 mL.

Polypseudotaxane structure formation between HDP and aCD was confirmed by ¹ H-NMR analysis (600 MHz; JNM-ECA-600, JEOL Ltd.). aCD (25 mg/mL) or HDP/aCD (5:25, mg/mL) was dissolved in D ₂ O for ¹ H-NMR analysis.

The host-guest interaction between HDP and aCD was confirmed by two-dimensional (2D) NOESY (NMR nuclear Overhauser effect spectroscopy) (850 MHz, Bruker AVANCE III HD, Bruker, Billerica, MA, USA) experiments. A mixture of HDP (5 mg/mL) and aCD (25 mg/mL) was also prepared by dissolving in D ₂ O.

Polymerization of dopamine molecules in the HDP conjugate was confirmed with a UV-Vis spectrophotometer (Libra S80 dual beam spectrophotometer, Biochrom Ltd., Cambridge, UK). Samples of normal HDP (20 mg/mL in DW) and cross-linked HDP (pH 8.5; 20 mg/mL in DW) were prepared and incubated for 6 hours. The absorbance profiles of both samples were monitored in the range of 250 to 900 nm.

The mechanism by which the PEG chains of HDP penetrate the inner cavity of aCD were further investigated using X-ray diffractometry (XRD) (Philips X'Pert PRO MPD diffractometer; PANalytical Corp., Almero, Netherlands). did. Intensity values of aCD, HDP, and HDP/aCD (lyophilized form) were scanned at angles ranging from 10 to 60°. Generator voltage and tube current were set and tested at 40 kV and 30 mA, respectively.

1.4. Rheological properties of the prepared hydrogel structure

The gelling properties of the designed hydrogel system were evaluated by an inversion test. HA/aCD (20:100, mg/mL), HD/aCD (20:100, mg/mL), HP/aCD (20:100, mg/mL), HP/aCD/PDM (20:100:1 (at donepezil concentration), mg/mL), HDP/aCD (20:100, mg/mL), HDP/aCD 8.5 (20:100, mg/mL; pH 8.5), HDP/aCD/PDM 8.5 (20 :100:1 (at donepezil concentration), mg/mL; pH 8.5) and HDP/PDM 8.5 (20:1 (at donepezil concentration), mg/mL; pH 8.5) samples were incubated at room temperature for 6 hours. After inversion, the gelation behavior in the reverse position was observed.

The time required for the sol-gel transition of HDP/aCD/PDM 8.5 (20:100:1 (at donepezil concentration), mg/mL; pH 8.5) was 1, 3, 5, 10, 30, 60, The behavior was measured by observing at 120, and 180 minutes.

The injectability of HDP/aCD/PDM 8.5 hydrogel with 0.2 mg/mL methylene blue was tested with a single syringe. To evaluate injectability, the hydrogel system was extruded through a syringe needle and the behavior was observed.

The rheological properties of the HP/aCD/PDM, HDP/aCD 8.5, HDP/PDM 8.5 and HDP/aCD/PDM 8.5 groups were measured at room temperature using a rheometer (MCR 302, Anton Paar GmbH, Graz, Austria). It was evaluated by incubation for a day. The storage coefficient (G') and loss coefficient (G") values were measured according to the strain change range (1-400 %) by a strain sweep test at a fixed frequency of 10 rad/s and a temperature of 37°C. (1-100 rad/s)-dependent G' and G" values were measured at 10% strain and 37°C temperature. 3 cycles of 100% strain (0-1, 2-3, and 4-5 min) and 0% strain (1-2, 3-4, and 5-6 min) of G' and G" values over time A correlation (plot) between shear stress and viscosity according to the shear rate was obtained in the range of 0.01-100 s ^-1 .

1.5. in vitro ( in vitro ) drug release and degradation evaluation

Cross-sectional pictures of lyophilized HDP/aCD 8.5 and HDP/aCD/PDM 8.5 gels were obtained using a field-emission scanning electron microscope (FE-SEM; SUPRA 55VP, Carl Zeiss, Oberkochen, Germany).

The DPZ release profile was measured at pH 7.4 from the HDP/aCD/PDM 8.5 system in vitro . Prepare donepezil base solution (1 mg/mL in 50% DMSO) and HDP/aCD/PDM 8.5 (with 1 mg/mL donepezil) and transfer an aliquot (0.6 mL) of each sample into a dialysis tube (Midi-GeBAflex tube, MWCO: 3.5 kDa; Gene Bio-Application Ltd., Yavne, Israel). The dialysis tube was immersed in PBS (pH 7.4) containing 0.3% Tween 80 (Tween 80, 30 mL) and incubated in a water bath at 37° C. and 50 rpm. At 6 hours and 24 hours for the donepezil solution group, and at 6, 24, 48, 72, 168, 192, 216, 336, 504 and 672 hours for the HDP/aCD/PDM 8.5 group, an aliquot (0.2 mL), respectively ) was taken. The concentration of donepezil in the discharged solution was analyzed by the HPLC method described above.

The in vitro degradation properties of the HDP/aCD/PDM 8.5 system were evaluated in the absence or presence of HAase. HDP/aCD/PDM 8.5 (0.5 mL) was mixed with DW (0.5 mL) or without HAase (1 mg/mL) (0.5 mL) and placed in a microcentrifuge tube. At each sampling time point (24, 48, 72, 168, 240, 336 and 504 hours), the supernatant was removed and the remaining gel mass was measured. Thereafter, the same volume of fresh medium was replenished and incubated at 37°C. The relative percentage of the remaining gel fraction was calculated compared to the initial value (0 h).

1.6. biodegradation test

The biodegradation properties of the developed hydrogel system were evaluated by measuring the volume reduction profile in a mouse model. The designed hydrogel system was subcutaneously injected into ICR mice (Institute of Cancer Research mouse, male, 5 weeks old; Orient Bio, Seongnam, Korea). All samples were incubated for one day at room temperature, and then an aliquot of PDM, HDP/aCD 8.5, HDP/PDM 8.5, HDP/aCD/PDM and HDP/aCD/PDM 8.5 samples (0.1 mL for 20 g body weight) was administered to the mouse. It was injected subcutaneously in the back. On day 14 post injection, mice were sacrificed under inhalation anesthesia and the residual gel was excised and weighed.

1.7. data analysis

For statistical analysis of the obtained experimental data, a two-sided t -test and one-way analysis of variance (ANOVA) followed by a post hoc test were performed. Each experiment was repeated three or more times, and the obtained data were expressed as mean±standard deviation (SD).

2. Results and Discussion

2.1. Hydrogel system design and HDP polymer synthesis

In order to fabricate a physically interconnected and chemically crosslinked hydrogel system, in the present invention, a polypseudotaxane structure formed between PEG (in the form linked to the HDP conjugate) and aCD, and a dopamine group (in the form attached to the HDP conjugate) of polydopamine binding was introduced. aCD can be linked (penetrated inside) with a PEG chain (form linked to HDP) to bind the HDP structure. Hydrogen bonds between adjacent aCD molecules and their aggregation can form crystalline complexes. In addition, dopamine polymerization at alkaline pH can provide chemical crosslinking of the HDP network. By this binding mechanism, the rheological and mechanical properties of the hydrogel can be controlled to develop an optimized subcutaneous injection formulation. In addition, donepezil-encapsulated PLGA microspheres (PDM) were incorporated in a hydrogel system designed for sustained release of the drug.

As the main gel matrix, a dopamine group and a PEG group were covalently linked to the HA backbone to finally synthesize an HDP conjugate (Fig. 1A). Dopamine was linked to the HA backbone via an amide bond catalyzed by EDC and NHS. Then, PEG was further linked to the synthesized HD polymer based on the amide bond between the amine group of mPEG2K-NH ₂ and the carboxylic acid group of HA (in HD).

The synthesis of HDP was confirmed by NMR analysis ( FIGS. 1B-1D ). In the ¹ H-NMR spectrum of HDP, the chemical shifts for the N -acetyl group of HA, the phenyl ring of dopamine, and the methylene group of PEG were 1.8 to 2.0 ppm (peak 1), 6.6 to 6.8 ppm (peaks 2 to 4) and 3.6, respectively. at ~3.7 ppm (peaks 5 and 6) (Fig. 1B). Since HD synthesis has already been confirmed through spectroscopic analysis in a previous study (Lee et al., 2020), relevant analytical data are not included here. The PEG content of the HDP polymer was determined by plotting a regression line with a standard sample (a mixture of mPEG2K-NH ₂ and HD). The average PEG content of the HDP conjugate in the present invention, calculated from the regression line ( FIG. 1C ), was 50.7%. The synthesis of HD and HDP was confirmed by ¹³ C-NMR analysis ( FIG. 1D ). ¹³ C-NMR spectra of HD showed carbon shifts to the N -acetyl group of HA (22.4 ppm; peak 1) and carbon shifts to the phenyl ring group of dopamine (116.5 and 121.2 ppm; peaks 2-4) (Ling et al. ., 2015; Zhang et al., 2016). With the N -acetyl group of HA (22.5 ppm; peak 1) and the phenyl ring group of dopamine (116.6 and 121.2 ppm; peaks 2-4), the carbon shifts of PEG to the methylene carbon in the HDP spectrum were 69.6 and 71.0 ppm ( peaks 5 and 6) (Mahou and Wandrey, 2012). These ¹³ C-NMR data also support that HDP was properly synthesized.

The synthesis of HDP was also verified by FT-IR analysis ( FIG. 1E ). Peaks for OH stretching (3286 cm ^-1 ), CH stretching in the pyranose ring (2917 cm ^-1 ), and C=O stretching in NH-Ac (1643 cm ^-1 ) appeared in the spectrum of the HD conjugate. . In the HDP spectrum, peaks for OH stretching (3361 cm ^-1 ), CH stretching in the pyranose ring (2875 cm ^-1 ), and C=O stretching in NH-Ac (1649 cm ^-1 ) were also observed, ^and 1466 cm -1 The peak of ¹ means the amide bond between HA and mPEG2K-NH ₂ (Chatterjee et al., 2019). From all these FT-IR data, it was confirmed that the dopamine and PEG moieties were properly bound to the HA backbone.

2.2. Preparation of hydrogel structure and identification of hydrogel crosslinking mechanism

Chemical-associated hydrogel systems functionalized with supramolecular structures and catechols were conveniently prepared by a blending method (Lee et al., 2020; Seo et al., 2020). Donepezil base-encapsulated microspheres (PDM) were prepared and mixed with the precursor of the hydrogel in a gel crosslinking process. PDM was incorporated into the hydrogel network with the goal of sustained release of donepezil after subcutaneous injection.

PDM was prepared using an emulsification/evaporation method as reported in previous studies (Lee et al., 2020; Seo et al., 2020). Donepezil base with low water solubility was introduced into PLGA microspheres for sustained release. As shown in FIG. 2A, a smooth spherical surface was observed in the FE-SEM photograph. The bulk density (Dv) frequency according to size was measured, and the Dv (10), Dv (50), and Dv (90) values of PDM were 10, 19, and 34 μm, respectively ( FIG. 2B ). This particle size distribution profile was comparable to previously reported data performed with similar experimental protocols (Seo et al., 2020). The average encapsulation efficiency of donepezil in PDM was 68%, indicating adequate drug encapsulation in microspheres.

The hydrogel crosslinking mechanism based on supramolecular chemistry and catechol polymerization was identified by NMR, UV-Vis and XRD analysis (FIG. 3). The host-guest interaction between aCD and PEG was investigated by ¹ H-NMR analysis ( FIG. 3A ). A proton shift (H3-H6) was observed at 3.5 to 3.9 ppm of the aCD spectrum, and this shift was also shown in the ¹ H-NMR spectrum of HDP/aCD. In the spectrum of HDP/aCD, a proton shift in the methylene group of PEG was also observed at about 3.6 ppm. These data indicate that HDP and aCD are included in the lyophilized HDP/aCD hydrogel system. The penetration of PEG chains (in the form linked to the HDP conjugate) through the inner cavity of aCD was further demonstrated by 2D NOESY NMR analysis (Fig. 3B). The 2D NOESY NMR spectrum of the HDP/aCD polypseudotaxane structure showed a crosspeak based on the interaction between the hydrogen atom of the PEG methylene group and the hydrogen atom of the aCD unit. This 2D NMR result indicates rotaxylation of the designed HDP/aCD structure.

Another hydrogel crosslinking mechanism, termed catechol polymerization, was studied by UV-Vis spectroscopy analysis ( FIG. 3C ). The high absorbance value near 280 nm in the HDP spectrum indicates the contribution of the phenyl ring of the dopamine molecule. In the spectrum of HDP 8.5, it was measured that the absorbance value near 400 nm was higher than that of HDP itself. Since polydopamine formation by pH control affected the absorbance profile, it can be seen from these data that it is hydrogel crosslinking through polymerization of catechol (in the form linked to the HDP conjugate).

Host-guest chemistry between aCD and PEG and crystalline complexes based on aCD aggregates were further evaluated by XRD analysis ( FIG. 3D ). As reported (Feng et al., 2016), crystalline properties were observed in the spectrum of aCD. It is known that the PEG chain can penetrate the tunnel structure of aCD, and the inclusion complex of PEG/aCD becomes insoluble in water due to the strong hydrogen bonding force between aCD molecules. In the XRD pattern of HDP/aCD, a clear peak appeared at 19.8˚, indicating a channel-type crystal structure. The observed XRD patterns support the formation of supramolecular structures based on PEG/aCD in this study.

2.3. Rheological properties of hydrogels

The gelling properties, injectability and viscoelastic properties of the designed hydrogel structure were evaluated as follows ( FIG. 4 ). The gelation behavior of HA/aCD, HD/aCD, HP/aCD, HP/aCD/PDM, HDP/aCD, HDP/aCD 8.5, HDP/aCD/PDM 8.5 and HDP/PDM 8.5 groups was evaluated by inversion test (Fig. 4A). In the HA/aCD and HD/aCD groups, the proposed cross-linking mechanism (ie, supramolecular chemistry and polydopamine linkage) was not applied, so the viscoelastic aspect did not appear to be increased. The HP/aCD and HP/aCD/PDM groups were theoretically applied with a PEG/aCD-based physical interaction strategy, but in these gel samples, they could not remain in the inverse position in the inversion test due to insufficient viscoelastic behavior. The HDP/aCD group partially remained in the inverted state and the HDP/aCD 8.5 group showed complete gel curing behavior. The HDP/aCD 8.5 group showed color change due to polydopamine formation compared to the HDP/aCD group. Incorporation of PDM into the HDP/aCD 8.5 network did not interfere with the gelation phenomenon as shown in the HDP/aCD/PDM 8.5 group. In addition, HDP/PDM 8.5 group also showed an increase in viscoelastic properties due to catechol polymerization without supramolecular chemistry (between PEG and aCD).

The gelation time was measured by an inversion test as shown in FIG. 4B. The HDP/aCD/PDM 8.5 sample already showed that the gel was retained in the inverted position even after 1 min and the gel hardening properties were maintained for 360 min. The injectability of the HDP/aCD/PDM 8.5 group was tested by extrusion through a syringe needle ( FIG. 4C ). The observed infusion potential in the HDP/aCD/PDM 8.5 group suggests the possibility of convenient subcutaneous injection.

The viscoelastic properties of the HP/aCD/PDM, HDP/aCD 8.5, HDP/PDM 8.5 and HDP/aCD/PDM 8.5 samples were evaluated with a rheometer ( FIG. 4D ). The HDP/PDM 8.5 group remained in the inverted position (Fig. 4A), but in the strain sweep and frequency sweep tests, it was estimated that the difference in test method and sample incubation time between the inversion and rheology tests was By factor, the storage coefficient (G') and loss coefficient (G") values of this group were significantly lower than that of other supramolecular hydrogel structures (mainly based on aCD and PEG interactions). As shown in the inversion test results ( 4A), the G' and G" values of the HP/aCD/PDM group in the frequency change test and the viscosity test were lower than in the HDP/aCD 8.5 and HDP/aCD/PDM 8.5 groups. Both HDP/aCD 8.5 and HDP/aCD/PDM 8.5 groups showed higher G' and G" values than HP/aCD/PDM and HDP/PDM 8.5 groups in strain change and frequency change tests. The introduction of the composite strategy means that the viscoelastic properties of the hydrogel can be greatly improved. Both the HDP/aCD 8.5 and HDP/aCD/PDM 8.5 groups have higher G' (elastic behavior) than the G" (indicating viscous behavior) values. ) values, suggesting that it is mainly a solid state characteristic in the frequency change data. A time-dependent stepwise test was performed to evaluate the destruction and subsequent recovery of the hydrogel structure under high shear. During the second and third resting periods (0% strain, 3-4 and Restoration of the solid-like properties (G'>G") of 5-6 min) suggests a self-healing behavior. These HDP/aCD 8.5 and HDP/aCD/PDM 8.5 hydrogels exhibited an increase in the viscosity data line with increasing shear rate. This shear-thinning behavior of the HDP/aCD/PDM 8.5 hydrogel can facilitate injection through the syringe needle in the subcutaneous tissue.All observed data are the designed HDP/aCD/ Immediate gelation of PDM 8.5 hydrogel, injectability through a single syringe, self-healing ability, and shear thinning behavior were implied, suggesting that these properties would be suitable for subcutaneous injection.

2.4. Physicochemical properties of hydrogels

The internal structures of the lyophilized HDP/aCD 8.5 and HDP/aCD/PDM 8.5 groups were observed by FE-SEM imaging (FIG. 5A). A honeycomb-like structure appeared in both the HDP/aCD 8.5 and HDP/aCD/PDM 8.5 groups, which may be due to the polypseudotaxane structure and the double crosslinking strategy based on polydopamine linkages. In particular, in the picture of the HDP/aCD/PDM 8.5 group, it was confirmed that PDM was present on the inner surface of the HDP/aCD 8.5 hydrogel system.

The drug release pattern of the HDP/aCD/PDM 8.5 group was compared with the donepezil solution group (pH 7.4) ( FIG. 5B ). In the drug release test, the donepezil solution immediately diffused through the polymer membrane. Approximately 94.4% of the loading drug amount diffused from the dialysis tube into the release solution within 24 h. In contrast, the amount of donepezil released from the HDP/aCD/PDM 8.5 hydrogel was only 6.0% at 24 h. The amount of donepezil released from the HDP/aCD/PDM 8.5 hydrogel on days 7 and 14 was 39.9% and 56.7%, respectively. The HDP/aCD/PDM 8.5 hydrogel group showed sustained drug release for 4 weeks at pH 7.4 in this study. The sustained release of drugs observed in microsphere-embedded cross-linked hydrogel systems may reduce dosing frequency and increase patient compliance.

The in vitro degradation profile of the designed HDP/aCD/PDM 8.5 hydrogel was evaluated in the presence or absence of HAase ( FIG. 5C ). In the absence of HAase, the relative weight of the hydrogel increased to 1.64 times its initial value for 72 hours, which may be caused by the expansive nature of the HA backbone. Thereafter, on day 21, the relative weight of the gel decreased to 118.7% of the initial weight. In the case of the HAase-containing group, the relative weight of the hydrogel at 48 hours was measured to be 119.9%. After that, a decreasing pattern was observed and finally reached 61.8% of the initial value on day 21. The lower relative weight of the hydrogel in the group with HAase compared to the group without HAase may mean that enzymatic degradation of the HA polymer proceeded in the HDP/aCD/PDM 8.5 hydrogel. The residual hydrogel weight (61.8%) at day 21 in the presence of HAase may represent the portion of the non-cleavable inclusion complex between PEG (linked to the HA backbone) and aCD tethered to the HDP network. From the observed in vitro degradation data, it can be seen that the designed hydrogel system can be degraded slowly in biological tissues including HAase. The sustained drug release from the cross-linked hydrogel and the low degradation rate of the hydrogel even in the presence of HAase may contribute to reducing the dosing frequency and creating a long-lasting drug delivery system.

2.5. Biodegradation properties

The biodegradation pattern of the designed hydrogel system was tested after subcutaneous injection in mice ( FIG. 6 ). PDM, HDP/aCD 8.5, HDP/PDM 8.5, HDP/aCD/PDM and HDP/aCD/PDM 8.5 specimens were injected subcutaneously into the dorsal side of mice, and retention properties were monitored in vivo . The remaining sample fragments could not be obtained from the PDM and HDP/PDM 8.5 groups, probably because the PDM and HDP/PDM 8.5 hydrogels immediately diffused into the subcutaneous tissue and degraded. In the HDP/PDM 8.5 group, catechol polymerization was used as a crosslinking method, but it did not remain in the subcutaneous tissue at 14 days after injection of the sample dispersion. As can be seen from the rheological data (FIG. 4D), the maximum G' values of the HDP/PDM 8.5 group in the strain and frequency change tests were only 20.6 and 18.6 Pa, respectively, and this low viscoelastic property is due to the rapid biodegradation and rapid biodegradation in the subcutaneous tissue. seems to be related. The order of gel weight measured by collecting the remaining gel fractions from HDP/aCD 8.5, HDP/aCD/PDM and HDP/aCD/PDM 8.5 groups is: HDP/aCD/PDM 8.5> HDP/aCD 8.5> HDP/aCD/PDM It was. The residual gel weight of the HDP/aCD/PDM 8.5 group was significantly higher than that of the HDP/aCD 8.5 group (p <0.05). The difference between the two groups was larger than the weight of the PDM included in the same injection amount, which means that the PDM dispersed in the hydrogel network contributed to maintaining the hydrogel structure at the injection site and delaying the biodegradation rate. The residual gel weight of the HDP/aCD/PDM 8.5 group was 5.8 times higher than that of the HDP/aCD/PDM group (p <0.05). Chemical crosslinking strategies based on dopamine polymerization and ligation of HDP conjugates with PEG/aCD-based supramolecular structures appear to contribute significantly to the low biodegradation rate. The presented data suggest that the HDP/aCD/PDM 8.5 hydrogel can be used as a biodegradable long-acting drug delivery system.

3. Conclusion

A cross-linked hydrogel was prepared by synthesizing a dopamine and PEG-linked HA polymer conjugate (HDP) and forming an inclusion complex between aCD and PEG and polydopamine bonds. The supramolecular system (between aCD and PEG) and catechol polymerization (between dopamine molecules grafted to the HA polymer) were introduced as dual physical and chemical hydrogel crosslinking strategies, whereby the viscoelastic properties were greatly improved. In addition, for the designed hydrogel system, rapid sol-to-gel conversion, injectability through a single syringe, self-healing ability, and shear thinning behavior were verified. For sustained release, PDM was incorporated into the cross-linked hydrogel network and the HDP/aCD/PDM 8.5 hydrogel showed low biodegradation rate and negligible toxicity after subcutaneous injection into mice. From all these results, it can be seen that the designed HDP/aCD/PDM 8.5 hydrogel can be safely used for long-term delivery of donepezil through subcutaneous injection.

4. Summary

In the present invention, a cross-linked hyaluronic acid (HA) hydrogel based on a polypseudotaxane structure and polydopamine bond was developed to continuously deliver the drug (donepezil) after subcutaneous injection. Dopamine and polyethylene glycol (PEG) molecules were covalently linked to the HA polymer for amide linkage for catechol polymerization and inclusion complexation with cyclodextrin (CD), respectively. Alpha-cyclodextrin (aCD) is bound to the PEG chain of the HA-dopamine-PEG (HDP) conjugate to form a polypseudotaxane structure, and the pH is adjusted to alkaline conditions (pH 8.5) to form polymerized dopamine (in the form attached to the HD conjugate). Poly(lactic-co-glycolic acid) [poly(lactic-co-glycolic acid), PLGA]/donepezil microspheres (microspheres, MS) (PDM) were incorporated into the HDP polymer network for sustained release. . The designed HDP/aCD/PDM 8.5 hydrogel system exhibited an immediate gelation pattern, injectability through a single syringe, self-healing ability and shear-thinning behavior. Donepezil was released in a continuous pattern from the HDP/aCD/PDM 8.5 hydrogel, and the HDP/aCD/PDM 8.5 hydrogel exhibited the property of being degraded by hyaluronic acid degrading enzyme. After subcutaneous injection, the amount of HDP/aCD/PDM 8.5 hydrogel remained larger than that of the other groups even after 14 days. Based on the observed results, the developed HDP/aCD/PDM 8.5 hydrogel suggests high clinical feasibility as a subcutaneous injection formulation.

The above description of the present invention is for illustration, and those of ordinary skill in the art to which the present invention pertains can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and likewise components described as distributed may also be implemented in a combined form.

The scope of the present invention is indicated by the following claims, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention.

Claims (15)

HA-dopamine-PEG conjugate in which dopamine and PEG are coupled to hyaluronic acid (HA); cyclodextrin; and a cation of a pharmaceutically usable salt, the hydrogel composition having a pH of 7 to 11. The hydrogel composition according to claim 1, wherein the hyaluronic acid has an average molecular weight of 10 to 3000 kDa. The hydrogel composition according to claim 1, wherein the PEG has a molecular weight of 100 to 100000 Da. The cation of claim 1, wherein the cation of the pharmaceutically usable salt is one cation selected from the group consisting of sodium ion, potassium ion, calcium ion, magnesium ion, barium ion, aluminum ion, and mixtures thereof. a hydrogel composition. According to claim 1, wherein the cation of the pharmaceutically usable salt is sodium hydroxide (NaOH), potassium monophosphate (KH ₂ PO ₄ ), potassium dibasic (K ₂ HPO ₄ ), potassium chloride (KCl), the first Sodium phosphate (NaH ₂ PO ₄ ), sodium phosphate dibasic (Na ₂ HPO ₄ ), sodium chloride (NaCl), and a hydrogel composition, characterized in that the cation of one salt selected from the group consisting of mixtures thereof. The hydrogel composition according to claim 1, further comprising a poorly soluble drug. 7. The method of claim 6, wherein the poorly soluble drug is donepezil, amphotericin B, curcumin, floretin, paclitaxel, docetaxel, dexamethasone, budesonide, cyclosporine, tacrolimus, rapamycin, fenofibrate, prednisolone, itraconazole, insulin ( Neutral pH), indomethacin, and a hydrogel composition, characterized in that one selected from the group consisting of mixtures thereof. The hydrogel composition according to claim 6, wherein the poorly soluble drug is encapsulated in microspheres. A drug delivery system comprising the hydrogel composition of any one of claims 1 to 8. An injection for subcutaneous injection comprising the hydrogel composition of any one of claims 1 to 8. A filler comprising the hydrogel composition of any one of claims 1 to 8. A dressing comprising the hydrogel composition of any one of claims 1 to 8. conjugating dopamine and PEG to hyaluronic acid (HA) to obtain a HA-dopamine-PEG conjugate; and
After mixing the HA-dopamine-PEG conjugate and cyclodextrin, adjusting the pH to 7-11 by mixing a pharmaceutically usable salt
A method for producing a hydrogel composition comprising a. 14. The method of claim 13, wherein the HA-dopamine-PEG conjugate comprises a carboxylic acid group of hyaluronic acid and an amine group of dopamine; and a method for producing a hydrogel composition, characterized in that it is prepared by an amide bond formed between the carboxylic acid group of hyaluronic acid and the amine group of PEG. 14. The method of claim 13, wherein the HA-dopamine-PEG conjugate and the cyclodextrin are mixed, and then the hydrogel composition further comprises the step of mixing a poorly soluble drug.

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