Multifunctional hydrogel–acellular dermal matrix composite patch: an anticalcification barrier with antibacterial and anti-inflammatory properties for abdominal wall repair

Xin Zheng , Ying Zhang , Nianhua Dan , Yining Chen , Zhengjun Li , Yunbing Wang

Collagen and Leather ›› 2025, Vol. 7 ›› Issue (1)

PDF
Collagen and Leather ›› 2025, Vol. 7 ›› Issue (1) DOI: 10.1186/s42825-025-00211-y
Research
research-article

Multifunctional hydrogel–acellular dermal matrix composite patch: an anticalcification barrier with antibacterial and anti-inflammatory properties for abdominal wall repair

Author information +
History +
PDF

Abstract

Calcification, infection, and inflammation are common complications associated with the in vivo application of biological patches. Porcine acellular dermal matrix (pADM), composed mainly of collagen with excellent bioactivity, is widely utilized as a substrate for such patches. However, integrating multiple therapeutic functions into pADM remains a significant challenge. To overcome this limitation, a hydrogel-encapsulated pADM patch (H-Cur-pADM) was developed, aiming to provide barrier protection and multifunctional enhancement. This design involves the in situ formation of a curcumin-loaded hydrogel (GelMA-DTT-Cur) on the surface of pADM via a thiol–ene click reaction. The resulting hybrid not only reinforces the anticalcification capacity of the patch but also imparts anti-infective and anti-inflammatory properties. By combining the mechanical support of pADM with the functional versatility of the hydrogel, this innovative approach enhances the overall performance of the biological patch. The GelMA-DTT-Cur hydrogel layer demonstrated robust structural integrity, interconnected porosity, and sustained release of curcumin micelles following a Fickian diffusion mechanism. In vitro, the hydrogel-encapsulated pADM displayed significant antibacterial activity against Escherichia coli and Staphylococcus aureus, good cytocompatibility, and pronounced anticalcification properties. In vivo studies showed that calcium deposition in the H-Cur-pADM group was only 5.2% of that observed in glutaraldehyde-cross-linked pADM after 21 days of implantation. The H-Cur-pADM patch also displayed strong anti-inflammatory effects and effectively promoted healing in an abdominal wall defect model. This work presents a novel strategy for improving the therapeutic performance of biological patches by integrating drug-loaded hydrogel encapsulation with pADM, offering promising potential for clinical applications in abdominal wall repair.

Keywords

Biological patch / Abdominal wall defect / Anticalcification / Acellular dermal matrix / Hydrogel

Cite this article

Download citation ▾
Xin Zheng, Ying Zhang, Nianhua Dan, Yining Chen, Zhengjun Li, Yunbing Wang. Multifunctional hydrogel–acellular dermal matrix composite patch: an anticalcification barrier with antibacterial and anti-inflammatory properties for abdominal wall repair. Collagen and Leather, 2025, 7(1): DOI:10.1186/s42825-025-00211-y

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

LiangK, DingC, LiJ, YaoX, YuJ, WuH, ChenL, ZhangM. A review of advanced abdominal wall hernia patch materials. Adv Healthc Mater, 2024, 1310. e2303506
[2]

NishiguchiA, ItoS, NagasakaK, TaguchiT. Tissue-adhesive decellularized extracellular matrix patches reinforced by a supramolecular gelator to repair abdominal wall defects. Biomacromol, 2023, 24(4): 1545-1554.

[3]

ChenY, ZhangY, WangQ, DanN, LiY, LiZ, DanW, WangY. Converting acellular dermal matrix into on-demand versatile skin scaffolds by a balanceable crosslinking approach for integrated infected wounds therapy. Biomacromol, 2023, 24(5): 2342-2355.

[4]

KiesendahlN, SchmitzC, MenneM, Schmitz-RodeT, SteinseiferU. In vitro calcification of bioprosthetic heart valves: test fluid validation on prosthetic material samples. Ann Biomed Eng, 2021, 49(2): 885-899.

[5]

ChangJ, YuL, LeiJ, LiuX, LiC, ZhengY, ChenH. A multifunctional bio-patch crosslinked with glutaraldehyde for enhanced mechanical performance, anti-coagulation properties, and anti-calcification properties. J Mater Chem B, 2023, 11(43): 10455-10463.

[6]

ZhengX, ChenYN, DanNH, LiZJ, DanWH. Anti-calcification potential of collagen based biological patch crosslinked by epoxidized polysaccharide. Int J Biol Macromol, 2022, 209: 1695-1702.

[7]

KanekoS, IsodaS, AoyamaT, GodaM, YasudaS, ShibuyaT, MatsumuraM, MitsuiH, OkudelaK, SuzukiS, MachidaD, MasudaM. Rapid anticalcification treatment for glutaraldehyde-fixed autologous tissue in cardiovascular surgery. J Cardiothorac Surg, 2022, 171138.

[8]

LiangX, LeiY, DingK, HuangX, ZhengC, WangY. Poly(2-methoxyethyl acrylate) coated bioprosthetic heart valves by copolymerization with enhanced anticoagulant, anti-inflammatory, and anti-calcification properties. J Mater Chem B, 2022, 10(48): 10054-10064.

[9]

Teng Y, Zhang X, Song L, Yang J, Li D, Shi Z, Guo X, Wang S, Fan H, Jiang L, Hou S, Ramakrishna S, Lv Q, Shi J. Construction of anti-calcification small-diameter vascular grafts using decellularized extracellular matrix/poly (L-lactide-co-epsilon-caprolactone) and baicalin-cathepsin S inhibitor. Acta Biomater. 2025;197:184-201.
[10]

Madduma-BandarageUSK, MadihallySV. Synthetic hydrogels: synthesis, novel trends, and applications. J Appl Polym Sci, 2021, 1381950376.

[11]

HuangKY, ZhengC, HuangXY, WeiBQ, ChenLP, LiGC, YangL, WangYB. Integrated hydrogel of fucoidan and rhCol III for bioprosthetic heart valves to promote the antithrombosis, anti-inflammatory, and anti-calcification properties. Compos Part B-Eng, 2025, 298112396.

[12]

KharkarPM, RehmannMS, SkeensKM, MaverakisE, KloxinAM. Thiol-ene click hydrogels for therapeutic delivery. Acs Biomater Sci Eng, 2016, 2(2): 165-179.

[13]

NguyenKT, WestJL. Photopolymerizable hydrogels for tissue engineering applications. Biomaterials, 2002, 23(22): 4307-4314.

[14]

HoyleCE, BowmanCN. Thiol-ene click chemistry. Angew Chem Int Edit, 2010, 49(9): 1540-1573.

[15]

HanDL, LiuXM, WuSL. Metal organic framework-based antibacterial agents and their underlying mechanisms. Chem Soc Rev, 2022, 51(16): 7138-7169.

[16]

YangCK, ZhangYT, TangPP, ZhengTT, ZhangXX, ZhangYZ, LiGY. Collagen-based hydrogels cross-linked via laccase- mediated system incorporated with Fe3+for wound dressing. Colloid Surface B, 2022, 219112825.

[17]

ZhangSM, ZhengC, LiML, DingKL, HuangXY, LiangXY, LeiY, JiangQ, WangYB. Sodium lignosulfonate cross-linked bioprosthetic heart valve materials for enhanced cytocompatibility, improved hemocompatibility, and reduced calcification. Compos Part B-Eng, 2022, 234109669.

[18]

ZhongTY, JiangZJ, WangP, BieSY, ZhangF, ZuoBQ. Silk fibroin/copolymer composite hydrogels for the controlled and sustained release of hydrophobic/hydrophilic drugs. Int J Pharmaceut, 2015, 494(1): 264-270.

[19]

GotoR, NishidaE, KobayashiS, AinoM, OhnoT, IwamuraY, KikuchiT, HayashiJI, YamamotoG, AsakuraM, MitaniA. Gelatin methacryloyl-riboflavin (GelMA-RF) hydrogels for bone regeneration. Int J Mol Sci, 2021, 2241635.

[20]

ZhengX, HeX, ChengY, LiZ, DanN, DanW. In situ cross-linked collagen-based biological patch integrating anti-infection and anti-calcification properties. Biomacromol, 2023, 24(1): 426-438.

[21]

NazirF, AshrafI, IqbalM, AhmadT, AnjumS. 6-deoxy-aminocellulose derivatives embedded soft gelatin methacryloyl (GelMA) hydrogels for improved wound healing applications: in vitro and in vivo studies. Int J Biol Macromol, 2021, 185: 419-433.

[22]

NabaviniaM, KhoshfetratAB, Naderi-MeshkinH. Nano-hydroxyapatite-alginate-gelatin microcapsule as a potential osteogenic building block for modular bone tissue engineering. Mat Sci Eng C-Mater, 2019, 97: 67-77.

[23]

XuSS, LiangWC, XuGZ, HuangCJ, ZhangJY, LangMD. A fast and dual crosslinking hydrogel based on vinyl ether sodium alginate. Appl Surf Sci, 2020, 515145811.

[24]

LiLL, LuCL, WangL, ChenM, WhiteJ, HaoXJ, McLeanKM, ChenH, HughesTC. Gelatin-based photocurable hydrogels for corneal wound repair. Acs Appl Mater Inter, 2018, 10(16): 13283-13292.

[25]

ChanJCY, BurugapalliK, HuangYS, KellyJL, PanditA. Cross-linked cholecyst-derived extracellular matrix for abdominal wall repair. Tissue Eng Part A, 2018, 24(15–16): 1190-1206.

[26]

KothaRR, LuthriaDL. Curcumin: biological, pharmaceutical, nutraceutical, and analytical aspects. Molecules, 2019, 24162930.

[27]

ChenYN, JingQX, ZhangY, WuXH, BaiZX, DanNH, LiZJ, LiYW, WangYB. Facile double-injection strategy for the engineering of versatile multiresponsive hydrogels encapsulating drug-loaded micelles for promoting diabetic wound healing. Ind Eng Chem Res, 2024, 63(6): 2570-2583.

[28]

AiliY, WeiP, YuX, FanG, MaimaitiailiN, LiY, LiuS, HuangY, ZhaoB, WangZ, QinH, WangY. Janus adhesive bio-patches with targeted drug delivery enabled anti-bacteria and pro-angiogenesis for dura mater repair. Mater Today Bio, 2025, 31. 101484
[29]

HiserodtR, HartmanTG, HoCT, RosenRT. Characterization of powdered turmeric by liquid chromatography mass spectrometry and gas chromatography mass spectrometry. J Chromatogr A, 1996, 740(1): 51-63.

[30]

YunDG, LeeDG. Antibacterial activity of curcumin via apoptosis-like response in. Appl Microbiol Biot, 2016, 100(12): 5505-5514.

[31]

MetzgerM, ManhartsederS, KrausgruberL, ScholzeL, FuchsD, WagnerC, StainerM, GrillariJ, KubinA, WightmanL, DungelP. The multifaceted actions of PVP-curcumin for treating infections. Int J Mol Sci, 2024, 25116140.

[32]

Gómez-EstacaJ, BalaguerMP, López-CarballoG, GavaraR, Hernández-MuñozP. Improving antioxidant and antimicrobial properties of curcumin by means of encapsulation in gelatin through electrohydrodynamic atomization. Food Hydrocolloid, 2017, 70: 313-320.

[33]

LutomskiJ, KedziaB, DebskaW. Effect of an alcohol extract and of active ingredients from Curcuma longa on bacteria and fungi (author's transl). Planta Med, 1974, 26(1): 9-19.

[34]

ZhengMX, WuXY, XuYK, MaSN, ShenJX, LiTT, ZhaiYJ, YuanL, HuGZ, PanYS, HeDD. reverses high-level tigecycline resistance mediated by different mechanisms in Gram-negative bacteria. Phytomedicine, 2025, 136156319.

[35]

ChangY, TsaiCC, LiangHC, SungHW. In vivo evaluation of cellular and acellular bovine pericardia fixed with a naturally occurring crosslinking agent (genipin). Biomaterials, 2002, 23(12): 2447-2457.

[36]

KimKM, HerreraGA, BattarbeeHD. Role of glutaraldehyde in calcification of porcine aortic valve fibroblasts. Am J Pathol, 1999, 154(3): 843-852.

[37]

ShuklaP, MitrukaM, PatiF. The effect of the synthetic route on the biophysiochemical properties of methacrylated gelatin (GelMA) based hydrogel for development of GelMA-based bioinks for 3D bioprinting applications. Materialia, 2022, 25101542.

[38]

ChenQS, JinM, YangF, ZhuJH, XiaoQZ, ZhangL. Matrix metalloproteinases: inflammatory regulators of cell behaviors in vascular formation and remodeling. Mediat Inflamm, 2013, 2013928315.

[39]

DongQ, ZuD, KongLQ, ChenSF, YaoJ, LinJW, LuL, WuB, FangB. Construction of antibacterial nano-silver embedded bioactive hydrogel to repair infectious skin defects. Biomater Res, 2022, 26136.

[40]

HutanM, BartkoC, MajeskyI, ProchotskyA, SekacJ, SkultetyJ. Reconstruction option of abdominal wounds with large tissue defects. Bmc Surg, 2014, 14: 1-7.

[41]

ZengH, LiuX, ZhangZ, SongX, QuanJ, ZhengJ, ShenZ, NiY, LiuC, ZhangY, HuG. Self-healing, injectable hydrogel based on dual dynamic covalent cross-linking against postoperative abdominal cavity adhesion. Acta Biomater, 2022, 151: 210-222.

[42]

ZhengX, ChenYN, DanNH, DanWH, LiZJ. Highly stable collagen scaffolds crosslinked with an epoxidized natural polysaccharide for wound healing. Int J Biol Macromol, 2021, 182: 1994-2002.

[43]

ShiC, ZhangY, WuG, ZhuZ, ZhengH, SunX, HengY, PanS, XiuH, ZhangJ, YinZ, YuZ, LiangB. Hyaluronic acid-based reactive oxygen species-responsive multifunctional injectable hydrogel platform accelerating diabetic wound healing. Adv Healthc Mater, 2024, 134. e2302626
[44]

ZhengLJ, HanZW, LuoDS, LiJL, PangNY, DingMY, YeHL, ZhuKY, YaoYF. IL-6, IL-1β and TNF-α regulation of the chondrocyte phenotype: a possible mechanism of haemophilic cartilage destruction. Hematology, 2023, 2812179867.

[45]

LiX, ZhangW, YuW, YuY, ChengH, LinY, FengJ, ZhaoM, JinY. Cutaneous wound healing functions of novel milk-derived antimicrobial peptides, hLFT-68 and hLFT-309 from human lactotransferrin, and bLGB-111 from bovine beta-lactoglobulin. Sci Rep, 2025, 1519965.

[46]

LiY, WangY, DingY, FanX, YeL, PanQ, ZhangB, LiP, LuoK, HuB, HeB, PuY. Correction to "A double network composite hydrogel with self-regulating Cu(2+)/luteolin release and mechanical modulation for enhanced wound healing". ACS Nano, 2024, 18(50): 34415-34418.

[47]

MilhomemAC, JorgeIMD, ArrudaFD, ToméFD, da CostaEL, VinaudMC, PereiraJX, LinoRD. Tissue remodeling after implantation with polymethylmethacrylate: an experimental study in mice. Aesthet Plast Surg, 2023, 47(3): 1205-1216.

Funding

National Natural Science Foundation of China(32101081)

Natural Science Foundation of Sichuan Province(2024NSFSC1656)

Sichuan Province Postdoctoral Special Funding(TB2022064)

RIGHTS & PERMISSIONS

The Author(s)

AI Summary AI Mindmap
PDF

111

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/