Tannic acid modified interpenetrating network hydrogel promotes tissue remodeling of ruptured Achilles tendon after surgery#br#

	#br#

doi:10.12307/2025.251

Abstract

Abstract: BACKGROUND: The regeneration and remodeling of Achilles tendon rupture after surgery are difficulties in clinical treatment. Tissue engineering hydrogels afford the possibility on the healing of postoperative Achilles tendon.
OBJECTIVE: To investigate the effect of tannic acid modified interpenetrating network hydrogel on tissue regeneration and remodeling of ruptured Achilles tendon in rats.
METHODS: (1) The interpenetrating network hydrogel was prepared under the blue light and the immersion of CaSO4 solution. The micromorphology, mechanical properties, adhesion properties, in vitro drug release properties, and biocompatibility of hydrogels were characterized. (2) Thirty Sprague-Dawley rats were randomly divided into sham operation group, operation group, and hydrogel group, with 10 rats in each group. The animal model of Achilles tendon rupture was established in the latter two groups. In the operation group, the ruptured Achilles tendon was sutured using the modified Kessler method. In the hydrogel group, the ruptured Achilles tendon was repaired by the same method, and the tannic acid modified interpenetrating network hydrogel patch was completely wrapped around the joint of the broken end. Four weeks after the operation, imaging examination, histological evaluation, biomechanical test, and the level test of inflammatory factors were performed.
RESULTS AND CONCLUSION: (1) Scanning electron microscope showed that tannic acid modified interpenetrating network hydrogels had porous microstructure with pore size of 3-10 μm, and the hydrogels had good in vitro drug release properties, adhesion strength and tensile strength. CCK-8 assay and live/dead staining showed that the hydrogel had no significant effect on the proliferation activity of rat bone marrow mesenchymal stem cells, and had good biocompatibility. (2) MRI imaging showed that compared with the operation group, the Achilles tendon in the hydrogel group showed uniform low signal, the thickness of the anteroposterior diameter of the Achilles tendon was reduced, and the boundary between the Achilles tendon and the surrounding tissue was more clear, and the performance was more similar to that of the sham operation group. Hematoxylin-eosin staining and Masson staining showed that the tendon fibers in the operation group were arranged in a loose and chaotic manner, with increased cell density and disordered arrangement, accompanied by obvious inflammatory cell infiltration, and intratendinous ossification appeared in some areas. In the hydrogel group, the tendon fibers were arranged in an orderly manner; the cell density was reduced and arranged orderly; the inflammatory cell infiltration was significantly reduced. The tensile strength of Achilles tendon in the operation group was lower than that in the sham operation group (P < 0.05). The tensile strength of Achilles tendon in the hydrogel group was higher than that in the operation group (P < 0.05). Compared with sham operation group, the mass concentration and mRNA expression of interleukin-1β, interleukin-6, and tumor necrosis factor α in Achilles tendon of rats were increased in the operation group (P < 0.05). Compared with the operation group, the level and mRNA expression of three inflammatory factors were decreased in the hydrogel group. (3) It is concluded that tannic acid modified interpenetrating network hydrogel can inhibit the local inflammatory response and promote the tendon remodeling.

Key words: tannic acid, hydrogel, interpenetrating network, Achilles tendon rupture, tissue remodeling, tissue regeneration

CLC Number:

Zhang Bo, Zhang Zhen, Jiang Dong. Tannic acid modified interpenetrating network hydrogel promotes tissue remodeling of ruptured Achilles tendon after surgery#br#

#br#

[J]. Chinese Journal of Tissue Engineering Research, 2025, 29(4): 721-729.

Figures/Tables 10

References

[1] MYHRVOLD SB, BROUWER EF, ANDRESEN TKM, et al. Nonoperative or Surgical Treatment of Acute Achilles’ Tendon Rupture. N Engl J Med. 2022;386(15):1409-1420.
[2] HOLM C, KJAER M, ELIASSON P. Achilles tendon rupture--treatment and complications: a systematic review. Scand J Med Sci Sports. 2015;25(1):e1-10.
[3] KULICK MI, BRAZLOW R, SMITH S, et al. Injectable Ibuprofen: Preliminary Evaluation of Its Ability to Decrease Peritendinous Adhesions. Ann Plast Surg. 1984;13(6):459.
[4] YAN Z, MENG X, SU Y, et al. Double layer composite membrane for preventing tendon adhesion and promoting tendon healing. Mater Sci Eng C Mater Biol Appl. 2021;123:111941.
[5] CHOI HJ, CHOI S, KIM JG, et al. Enhanced tendon restoration effects of anti-inflammatory, lactoferrin-immobilized, heparin-polymeric nanoparticles in an Achilles tendinitis rat model. Carbohydr Polym. 2020;241:116284.
[6] TU T, SHEN Y, WANG X, et al. Tendon ECM modified bioactive electrospun fibers promote MSC tenogenic differentiation and tendon regeneration. Appl Mater Today. 2020;18:100495.
[7] CAI C, ZHANG X, LI Y, et al. Self-Healing Hydrogel Embodied with Macrophage-Regulation and Responsive-Gene-Silencing Properties for Synergistic Prevention of Peritendinous Adhesion. Adv Mater. 2022;34(5):e2106564.
[8] ZHANG Q, YANG Y, YILDIRIMER L, et al. Advanced technology-driven therapeutic interventions for prevention of tendon adhesion: Design, intrinsic and extrinsic factor considerations. Acta Biomater. 2021;124:15-32.
[9] JAFARI H, GHAFFARI-BOHLOULI P, NIKNEZHAD SV, et al. Tannic acid: a versatile polyphenol for design of biomedical hydrogels. J Mater Chem B. 2022;10(31):5873-5912.
[10] GUO S, YAO M, ZHANG D, et al. One-Step Synthesis of Multifunctional Chitosan Hydrogel for Full-Thickness Wound Closure and Healing. Adv Healthc Mater. 2022;11(4):2101808.
[11] LI Q, XIAO W, ZHANG F, et al. Tannic acid-derived metal-phenolic networks facilitate PCL nanofiber mesh vascularization by promoting the adhesion and spreading of endothelial cells. J Mater Chem B. 2018; 6(18):2734-2738.
[12] NAGESH PKB, CHOWDHURY P, HATAMI E, et al. Tannic acid inhibits lipid metabolism and induce ROS in prostate cancer cells. Sci Rep. 2020;10(1):980.
[13] DHAND AP, GALARRAGA JH, BURDICK JA. Enhancing Biopolymer Hydrogel Functionality through Interpenetrating Networks. Trends Biotechnol. 2021;39(5):519-538.
[14] HU M, YANG J, XU J. Structural and biological investigation of chitosan/hyaluronic acid with silanized-hydroxypropyl methylcellulose as an injectable reinforced interpenetrating network hydrogel for cartilage tissue engineering. Drug Deliv. 2021;28(1):607-619.
[15] ZHANG Y, DOU X, ZHANG L, et al. Facile fabrication of a biocompatible composite gel with sustained release of aspirin for bone regeneration. Bioact Mater. 2022;11:130-139.
[16] THANKAM FG, DIAZ C, CHANDRA I, et al. Hybrid interpenetrating hydrogel network favoring the bidirectional migration of tenocytes for rotator cuff tendon regeneration. J Biomed Mater Res B Appl Biomater. 2022;110(2):467-477.
[17] FAN X, WANG S, FANG Y, et al. Tough polyacrylamide-tannic acid-kaolin adhesive hydrogels for quick hemostatic application. Mater Sci Eng C Mater Biol Appl. 2020;109:110649.
[18] SMAJILAGIĆ A, ALJIČEVIĆ M, REDŽIĆ A, et al. Rat bone marrow stem cells isolation and culture as a bone formative experimental system. Bosn J Basic Med Sci. 2013;13(1):27-30.
[19] YANG S, SHI X, LI X, et al. Oriented collagen fiber membranes formed through counter-rotating extrusion and their application in tendon regeneration. Biomaterials. 2019;207:61-75.
[20] FREEDMAN BR, MOONEY DJ. Biomaterials to Mimic and Heal Connective Tissues. Adv Mater. 2019;31(19):e1806695.
[21] LI J, FENG X, LIU B, et al. Polymer materials for prevention of postoperative adhesion. Acta Biomater. 2017;61:21-40.
[22] ZHANG J, XIAO C, ZHANG X, et al. An oxidative stress-responsive electrospun polyester membrane capable of releasing anti-bacterial and anti-inflammatory agents for postoperative anti-adhesion. J Control Release. 2021;335:359-368.
[23] EVROVA O, BÜRGISSER GM, EBNÖTHER C, et al. Elastic and surgeon friendly electrospun tubes delivering PDGF-BB positively impact tendon rupture healing in a rabbit Achilles tendon model. Biomaterials. 2020;232:119722.
[24] LIU C, TIAN S, BAI J, et al. Regulation of ERK1/2 and SMAD2/3 Pathways by Using Multi-Layered Electrospun PCL-Amnion Nanofibrous Membranes for the Prevention of Post-Surgical Tendon Adhesion. Int J Nanomedicine. 2020;15:927-942.
[25] YANG Y, XU T, ZHANG Q, et al. Biomimetic, Stiff, and Adhesive Periosteum with Osteogenic-Angiogenic Coupling Effect for Bone Regeneration. Small. 2021;17(14):e2006598.
[26] COOMBES BK, BISSET L, VICENZINO B. Efficacy and safety of corticosteroid injections and other injections for management of tendinopathy: a systematic review of randomised controlled trials. Lancet. 2010;376(9754):1751-1767.
[27] GUO Z, XIE W, LU J, et al. Tannic acid-based metal phenolic networks for bio-applications: a review. J Mater Chem B. 2021;9(20):4098-4110.
[28] GRACEY E, BURSSENS A, CAMBRÉ I, et al. Tendon and ligament mechanical loading in the pathogenesis of inflammatory arthritis. Nat Rev Rheumatol. 2020;16(4):193-207.
[29] CHOI S, CHOI Y, KIM J. Anisotropic Hybrid Hydrogels with Superior Mechanical Properties Reminiscent of Tendons or Ligaments. Adv Funct Mater. 2019;29(38):1904342.
[30] TANG Y, WANG Z, XIANG L, et al. Functional biomaterials for tendon/ligament repair and regeneration. Regen Biomater. 2022;9:rbac062.
[31] CHEN C, YANG H, YANG X, et al. Tannic acid: a crosslinker leading to versatile functional polymeric networks: a review. RSC Adv. 2022; 12(13):7689-7711.
[32] REN L, GONG P, GAO X, et al. Metal-phenolic networks acted as a novel bio-filler of a barrier membrane to improve guided bone regeneration via manipulating osteoimmunomodulation. J Mater Chem B. 2022;10(48):10128-10138.
[33] WU F, NERLICH M, DOCHEVA D. Tendon injuries: Basic science and new repair proposals. EFORT Open Rev. 2017;2(7):332-342.
[34] MILLAR NL, MURRELL GAC, MCINNES IB. Inflammatory mechanisms in tendinopathy - towards translation. Nat Rev Rheumatol. 2017;13(2): 110-122.
[35] JUNEJA SC, SCHWARZ EM, O’KEEFE RJ, et al. Cellular and molecular factors in flexor tendon repair and adhesions: a histological and gene expression analysis. Connect Tissue Res. 2013;54(3):218-226.
[36] VOLETI PB, BUCKLEY MR, SOSLOWSKY LJ. Tendon healing: repair and regeneration. Annu Rev Biomed Eng. 2012;14:47-71.
[37] HOU J, YANG R, VUONG I, et al. Biomaterials strategies to balance inflammation and tenogenesis for tendon repair. Acta Biomater. 2021;130:1-16.
[38] NICHOLS AEC, BEST KT, LOISELLE AE. The cellular basis of fibrotic tendon healing: challenges and opportunities. Transl Res. 2019;209: 156-168.
[39] JING W, XIAOLAN C, YU C, et al. Pharmacological effects and mechanisms of tannic acid. Biomed Pharmacother. 2022;154:113561.
[40] CHEN Y, TIAN L, YANG F, et al. Tannic Acid Accelerates Cutaneous Wound Healing in Rats Via Activation of the ERK 1/2 Signaling Pathways. Adv Wound Care. 2019;8(7):341-354.
[41] XI Q, HOTH-HANNIG W, DENG S, et al. The effect of polyphenol-containing solutions on in situ biofilm formation on enamel and dentin. J Dent. 2020;102:103482.
[42] HU F, ZHANG R, GUO W, et al. PEGylated-PLGA Nanoparticles Coated with pH-Responsive Tannic Acid–Fe(III) Complexes for Reduced Premature Doxorubicin Release and Enhanced Targeting in Breast Cancer. Mol Pharmaceutics. 2021;18(6):2161-2173.