基于聚(乙二醇)的强力四臂水凝胶作为组织生物粘合剂,可有效修复半月板撕裂。

IF 10.7 Q1 MEDICINE, RESEARCH & EXPERIMENTAL
MedComm Pub Date : 2024-10-24 DOI:10.1002/mco2.738
Jing Ye, Yourong Chen, Ronghui Deng, Jiying Zhang, Hufei Wang, Shitang Song, Xinjie Wang, Bingbing Xu, Xing Wang, Jia-Kuo Yu
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引用次数: 0

摘要

修复和保护受伤的半月板已成为临床实践中的重中之重。然而,半月板修复的各种临床缝合技术十分复杂,给基层医生带来了挑战。因此,人们对生物粘合剂等创新治疗策略产生了浓厚的兴趣。理想的生物粘合剂必须能在水和血液环境中快速固化、结合力强、能承受关节镜清洗压力,并能适当降解以促进组织再生。在这里,我们展示了一种基于四聚(乙二醇)(PEG)的水凝胶生物粘合剂,它具有很高的生物相容性、超快的凝胶化速度、方便的注射操作和良好的机械强度。鉴于化学锚和物理链缠结对半月板紧密结合的协同作用,周围的半月板组织和水凝胶之间形成了无缝界面,使原位融合的半月板纵向撕裂处能够承受较大的拉力,粘合强度为 541.5 ± 31.4 kPa,关节镜下抗冲洗能力为 29.4 kPa。与现有的商业粘合剂相比,我们的粘合剂无需缝合和关节镜辅助即可使用,无需专门的临床技能。这项研究有望极大地影响我们对半月板愈合的理解,并最终促进撕裂半月板功能和结构恢复的简易程序。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Robust tetra-armed poly (ethylene glycol)-based hydrogel as tissue bioadhesive for the efficient repair of meniscus tears

Robust tetra-armed poly (ethylene glycol)-based hydrogel as tissue bioadhesive for the efficient repair of meniscus tears

Repair and preservation of the injured meniscus has become paramount in clinical practice. However, the complexities of various clinic stitching techniques for meniscus repair pose challenges for grassroots doctors. Hence, there is a compelling interest in innovative therapeutic strategies such as bioadhesives. An ideal bioadhesive must cure quickly in aqueous and blood environments, bind strongly, endure arthroscopic washing pressures, and degrade appropriately for tissue regeneration. Here, we present a tetra-poly (ethylene glycol) (PEG)-based hydrogel bioadhesive, boasting high biocompatibility, ultrafast gelation, facile injectable operation, and favorable mechanical strength. In view of the synergistic effects of chemical anchor and physical chain entanglement to tightly bind the meniscus, a seamless interface was formed between the surrounding meniscal tissues and hydrogels, enabling the longitudinal tear of the meniscus fused in situ to withstand large tensile force with the adhesive strength of 541.5 ± 31.4 kPa and arthroscopic washout resistance of 29.4 kPa. Superior to existing commercial adhesives, ours allows sutureless application and arthroscopic assistance, without requiring specialized clinical skills. This research is expected to significantly impact our understanding of meniscal healing and ultimately promote a simpler process for achieving functional and structural recovery in torn menisci.

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CiteScore
6.70
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