National Engineering Research Center for Nanomedicine, College of Life Science and Technology, Huazhong University of Science and Technology, Wuhan, 430074, China.
Oujiang Laboratory (Zhejiang Lab for Regenerative Medicine, Vision and Brain Health), School of Pharmaceutical Science, Wenzhou Medical University, Wenzhou, Zhejiang, 325000, China.
Small. 2024 Jun;20(23):e2309793. doi: 10.1002/smll.202309793. Epub 2023 Dec 26.
The nerve guidance conduits incorporated with stem cells, which can differentiate into the Schwann cells (SCs) to facilitate myelination, shows great promise for repairing the severe peripheral nerve injury. The innovation of advanced hydrogel materials encapsulating stem cells, is highly demanded for generating supportive scaffolds and adaptive microenvironment for nerve regeneration. Herein, this work demonstrates a novel strategy in regulating regenerative microenvironment for peripheral nerve repair with a biodegradable conductive hydrogel scaffold, which can offer multifunctional capabilities in immune regulation, enhancing angiogenesis, driving SCs differentiation, and promoting axon regrowth. The biodegradable conductive hydrogel is constructed by incorporation of polydopamine-modified silicon phosphorus (SiP@PDA) nanosheets into a mixture of methacryloyl gelatin and decellularized extracellular matrix (GelMA/ECM). The biomimetic electrical microenvironment performs an efficacious strategy to facilitate macrophage polarization toward a pro-healing phenotype (M2), meanwhile the conductive hydrogel supports vascularization in regenerated tissue through sustained Si element release. Furthermore, the MSCs 3D-cultured in GelMA/ECM-SiP@PDA conductive hydrogel exhibits significantly increased expression of genes associated with SC-like cell differentiation, thus facilitating the myelination and axonal regeneration. Collectively, both the in vitro and in vivo studies demonstrates that the rationally designed biodegradable multifunctional hydrogel significantly enhances nerve tissues repair.
神经导管与干细胞结合,干细胞可以分化为施万细胞(SCs),促进髓鞘形成,在修复严重周围神经损伤方面显示出巨大的潜力。先进的水凝胶材料封装干细胞的创新,对生成支持神经再生的支架和适应性微环境有很高的要求。在此,本工作展示了一种用可生物降解的导电水凝胶支架调节周围神经修复再生微环境的新策略,该支架具有免疫调节、促进血管生成、驱动SCs 分化和促进轴突再生的多功能能力。可生物降解的导电水凝胶是通过将多巴胺修饰的硅磷(SiP@PDA)纳米片掺入甲基丙烯酰化明胶和去细胞外基质(GelMA/ECM)混合物中构建的。仿生电微环境是一种有效的策略,可促进巨噬细胞向促修复表型(M2)极化,同时导电水凝胶通过持续释放 Si 元素支持再生组织中的血管生成。此外,在 GelMA/ECM-SiP@PDA 导电水凝胶中 3D 培养的间充质干细胞,其与SCs 样细胞分化相关的基因表达显著增加,从而促进髓鞘形成和轴突再生。总之,体外和体内研究都表明,这种合理设计的可生物降解多功能水凝胶显著增强了神经组织的修复。
