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具有串珠结构的自增强 PTLG 共聚物和仿生表面作为组织工程应用的生物植入材料。

Self-Reinforced PTLG Copolymer with Shish Kebab Structures and a Bionic Surface as Bioimplant Materials for Tissue Engineering Applications.

机构信息

China Coal Research Institute, Coal Mining Branch, Beijing 400037, P. R. China.

CCTEG Coal Mining Research Institute, Beijing 100013, P. R. China.

出版信息

ACS Appl Mater Interfaces. 2024 Feb 28;16(8):11062-11075. doi: 10.1021/acsami.3c18093. Epub 2024 Feb 20.

DOI:10.1021/acsami.3c18093
PMID:38378449
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10910444/
Abstract

Green and biodegradable materials with great mechanical properties and biocompatibility will offer new opportunities for next-generation high-performance biological materials. Herein, the novel oriented shish kebab crystals of a novel poly(trimethylene carbonate-lactide-glycolide) (PTLG) vascular stent are first reported to be successfully fabricated through a feasible solid-state drawing process to simultaneously enhance the mechanical performance and biocompatibility. The crystal structure of this self-reinforced vascular stent was transformed from spherulites to a shish kebab crystal, which indicates the mechanical interlocking effect and prevents the lamellae from slipping with a significant improvement of mechanical strength to 333 MPa. Meanwhile, it is different from typical biomedical polymers with smooth surface structures, and the as-obtained PTLG vascular stent exhibits a bionic surface morphology with a parallel micro groove and ridge structure. These ridges and grooves were attributed to the reorganization of cytoskeleton fiber bundles following the direction of blood flow shear stress. The structure and parameters of these morphologies were highly similar to the inner surface of blood vessels of the human, which facilitates cell adhesion growth to improve its proliferation, differentiation, and activity on the surface of PTLG.

摘要

具有优异机械性能和生物相容性的绿色可生物降解材料将为下一代高性能生物材料提供新的机会。本文首次报道了通过可行的固态拉伸工艺成功制备了新型聚(三亚甲基碳酸酯-丙交酯-乙交酯)(PTLG)血管支架的新型定向串晶,以同时提高机械性能和生物相容性。这种自增强血管支架的晶体结构从球晶转变为串晶,表明存在机械联锁效应,可以防止层片滑动,从而使机械强度显著提高到 333MPa。同时,它与典型的具有光滑表面结构的生物医学聚合物不同,所获得的 PTLG 血管支架具有仿生表面形貌,具有平行的微槽和脊结构。这些脊和槽归因于细胞骨架纤维束沿着血流切应力方向的重新组织。这些形态的结构和参数与人体血管的内表面高度相似,有利于细胞黏附生长,从而提高其在 PTLG 表面的增殖、分化和活性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cece/10910444/f29059416a02/am3c18093_0014.jpg
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