用于引导膀胱组织再生的合成水凝胶基质。

Catharina A M Adelöw, Peter Frey
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引用次数: 20

摘要

组织工程旨在为损伤或疾病部位的修复提供一个临时支架,能够在基质蛋白合成和重组发生时支持细胞附着和生长。膀胱组织工程虽然相对成功,但由于平滑肌细胞(SMCs)从静止的收缩型表型转变为合成的增殖型表型,即肌成纤维细胞,因此在支架植入部位会形成疤痕组织。我们假设,在整合素结合肽修饰的酶降解聚乙二醇(PEG)水凝胶中培养人SMCs,并与人尿路上皮细胞(UCs)共培养,将为其随后分化为静止SMCs所需的环境提供一些见解。我们已经建立了人类膀胱UCs、SMCs和成纤维细胞的分离、培养和表征方案,并研究了SMCs和UCs的共培养条件。通过改变细胞粘附肽、PEG和交联剂的量,并使用光学和荧光显微镜检查,研究了促进这些细胞生长的最佳PEG水凝胶特性。此外,用组织学和免疫组织化学方法检测了接种后14天凝胶内和凝胶表面的细胞组织。我们研究了将UCs和SMCs整合到PEG水凝胶中的共培养模型,模拟膀胱壁的一部分用于重建目的,这也有助于理解SMC分化的潜在基本机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Synthetic hydrogel matrices for guided bladder tissue regeneration.

Tissue engineering aims to provide a temporary scaffold for repair at the site of injury or disease that is able to support cell attachment and growth while synthesis of matrix proteins and reorganization take place. Although relatively successful, bladder tissue engineering suffers from the formation of scar tissue at the scaffold implant site partly due to the phenotypic switch of smooth muscle cells (SMCs) from a quiescent contractile phenotype to a synthetic proliferative phenotype, known as myofibroblast. We hypothesize that culturing human SMCs in enzymatically degradable poly(ethylene) glycol (PEG) hydrogels modified with integrin-binding peptides, and in co-culture with human urothelial cells (UCs), will offer some insight as to the required environment for their subsequent differentiation into quiescent SMCs. We have established protocols for isolation, culture, and characterization of human bladder UCs, SMCs, and fibroblasts and investigated co-culture conditions for SMCs and UCs. The optimal PEG hydrogel properties, promoting growth of these cells, have been investigated by varying the amounts of cell adhesion peptide, PEG, and crosslinker and examined using light and fluorescence microscopy. Furthermore, the cell organization within and on top of gels 14 days post seeding has been examined by histology and immunohistochemistry. We have investigated a co-culture model for UCs and SMCs integrated into PEG hydrogels, mimicking a section of the bladder wall for reconstructive purposes that also could contribute to the understanding of the underlying basic mechanisms of SMC differentiation.

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