基于电刺激的脱细胞基质膀胱贴片促进大鼠膀胱修复

IF 5.4 2区医学 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Biomaterials Science & Engineering Pub Date : 2024-10-14 Epub Date: 2024-09-06 DOI:10.1021/acsbiomaterials.4c00961

Zhengyun Ling, Haoqian Zhang, Jian Zhao, Pengchao Wang, Ziyan An, Shuwei Xiao, Yanfeng Sun, Weijun Fu

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引用次数: 0

摘要

膀胱组织工程在修复先天性和后天性膀胱缺损方面具有巨大潜力。然而，工程移植物的有效性往往受到血管化和神经再生不足的限制。本研究利用四种主要生物材料--甲基丙烯酰明胶（Gelatin methacryloyl，GelMA）、甲壳素纳米晶（Chitin nanocrystals，ChiNC）、碳化钛（Titanium carbide，MXene）和脂肪干细胞（adipose-derived stem cells，ADSC）--按特定比例配制成两种生物墨水，即 GCM0.2 和 GCM0.2-ADSC。将这些生物墨水三维打印到膀胱无细胞基质（BAM）补片上，制成BAM-GCM0.2和BAM-GCM0.2-ADSC补片。BAM-GCM0.2-ADSC补片经过电刺激后产生GCM0.2-ADSC-ES膀胱补片。这些补片被用于修复大鼠膀胱缺损，并与对照组进行了对比评估，对照组进行了部分膀胱切除术，然后直接缝合。我们的研究结果表明，加入 ADSC 和电刺激可显著提高大鼠膀胱平滑肌（从 [24.052 ± 2.782] % 提高到 [57.380 ± 4.017] %）、血管（从 [5.326 ± 0.703] % 提高到 [12.723 ± 1.440] %）和神经（从 [0.227 ± 0.017] % 提高到 [1.369 ± 0.218] %）的再生能力。这项研究强调了 GCM0.2-ADSC-ES 补丁卓越的膀胱修复能力，并为膀胱缺损修复开辟了新的途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Electrostimulation-Based Decellularized Matrix Bladder Patch Promotes Bladder Repair in Rats.

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Electrostimulation-Based Decellularized Matrix Bladder Patch Promotes Bladder Repair in Rats.

Bladder tissue engineering offers significant potential for repairing defects resulting from congenital and acquired conditions. However, the effectiveness of engineered grafts is often constrained by insufficient vascularization and neural regeneration. This study utilized four primary biomaterials─gelatin methacryloyl (GelMA), chitin nanocrystals (ChiNC), titanium carbide (MXene), and adipose-derived stem cells (ADSC)─to formulate two types of bioinks, GCM0.2 and GCM0.2-ADSC, in specified proportions. These bioinks were 3D printed onto bladder acellular matrix (BAM) patches to create BAM-GCM0.2 and BAM-GCM0.2-ADSC patches. The BAM-GCM0.2-ADSC patches underwent electrical stimulation to yield GCM0.2-ADSC-ES bladder patches. Employed for the repair of rat bladder defects, these patches were evaluated against a Control group, which underwent partial cystectomy followed by direct suturing. Our findings indicate that the inclusion of ADSC and electrical stimulation significantly enhances the regeneration of rat bladder smooth muscle (from [24.052 ± 2.782] % to [57.380 ± 4.017] %), blood vessels (from [5.326 ± 0.703] % to [12.723 ± 1.440] %), and nerves (from [0.227 ± 0.017] % to [1.369 ± 0.218] %). This research underscores the superior bladder repair capabilities of the GCM0.2-ADSC-ES patch and opens new pathways for bladder defect repair.

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来源期刊

ACS Biomaterials Science & Engineering Materials Science-Biomaterials

CiteScore

10.30

自引率

3.40%

发文量

413

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