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基于骨髓干细胞和脱细胞胶原蛋白的模块化环策略仿生气管工程在广泛气管重建中的应用

Biomimetic Trachea Engineering via a Modular Ring Strategy Based on Bone-Marrow Stem Cells and Atelocollagen for Use in Extensive Tracheal Reconstruction.

作者信息

Xu Yong, Dai Jie, Zhu Xinsheng, Cao Runfeng, Song Nan, Liu Ming, Liu Xiaogang, Zhu Junjie, Pan Feng, Qin Linlin, Jiang Gening, Wang Haifeng, Yang Yang

机构信息

Department of Thoracic Surgery, Shanghai Pulmonary Hospital, School of Medicine, Tongji University, Shanghai, 200433, China.

出版信息

Adv Mater. 2022 Feb;34(6):e2106755. doi: 10.1002/adma.202106755. Epub 2021 Dec 23.

DOI:10.1002/adma.202106755
PMID:34741771
Abstract

The fabrication of biomimetic tracheas with a architecture of cartilaginous rings alternately interspersed between vascularized fibrous tissue (CRVFT) has the potential to perfectly recapitulate the normal tracheal structure and function. Herein, the development of a customized chondroitin-sulfate-incorporating type-II atelocollagen (COL II/CS) scaffold with excellent chondrogenic capacity and a type-I atelocollagen (COL I) scaffold to facilitate the formation of vascularized fibrous tissue is described. An efficient modular ring strategy is then adopted to develop a CRVFT-based biomimetic trachea. The in vitro engineering of cartilaginous rings is achieved via the recellularization of ring-shaped COL II/CS scaffolds using bone marrow stem cells as a mimetic for native cartilaginous ring tissue. A CRVFT-based trachea with biomimetic mechanical properties, composed of bionic biochemical components, is additionally successfully generated in vivo via the alternating stacking of cartilaginous rings and ring-shaped COL I scaffolds on a silicone pipe. The resultant biomimetic trachea with pedicled muscular flaps is used for extensive tracheal reconstruction and exhibits satisfactory therapeutic outcomes with structural and functional properties similar to those of native trachea. This is the first study to utilize stem cells for long-segmental tracheal cartilaginous regeneration and this represents a promising method for extensive tracheal reconstruction.

摘要

构建具有软骨环结构交替穿插于血管化纤维组织(CRVFT)中的仿生气管,有可能完美重现正常气管的结构和功能。本文描述了一种定制的含硫酸软骨素的II型不完全胶原蛋白(COL II/CS)支架的开发,该支架具有出色的软骨生成能力,以及一种I型胶原蛋白(COL I)支架以促进血管化纤维组织的形成。然后采用一种有效的模块化环策略来开发基于CRVFT的仿生气管。软骨环的体外工程通过使用骨髓干细胞对环形COL II/CS支架进行再细胞化来实现,以模拟天然软骨环组织。此外,通过在硅胶管上交替堆叠软骨环和环形COL I支架,在体内成功生成了具有仿生力学性能、由仿生生化成分组成的基于CRVFT的气管。所得带蒂肌瓣的仿生气管用于广泛的气管重建,并表现出令人满意的治疗效果,其结构和功能特性与天然气管相似。这是第一项利用干细胞进行长节段气管软骨再生的研究,这代表了一种用于广泛气管重建的有前景的方法。

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