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首页> 外文期刊>Biomaterials >Fabrication of nanofibrous microcarriers mimicking extracellular matrix for functional microtissue formation and cartilage regeneration
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Fabrication of nanofibrous microcarriers mimicking extracellular matrix for functional microtissue formation and cartilage regeneration

机译:纳米纤维微载体模拟肌室基质的纳米纤维微载体进行功能性微训练形成和软骨再生

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摘要

Cartilage has rather limited capacities for self-repair and regeneration. To repair complexly shaped cartilage tissue defects, we propose the application of microtissues fabricated from bone marrow-derived mesenchymal stem cells (BMSCs) cultured in natural bionic nanofibrous microcarriers (NF-MCs). The NF-MCs were structurally and functionally designed to mimic natural extracellular matrix (ECM) by crosslinking dialdehyde bacterial cellulose (DBC) with DL-allo-hydroxylysine (DHYL) and complexing chitosan (CS) with DHYL through electrostatic interactions. The orthogonal design allows for fine tuning of fiber diameter, pore size, porosity, mechanical properties, and biodegradation rate of the NF-MC. BMSCs cultured in NF-MCs showed improved proliferation compared with those cultured in chitosan microcarriers (CS-MCs). After three-week culture under microgravity conditions, functional cartilage microtissues were generated. When implanted into a knee articular cartilage defect in mice, the microtissue showed superior in vivo cartilage repair as characterized by cell tracking, histology, micro CT image, and gait analysis. Versatile in natural biopolymer design and biomimetic in nanofibrous component embedded in macroporous microcarriers, these injectable NC-MCs demonstrate to be effective carriers for cell proliferation and differentiation. Furthermore, the functional microtissues also show their prospect in repair of cartilage tissue, and suggest their potential for other tissues in general. (C) 2018 Elsevier Ltd. All rights reserved.
机译:软骨具有相当有限的自我修复和再生能力。为了修复复杂的软骨组织缺陷,我们提出了在天然仿生纳米纤维微载体(NF-MCS)中培养的骨髓衍生的间充质干细胞(BMSC)制造的微小发布。通过通过静电相互作用将二醛细菌纤维素(DBC)与Dl-Allo-羟基氨酮(DBC)交联通过静电相互作用将二醛细菌纤维素(DBC)和络合壳聚糖(Cs)络合,通过静电相互作用来在结构上和功能设计成模拟天然细胞外基质(ECM)。正交设计允许微观调整纤维直径,孔径,孔隙率,机械性能和NF-MC的生物降解率。与在壳聚糖微载体(CS-MCS)中培养的人相比,NF-MCS中培养的BMSCs显示出改善的增殖。在微重力条件下三周培养后,产生功能性软骨微发射。当植入小鼠的膝关节软骨缺陷时,微小仪表在体内软骨修复中显示出优异的,其特征在于细胞跟踪,组织学,微CT图像和步态分析。在嵌入大孔微载体中的天然生物聚合物设计和仿生染色中的仿生组成,这些可注射的NC-MCS表明是细胞增殖和分化的有效载体。此外,功能性微调还显示出他们在修复软骨组织的前景,并表明它们通常对其他组织的潜力。 (c)2018年elestvier有限公司保留所有权利。

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  • 来源
    《Biomaterials》 |2018年第2018期|共15页
  • 作者

    Wang Yansen; Yuan Xueling; Yu Kun; Meng Haoye; Zheng Yudong; Peng Jiang; Lu Shibi; Liu Xiaotong; Xie Yajie; Qiao Kun;

  • 作者单位

    Univ Sci &

    Technol Beijing Sch Mat Sci &

    Engn Beijing Peoples R China;

    Chinese Peoples Liberat Army Gen Hosp PLA Inst Orthoped Key Lab Musculoskeletal Trauma &

    War;

    Univ Sci &

    Technol Beijing Sch Mat Sci &

    Engn Beijing Peoples R China;

    Univ Sci &

    Technol Beijing Sch Mat Sci &

    Engn Beijing Peoples R China;

    Univ Sci &

    Technol Beijing Sch Mat Sci &

    Engn Beijing Peoples R China;

    Chinese Peoples Liberat Army Gen Hosp PLA Inst Orthoped Key Lab Musculoskeletal Trauma &

    War;

    Chinese Peoples Liberat Army Gen Hosp PLA Inst Orthoped Key Lab Musculoskeletal Trauma &

    War;

    Univ Sci &

    Technol Beijing Sch Mat Sci &

    Engn Beijing Peoples R China;

    Univ Sci &

    Technol Beijing Sch Mat Sci &

    Engn Beijing Peoples R China;

    Univ Sci &

    Technol Beijing Sch Mat Sci &

    Engn Beijing Peoples R China;

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  • 原文格式 PDF
  • 正文语种 eng
  • 中图分类 生物医学工程;
  • 关键词

    Nanofibrous microcarriers; Microtissue; Dialdehyde bacterial cellulose; Chitosan; Cartilage regeneration;

    机译:纳米纤维微载体;Microtssue;二醛细菌纤维素;壳聚糖;软骨再生;

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