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外在巨噬细胞在肌腱祖细胞降解时起到保护作用:来自肌腱隔室串扰的组织工程模型的见解。

Extrinsic Macrophages Protect While Tendon Progenitors Degrade: Insights from a Tissue Engineered Model of Tendon Compartmental Crosstalk.

机构信息

Department of Orthopedics, Balgrist University Hospital, University of Zurich, Lengghalde 5, Zurich, 8008, Switzerland.

Institute for Biomechanics, ETH Zurich, Zurich, 8093, Switzerland.

出版信息

Adv Healthc Mater. 2021 Oct;10(20):e2100741. doi: 10.1002/adhm.202100741. Epub 2021 Sep 8.

DOI:10.1002/adhm.202100741
PMID:34494401
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11468160/
Abstract

Tendons are among the most mechanically stressed tissues of the body, with a functional core of type-I collagen fibers maintained by embedded stromal fibroblasts known as tenocytes. The intrinsic load-bearing core compartment of tendon is surrounded, nourished, and repaired by the extrinsic peritendon, a synovial-like tissue compartment with access to tendon stem/progenitor cells as well as blood monocytes. In vitro tendon model systems generally lack this important feature of tissue compartmentalization, while in vivo models are cumbersome when isolating multicellular mechanisms. To bridge this gap, an improved in vitro model of explanted tendon core stromal tissue (mouse tail tendon fascicles) surrounded by cell-laden collagen hydrogels that mimic extrinsic tissue compartments is suggested. Using this model, CD146 tendon stem/progenitor cell and CD45 F4/80 bone-marrow derived macrophage activity within a tendon injury-like niche are recapitulated. It is found that extrinsic stromal progenitors recruit to the damaged core, contribute to an overall increase in catabolic ECM gene expression, and accelerate the decrease in mechanical properties. Conversely, it is found that extrinsic bone-marrow derived macrophages in these conditions adopt a proresolution phenotype that mitigates rapid tissue breakdown by outwardly migrated tenocytes and F4/80 "tenophages" from the intrinsic tissue core.

摘要

肌腱是人体中机械应力最强的组织之一,其功能核心是由嵌入的基质成纤维细胞维持的 I 型胶原纤维。肌腱的固有承载核心部分被外被的腱周组织包围、滋养和修复,腱周组织是一种类似滑膜的组织间隙,其中有肌腱干/祖细胞以及血液单核细胞。体外肌腱模型系统通常缺乏这种重要的组织分区特征,而体内模型在分离多细胞机制时则很繁琐。为了弥补这一空白,建议建立一种改良的体外模型,即围绕富含细胞的胶原水凝胶植入离体肌腱核心基质组织(小鼠尾肌腱束),以模拟外组织间隙。使用该模型,在类似于肌腱损伤的龛位中重现了 CD146 肌腱干/祖细胞和 CD45 F4/80 骨髓来源巨噬细胞的活性。研究发现,外源性基质祖细胞募集到受损的核心部位,导致细胞外基质基因表达总体增加,并加速机械性能下降。相反,研究发现,在这些条件下,外源性骨髓来源的巨噬细胞表现出一种促解决的表型,通过向外迁移的肌腱细胞和 F4/80“肌腱吞噬细胞”从固有组织核心减轻快速的组织破坏。

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