间充质干细胞
阿格里坎
间质细胞
剪应力
硫氧化物9
蛋白多糖
软骨发生
II型胶原
剪切(地质)
化学
细胞生物学
细胞外基质
软骨
机械转化
生物物理学
生物医学工程
细胞
解剖
材料科学
组织工程
生物反应器
Ⅰ型胶原
电池类型
基因表达
基质(化学分析)
关节软骨
细胞培养
糖胺聚糖
软骨细胞
剪切力
作者
Terreill Robertson,Alec W. Schuler,Pakkanpat P. Pondipornnont,Ryan R. Driskell,Lawrence J. Bonassar,B. Arda Gozen,Wen‐Ji Dong,David B. Thiessen,Bernard Van Wie
标识
DOI:10.1021/acsbiomaterials.5c01183
摘要
Recreating articular cartilage trilayered patterning for an engineered in vitro cell construct holds promise for advancing cartilage repair efforts. Our approach involves the development of a multichambered perfusion tissue bioreactor that regulates fluid shear stress levels similar to the gradated hydrodynamic environment in articular cartilage. COMSOL modeling reveals our tapered cell chamber design will produce three different shear levels, high in the 22-41 mPa range, medium in the 4.5-8.4 mPa range, and low in the 2.2-3.8 mPa range and distributed across the surface of our mesenchymal stromal cell (MSC) encapsulated construct. In a 14-day bioreactor culture, we assess how the fluid shear magnitude and cell vertical location within a 3D construct influence cell chondrogenesis. Notably, Sox9 expression for MSCs cultivated in our reactor shows spatially patterned gene upregulations that encode key chondrogenic marker proteins. Beginning with the high shear stress region, lubricin and type II collagen gene increases of 410- and 370-fold indicate cell movement toward a superficial zone archetype, which is further supported by histological and immunohistochemical stains illustrating the formation of a dense proteoglycan matrix enriched with lubricin, versican, and collagen types I and II molecules. For the medium shear stress region, high aggrecan and type II collagen gene expressions of 2.3- and 400-fold, respectively, along with high proteoglycan analysis, show movement toward a superficial/midzone cartilage archetype. For low shear stress regions, higher collagen type II and X gene upregulations of 550- and 8300-fold, the latter being 2× of that for the high shear regime, indicate cell movement toward deep zone characteristics. Collectively, biochemical analysis, histology, and gene expression data demonstrate that our fluid shear bioreactor induces formation of a stratified structure within tissue-engineered constructs, demonstrating the feasibility of using this approach to recapitulate the structure of native articular cartilage.
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