通过使用显微镜和光学相干断层扫描测量锚定胶原基质的压实,可预测成纤维细胞张力的产生

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2019-01-01 DOI:10.1080/19336918.2019.1644855
Melville B Vaughan, Gang Xu, Tracy L. Morris, Pratiksha Kshetri, Jing X Herwig
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引用次数: 3

摘要

摘要锚定成纤维细胞聚集的胶原基质(aFPCM)是研究纤维收缩性疾病机制的合适模型。我们的目标是确定开发过程中FPCM高度降低(压实)是否足以预测张力的产生。每天通过传统的光学显微镜和光学相干断层扫描(OCT)系统对压实进行量化。通过将其从锚定处释放,可发现aFPCM收缩。我们发现aFPCM收缩增加与压实增加相关。细胞松弛素D处理可逆地抑制压实。因此,我们证明了aFPCM高度降低可以有效地测量胶原蛋白基质在发育或治疗过程中的压实、收缩和相对成熟度。此外,我们发现OCT适用于对培养物中aFPCM的横截面形态进行有效成像。这项研究将为更有效地研究组织环境中伤口愈合和Dupuytren挛缩的迁移和收缩机制(以及针对迁移和收缩的治疗方法)铺平道路。
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Predictable fibroblast tension generation by measuring compaction of anchored collagen matrices using microscopy and optical coherence tomography
ABSTRACT The anchored fibroblast-populated collagen matrix (aFPCM) is an appropriate model to study fibrocontractive disease mechanisms. Our goal was to determine if aFPCM height reduction (compaction) during development is sufficient to predict tension generation. Compaction was quantified daily by both traditional light microscopy and an optical coherence tomography (OCT) system. Contraction in aFPCM was revealed by releasing them from anchorage. We found that aFPCM contraction increase was correlated to the compaction increase. Cytochalasin D treatment reversibly inhibited compaction. Therefore, we demonstrated that aFPCM height reduction efficiently measures compaction, contraction, and relative maturity of the collagen matrix during development or treatment. In addition, we showed that OCT is suitable for effectively imaging the cross-sectional morphology of the aFPCM in culture. This study will pave the way for more efficient studies on the mechanisms of (and treatments that target) migration and contraction in wound healing and Dupuytren’s contracture in a tissue environment.
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CiteScore
7.20
自引率
4.30%
发文量
567
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