通过氧化铝纺织品诱导上皮间充质转化的拓扑结构,实现潜在的伤口愈合应用。

Deepanjalee Dutta, Titinun Nuntapramote, Maren Rehders, Klaudia Brix, Dorothea Brüggemann
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引用次数: 0

摘要

基底地形在决定细胞生长和细胞行为命运方面至关重要。尽管目前对潜在细胞信号通路的体外研究大多依赖于特定生长因子或化学物质的诱导,但较少探讨基底形貌对细胞特定变化的影响。本研究探讨了基底拓扑结构(特别是氧化铝纺织品的经编微纤维结构)对细胞行为的影响,重点研究了成纤维细胞和角质细胞在伤口愈合方面的潜在应用。首次将纺织品作为体外基质进行研究,结果表明,纺织品支持角质形成细胞的粘附,从而导致细胞形态以及 E 黏附因子和纤连蛋白的表达发生变化。这些地形诱导的变化类似于上皮细胞向间质转化(EMT),对伤口愈合至关重要,而且对角质形成细胞具有特异性,同样处理的成纤维细胞则没有这种变化。在平整的氧化铝基底上培养的角质形成细胞中,生化诱导的 EMT 与单独使用氧化铝纺织品时看到的变化相同,这表明经编微纤维拓扑可作为体外模型系统来诱导类似 EMT 的机制。这些结果加深了我们对基底拓扑如何影响伤口愈合中 EMT 相关过程的理解,为进一步评估氧化铝微纤维纺织品作为创新型伤口敷料铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Topography-Mediated Induction of Epithelial Mesenchymal Transition via Alumina Textiles for Potential Wound Healing Applications.

Substrate topography is vital in determining cell growth and fate of cellular behavior. Although current in vitro studies of the underlying cellular signaling pathways mostly rely on their induction by specific growth factors or chemicals, the influence of substrate topography on specific changes in cells has been explored less often. This study explores the impact of substrate topography, specifically the tricot knit microfibrous structure of alumina textiles, on cell behavior, focusing on fibroblasts and keratinocytes for potential wound healing applications. The textiles, studied for the first time as in vitro substrates, demonstrated support for keratinocyte adhesion, leading to alterations in cell morphology and the expression of E-cadherin and fibronectin. These topography-induced changes resembled the epithelial-to-mesenchymal transition (EMT), crucial for wound healing, and were specific to keratinocytes and absent in identically treated fibroblasts. Biochemically induced EMT in keratinocytes cultured on flat alumina substrates mirrored the changes seen with alumina textiles alone, suggesting the tricot knit microfibrous topography could serve as an in vitro model system to induce EMT-like mechanisms. These results enhance our understanding of how substrate topography influences EMT-related processes in wound healing, paving the way for further evaluation of microfibrous alumina textiles as innovative wound dressings.

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