Tissue Architecture Modulates Compositional and Structural Properties of Corneal Myofibroblast-Derived Matrix.

IF 2.6 3区医学 Q2 OPHTHALMOLOGY

Translational Vision Science & Technology Pub Date : 2025-09-02 DOI:10.1167/tvst.14.9.9

Antonios Giannopoulos, Ludvig J Backman, Patrik Danielson

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引用次数: 0

Abstract

Purpose: To develop an in vitro model that mimics aspects of corneal healing in humans for uncovering key mechanisms involved in the mechanisms involved in the healing and scarring processes.

Methods: As part of the healing matrix, TGF-β1-induced and corneal-derived myofibroblasts were cultured in fibrin hydrogels with configurations that recapitulate the healthy (aligned) and wounded (random) microenvironment of the cornea.

Results: Evaluation of cellular alpha smooth muscle actin (α-SMA) and collagen hybridizing peptide (CHP) showed cell and matrix alignment, respectively. The aligned compared to the random constructs demonstrated an increased ability to synthesize total soluble proteins, including collagen type V, but collagen type I levels were reduced. This finding reveals a differential pattern for these proteins. Additionally, the collagen fibril diameters were larger in the aligned tissue constructs compared to the random constructs. Fibronectin and CHP colocalization patterns did not differ between groups; however, fibronectin and decorin were increased in the aligned group in contrast to tenascin C, which showed no difference.

Conclusions: These findings suggest that the alignment of the healing microenvironment plays a crucial role in modulating the structural properties of the extracellular matrix (ECM) and regulates the synthesis of key proteins that are closely involved in fibrillogenesis and are indicative of the quality of the deposited ECM.

Translational relevance: We developed a three-dimensional in vitro model that closely mimics in vivo conditions to investigate the role of corneal myofibroblasts in healing and regeneration. Ultimately, this model can help develop targeted antifibrotic therapies to prevent corneal scarring.

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组织结构调节角膜肌成纤维细胞衍生基质的组成和结构特性。

目的：建立一个模拟人类角膜愈合的体外模型，以揭示愈合和瘢痕形成过程中涉及的关键机制。方法：作为愈合基质的一部分，TGF-β1诱导的和角膜来源的肌成纤维细胞在纤维蛋白水凝胶中培养，其结构再现角膜健康（排列）和损伤（随机）微环境。结果：细胞α-平滑肌肌动蛋白（α-SMA）和胶原杂交肽（CHP）分别显示细胞和基质排列。与随机结构相比，排列的结构显示出合成总可溶性蛋白的能力增加，包括V型胶原蛋白，但I型胶原蛋白水平降低。这一发现揭示了这些蛋白质的不同模式。此外，与随机结构相比，排列组织结构中的胶原纤维直径更大。纤维连接蛋白和CHP的共定位模式在两组之间没有差异；然而，与tenascin C相比，排列组纤维连接蛋白和decorin增加，但没有差异。结论：这些研究结果表明，愈合微环境的排列在调节细胞外基质（ECM）的结构特性中起着至关重要的作用，并调节与纤维形成密切相关的关键蛋白质的合成，并指示沉积的ECM的质量。翻译相关性：我们开发了一个三维体外模型，密切模仿体内条件，以研究角膜肌成纤维细胞在愈合和再生中的作用。最终，该模型可以帮助开发靶向抗纤维化疗法来预防角膜瘢痕形成。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Translational Vision Science & Technology Engineering-Biomedical Engineering

CiteScore

5.70

自引率

3.30%

发文量

346

审稿时长

25 weeks

期刊介绍： Translational Vision Science & Technology (TVST), an official journal of the Association for Research in Vision and Ophthalmology (ARVO), an international organization whose purpose is to advance research worldwide into understanding the visual system and preventing, treating and curing its disorders, is an online, open access, peer-reviewed journal emphasizing multidisciplinary research that bridges the gap between basic research and clinical care. A highly qualified and diverse group of Associate Editors and Editorial Board Members is led by Editor-in-Chief Marco Zarbin, MD, PhD, FARVO. The journal covers a broad spectrum of work, including but not limited to: Applications of stem cell technology for regenerative medicine, Development of new animal models of human diseases, Tissue bioengineering, Chemical engineering to improve virus-based gene delivery, Nanotechnology for drug delivery, Design and synthesis of artificial extracellular matrices, Development of a true microsurgical operating environment, Refining data analysis algorithms to improve in vivo imaging technology, Results of Phase 1 clinical trials, Reverse translational ("bedside to bench") research. TVST seeks manuscripts from scientists and clinicians with diverse backgrounds ranging from basic chemistry to ophthalmic surgery that will advance or change the way we understand and/or treat vision-threatening diseases. TVST encourages the use of color, multimedia, hyperlinks, program code and other digital enhancements.