Development of an in vitro fibrotic scar model of spinal cord injury using macromolecular crowding

IF 2.3 4区医学 Q2 BIOCHEMICAL RESEARCH METHODS

Journal of Neuroscience Methods Pub Date : 2025-10-12 DOI:10.1016/j.jneumeth.2025.110601

Sorour Nemati , Alanna Stanley , Michelle Kilcoyne , Dimitrios Zeugolis , Siobhan S. McMahon

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引用次数: 0

Abstract

Background

Spinal cord injury (SCI) results in a cascade of cellular and molecular events that lead to permanent tissue damage and functional impairment. A key consequence of this injury is the formation of both glial and fibrotic scars, which pose significant barriers to regeneration. The fibrotic scar that forms following SCI remains a significant therapeutic challenge. One major obstacle in developing anti-fibrotic compounds is the absence of a comprehensive in vitro screening system.

New method

In this study, we employed a macromolecular crowding (MMC) technique to accelerate ECM deposition. Leptomeningeal (LPG) cells were cultured in media supplemented with the MMC Ficoll (FC). To mimic the injury environment in vivo, the cells were exposed to either physical or chemical injury.

Results

The growth and metabolic activity of the LPG cells remained unchanged under these different injuries and treatments. Groups supplemented with the MMC FC exhibited higher deposition of ECM proteins involved in fibrotic scar formation, including fibronectin, collagen IV, collagen I, and laminin, compared to those without FC.

Comparison with existing methods

A key limitation of conventional cell culture in aqueous media is its clear difference from the naturally ‘crowded’ tissue environment, resulting in a slow rate of ECM protein deposition. Using the MMC approach, we successfully accelerated ECM protein deposition within an in vitro model of the fibrotic scar.

Conclusions

Supplementing LPG culture media with MMCs can effectively mimic the fibrotic scar environment, providing a valuable refinement in developing SCI in vitro models for drug screening and therapeutic applications.

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利用大分子拥挤技术建立脊髓损伤纤维化瘢痕模型。

背景：脊髓损伤（SCI）导致一系列细胞和分子事件，导致永久性组织损伤和功能损伤。这种损伤的一个关键后果是神经胶质和纤维化疤痕的形成，这对再生构成了重大障碍。脊髓损伤后形成的纤维化瘢痕仍然是一个重大的治疗挑战。开发抗纤维化化合物的一个主要障碍是缺乏全面的体外筛选系统。新方法：在本研究中，我们采用大分子拥挤（MMC）技术来加速ECM的沉积。将Leptomeningeal （LPG）细胞培养在添加了MMC Ficoll （FC）的培养基中。为了模拟体内的损伤环境，将细胞暴露于物理或化学损伤中。结果：在不同的损伤和处理下，液化石油气细胞的生长和代谢活性没有变化。与未添加FC的组相比，添加MMC FC的组显示出参与纤维化瘢痕形成的ECM蛋白的沉积量更高，包括纤维连接蛋白、胶原IV、胶原I和层粘连蛋白。与现有方法的比较：在水培养基中传统细胞培养的一个关键限制是它与自然“拥挤”的组织环境明显不同，导致ECM蛋白沉积速度缓慢。使用MMC方法，我们成功地加速了体外纤维化疤痕模型中的ECM蛋白沉积。结论：在LPG培养基中添加MMCs可以有效地模拟纤维化疤痕环境，为开发用于药物筛选和治疗应用的SCI体外模型提供了有价值的改进。

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

Journal of Neuroscience Methods 医学-神经科学

CiteScore

7.10

自引率

3.30%

发文量

226

审稿时长

52 days

期刊介绍： The Journal of Neuroscience Methods publishes papers that describe new methods that are specifically for neuroscience research conducted in invertebrates, vertebrates or in man. Major methodological improvements or important refinements of established neuroscience methods are also considered for publication. The Journal''s Scope includes all aspects of contemporary neuroscience research, including anatomical, behavioural, biochemical, cellular, computational, molecular, invasive and non-invasive imaging, optogenetic, and physiological research investigations.