Fibroblast alignment and matrix remodeling induced by a stiffness gradient in a skin-derived extracellular matrix hydrogel

IF 9.4 1区 医学 Q1 ENGINEERING, BIOMEDICAL
Fenghua Zhao , Meng Zhang , Mehmet Nizamoglu , Hans J. Kaper , Linda A. Brouwer , Theo Borghuis , Janette K. Burgess , Martin C. Harmsen , Prashant K. Sharma
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引用次数: 0

Abstract

Large skin injuries heal as scars. Stiffness gradually increases from normal skin to scar tissue (20x higher), due to excessive deposition and crosslinking of extracellular matrix (ECM) mostly produced by (myo)fibroblasts. Using a custom mold, skin-derived ECM hydrogels (dECM) were UV crosslinked after diffusion of ruthenium (Ru) to produce a Ru-dECM gradient hydrogel. The Ru diffusion gradient equates to a stiffness gradient and models physiology of the scarred skin. Crosslinking in Ru-dECM hydrogels results in a 23-fold increase in stiffness from a stiffness similar to that of normal skin. Collagen fiber density increases in a stiffness-dependent fashion while stress relaxation also alters, with one additional Maxwell element necessary for characterizing Ru-dECM. Alignment of fibroblasts encapsulated in hydrogels suggests that the stiffness gradient directs fibroblasts to orientate at ∼45 ° in regions below 120 kPa. In areas above 120 kPa, fibroblasts decrease the stiffness prior to adjusting their orientation. Furthermore, fibroblasts remodel their surrounding ECM in a gradient-dependent fashion, with rearrangement of cell-surrounding ECM in high-stiffness areas, and formation of interlaced collagen bundles in low-stiffness areas. Overall, this study shows that fibroblasts remodel their local environment to generate an optimal ECM mechanical and topographical environment.

Statement of significance

This study developed a versatile in vitro model with a gradient stiffness using skin-derived ECM hydrogel with unchanged biochemical environment. Using Ruthenium crosslinking, a 20-fold stiffness increase was achieved as observed in fibrotic skin.

The interaction between fibroblasts and matrix depends on changes in the matrix stiffness. The stiffness gradient directed the alignment of fibroblasts with ∼45° in regions with≤ 120 kPa. The cells in regions with the higher stiffness decreased stiffness first and then oriented themselves. Furthermore, fibroblasts remodeled surrounding ECM and regulated its mechanics in a gradient-dependent fashion to reach an optimal condition.

Our study highlights the dynamic interplay between cells and surrounding matrix, shedding light on potential mechanisms and strategies to target scar formation and remodeling.

Abstract Image

源自皮肤的细胞外基质水凝胶的硬度梯度诱导成纤维细胞排列和基质重塑。
大面积皮肤损伤愈合后会形成疤痕。由于细胞外基质(ECM)的过度沉积和交联,大部分由(肌)成纤维细胞产生,因此从正常皮肤到疤痕组织的硬度逐渐增加(高出 20 倍)。使用定制模具,将源自皮肤的 ECM 水凝胶(dECM)在钌(Ru)扩散后进行紫外交联,生成 Ru-dECM 梯度水凝胶。Ru 扩散梯度相当于硬度梯度,是疤痕皮肤的生理模型。Ru-dECM 水凝胶交联后的硬度比正常皮肤的硬度增加了 23 倍。胶原纤维密度的增加与硬度有关,同时应力松弛也发生了变化,Ru-dECM 的表征还需要一个额外的麦克斯韦元素。封装在水凝胶中的成纤维细胞的排列表明,在低于 120 kPa 的区域,硬度梯度引导成纤维细胞以 ∼45 ° 的角度定向。在 120 千帕以上的区域,成纤维细胞在调整方向之前会降低硬度。此外,成纤维细胞以梯度依赖的方式重塑其周围的 ECM,在高硬度区域,细胞周围的 ECM 重新排列,而在低硬度区域,则形成交错的胶原束。总之,这项研究表明,成纤维细胞可重塑其局部环境,以生成最佳的 ECM 机械和地形环境。意义说明:本研究利用生化环境不变的皮肤衍生 ECM 水凝胶,开发了一种具有梯度硬度的多功能体外模型。利用钌交联技术,实现了在纤维化皮肤中观察到的 20 倍硬度增加。成纤维细胞与基质之间的相互作用取决于基质硬度的变化。在硬度≤ 120 kPa 的区域,硬度梯度引导成纤维细胞以 ∼ 45° 的角度排列。刚度较高区域的细胞首先降低刚度,然后自行定向。此外,成纤维细胞重塑了周围的 ECM,并以梯度依赖的方式调节其力学,以达到最佳状态。我们的研究强调了细胞与周围基质之间的动态相互作用,揭示了针对疤痕形成和重塑的潜在机制和策略。
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来源期刊
Acta Biomaterialia
Acta Biomaterialia 工程技术-材料科学:生物材料
CiteScore
16.80
自引率
3.10%
发文量
776
审稿时长
30 days
期刊介绍: Acta Biomaterialia is a monthly peer-reviewed scientific journal published by Elsevier. The journal was established in January 2005. The editor-in-chief is W.R. Wagner (University of Pittsburgh). The journal covers research in biomaterials science, including the interrelationship of biomaterial structure and function from macroscale to nanoscale. Topical coverage includes biomedical and biocompatible materials.
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