Tailoring the secretome composition of mesenchymal stem cells to augment specific functions of epidermal regeneration: an in vitro diabetic model.

Frontiers in Medical Technology Pub Date : 2023-06-12 eCollection Date: 2023-01-01 DOI:10.3389/fmedt.2023.1194314
Jacob G Hodge, Jennifer L Robinson, Adam J Mellott
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Abstract

Introduction: Wound healing consists of a dynamic series of events that are highly dependent on paracrine factors for proper progression through the phases of wound healing. Inappropriate progression through the phases is associated with insufficient epidermal regeneration (i.e., re-epithelialization) of wounds and subsequent propagation of chronic wounds, such as diabetic ulcers, which are associated with increased patient morbidity. Recently, investigation into the dynamic secretome of Adipose-derived Mesenchymal Stem Cells (ASCs), have shown promise in augmenting the wound healing response of chronic diabetic wounds. However, currently utilized 2D culture techniques are known to drastically alter the regenerative phenotype of ASCs. In this study a novel tissue-mimetic 3D system was utilized as a means to culture ASCs.

Methods: The capacity for the ASC secretome to augment epidermal regeneration activity was then evaluated after exposure of ASCs to "wound priming stimuli" in 2D and 3D. The priming stimuli consisted of coating the 2D and 3D systems with the wound matrix proteins, collagen type I, fibronectin, and fibrin. To understand the potential benefit of the ASC secretome in the context of diabetic wounds, keratinocytes (KCs) were exposed to super-physiological glucose levels to induce a diabetic-like phenotype (idKCs).

Results: Relative to KCs, idKC exhibited a 52% and 23% decline in proliferation and migration, respectively. Subsequently, analyses of the ASC secretome were performed. ASC conditioned media (ASC-CM) from tissue-mimetic culture demonstrated a > 50% increase secretion of proteins and a 2-fold increase in secreted EVs, relative to 2D culture. Interestingly, the different priming stimuli did not alter the total amount of protein or EVs secreted within the tissue-mimetic system. However, evaluation of specific soluble proteins via ELISA revealed significant differences in key epidermal regeneration factors, such as EGF, IGF-1, FGF-2, MMP-1, TIMP-1, and TGFβ-1. Additionally, the relative effect of ASC-EVs from the 2D and 3D system on idKCs epidermal regeneration functionality varied significantly, with EVs from 3D-Collagen culture providing the most significant benefit on idKC activity.

Discussion: Together, these data support the utilization of tissue-mimetic culture system to enhance the adaptability and secretory activity of MSC-like populations in order to generate tailored biologics, via priming stimuli, for specific wound healing applications.

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定制间充质干细胞的分泌组成分,增强表皮再生的特定功能:体外糖尿病模型。
简介伤口愈合由一系列动态事件组成,伤口愈合各阶段的正常进展高度依赖于旁分泌因子。不适当的阶段性进展与伤口表皮再生(即再上皮化)不足以及随后慢性伤口(如糖尿病溃疡)的扩展有关,而慢性伤口与患者发病率的增加有关。最近,对脂肪间充质干细胞(ASCs)动态分泌组的研究表明,ASCs 有望增强慢性糖尿病伤口的愈合反应。然而,目前使用的二维培养技术会大幅改变间充质干细胞的再生表型。本研究采用了一种新型组织模拟三维系统来培养 ASCs:方法:将 ASCs 暴露于二维和三维的 "伤口启动刺激 "后,评估 ASC 分泌组增强表皮再生活性的能力。伤口启动刺激包括在二维和三维系统上涂抹伤口基质蛋白、I型胶原蛋白、纤连蛋白和纤维蛋白。为了了解 ASC 分泌组在糖尿病伤口中的潜在益处,角质形成细胞(KCs)暴露在超生理葡萄糖水平下,诱导出糖尿病样表型(idKCs):结果:相对于 KCs,idKC 的增殖和迁移率分别下降了 52% 和 23%。随后,对ASC分泌组进行了分析。与二维培养相比,组织模拟培养的ASC条件培养基(ASC-CM)显示蛋白质分泌量增加了50%以上,分泌的EV增加了2倍。有趣的是,不同的启动刺激并没有改变组织模拟系统中分泌的蛋白质或EVs总量。然而,通过酶联免疫吸附法评估特定的可溶性蛋白发现,关键的表皮再生因子(如 EGF、IGF-1、FGF-2、MMP-1、TIMP-1 和 TGFβ-1)存在显著差异。此外,二维和三维系统中的ASC-EV对idKC表皮再生功能的相对影响也有显著差异,其中三维-胶原培养的EV对idKC活性的益处最大:总之,这些数据支持利用组织模拟培养系统来提高间充质干细胞类群的适应性和分泌活性,以便通过引物刺激产生定制的生物制剂,用于特定的伤口愈合应用。
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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