肉芽组织
伤口愈合
细胞外基质
医学
间质细胞
再生(生物学)
血管生成
间充质干细胞
病理
解剖
基质(化学分析)
再生医学
生物医学工程
血管
细胞浸润
化学
细胞生物学
伤口闭合
新生血管
维斯坎
外围设备
基质金属蛋白酶
细胞疗法
收缩(语法)
丝状体
体内
周围神经病变
内皮干细胞
糖尿病神经病变
组织工程
作者
Colette A. Abbey,Joshua Benton,Erin Goebel,Jocelyn Ma,Sebastian Lomeli,Indu Kancharla,Ivan Juarez,Akshaya Kannan,Christopher Story,Andrew Haskell,Hussain Alcassab,Kayla J. Bayless,Carl A. Gregory
标识
DOI:10.64898/2026.02.20.707094
摘要
Abstract Despite the growing prevalence of non-healing diabetic wounds, no current treatment options overcome multifactorial deficits in repair. To this end, a mesenchymal stromal cell-derived regenerative extracellular matrix (rECM) was evaluated for the ability to accelerate cutaneous wound repair in leptin receptor-deficient (db/db) diabetic mice with paired full-thickness dorsal skin defects. A single dose of rECM significantly accelerated wound closure compared with vehicle controls. Also, rECM dose-dependently improved overall histological healing scores and modulated granulation tissue dynamics, with the highest dose promoting rapid resolution of granulation tissue relative to wound area. Spatial transcriptomics and immunofluorescence revealed that rECM drove robust formation of de novo peripheral nerve clusters characterized by the Schwann cell marker, p75. The rECM also enhanced vascular maturation in healed wounds, increasing average blood vessel size, smooth muscle actin–positive vessels, and vessel density within myofibroblast-rich regions. In a complementary 3D angiogenic sprouting model, rECM accelerated endothelial invasion and filopodia extension, and at higher concentrations induced contraction of collagen matrices consistent with accelerated resolution of granulation tissue. These data demonstrate that rECM accelerates closure of diabetic skin defects by coordinating faster granulation tissue remodeling with enhanced peripheral nerve formation and vascular maturation.
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