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评估种植于无胸腺鼠的工程化皮肤替代物中人类角质形成细胞的复制率。

Assessment of replication rates of human keratinocytes in engineered skin substitutes grafted to athymic mice.

机构信息

Department of Surgery, University of Cincinnati College of Medicine, Cincinnati, OH 45267-0558, USA.

出版信息

Wound Repair Regen. 2012 Jul-Aug;20(4):544-51. doi: 10.1111/j.1524-475X.2012.00807.x. Epub 2012 Jun 7.

Abstract

Stable closure of skin wounds with engineered skin substitutes (ESS) requires indefinite mitotic capacity to generate the epidermis. To evaluate whether keratinocytes in ESS exhibit the stem cell phenotype of label retention, ESS (n = 6-9/group) were pulsed with 5-bromo-2'-deoxyuridine (BrdU) in vitro, and after grafting to athymic mice (n = 3-6/group). Pulse and immediate chase in vitro labeled virtually all basal keratinocytes at day 8, with label uptake decreasing until day 22. Label retention in serial chase decreased more rapidly from day 8 to day 22, with a reorganization of BrdU-positive cells into clusters. Similarly, serial chase of labeled basal keratinocytes in vivo decreased sharply from day 20 to day 48 after grafting. Label uptake was assessed by immediate chases of basal keratinocytes, and decreased gradually to day 126, while total labeled cells remained relatively unchanged. These results demonstrate differential rates of label uptake and retention in basal keratinocytes of ESS in vitro and in vivo, and a proliferative phenotype with potential for long-term replication in the absence of hair follicles. Regulation of a proliferative phenotype in keratinocytes of ESS may improve the biological homology of tissue-engineered skin to natural skin, and contribute to more rapid and stable wound healing.

摘要

采用工程化皮肤替代物(ESS)稳定闭合皮肤伤口需要有无限的有丝分裂能力来产生表皮。为了评估 ESS 中的角质形成细胞是否表现出标签保留的干细胞表型,将 ESS(n=6-9/组)进行体外 BrdU(5-溴-2'-脱氧尿苷)脉冲标记,然后移植到无胸腺小鼠(n=3-6/组)。体外脉冲和即时追踪标记了第 8 天几乎所有的基底角质形成细胞,标记摄取量减少到第 22 天。从第 8 天到第 22 天,连续追踪标签保留的速度更快,BrdU 阳性细胞重新组织成簇。同样,体内标记的基底角质形成细胞连续追踪显示,在移植后第 20 天到第 48 天急剧减少。通过对基底角质形成细胞进行即时追踪来评估标记摄取情况,标记摄取量逐渐减少到第 126 天,而总标记细胞数量相对保持不变。这些结果表明,在体外和体内 ESS 的基底角质形成细胞中,标记摄取和保留的速度存在差异,并且具有潜在的长期复制能力,而无需毛囊。调节 ESS 角质形成细胞的增殖表型可能会提高组织工程皮肤与天然皮肤的生物学同源性,并有助于更快、更稳定的伤口愈合。

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