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小鼠烧伤严重程度增加与循环血管生成细胞动员延迟的关联。

Association of increasing burn severity in mice with delayed mobilization of circulating angiogenic cells.

作者信息

Zhang Xianjie, Wei Xiaofei, Liu Lixin, Marti Guy P, Ghanamah Mohammed S, Arshad Muhammad J, Strom Lori, Spence Robert, Jeng James, Milner Stephen, Harmon John W, Semenza Gregg L

机构信息

Section of Surgical Sciences, Johns Hopkins Bayview Medical Center, 4940 Eastern Ave., Baltimore, MD 21224, USA.

出版信息

Arch Surg. 2010 Mar;145(3):259-66. doi: 10.1001/archsurg.2009.285.

DOI:10.1001/archsurg.2009.285
PMID:20231626
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4209728/
Abstract

OBJECTIVE

To perform a systematic exploration of the phenomenon of mobilization of circulating angiogenic cells (CACs) in an animal model. This phenomenon has been observed in patients with cutaneous burn wounds and may be an important mechanism for vasculogenesis in burn wound healing.

DESIGN

We used a murine model, in which burn depth can be varied precisely, and a validated culture method for quantifying circulating CACs.

SETTING

Michael D. Hendrix Burn Research Center, Baltimore, Maryland.

PARTICIPANTS

Male 129S1/SvImJ mice, aged 8 weeks, and 31 patients aged 19-59 years with burn injury on 1% to 64% of the body surface area and evidence of hemodynamic stability.

MAIN OUTCOME MEASURES

Burn wound histological features, including immunohistochemistry for blood vessels with CD31 and alpha-smooth muscle actin antibodies, blood flow measured with laser Doppler perfusion imaging, and mobilization of CACs into circulating blood measured with a validated culture technique.

RESULTS

Increasing burn depth resulted in a progressive delay in the time to mobilization of circulating CACs and reduced mobilization of CACs. This delay and reduction in CAC mobilization was associated with reduced perfusion and vascularization of the burn wound tissue. Analysis of CACs in the peripheral blood of the human patients, using a similar culture assay, confirmed results previously obtained by flow cytometry, that CAC levels peak early after the burn wound.

CONCLUSION

If CAC mobilization and wound perfusion are important determinants of clinical outcome, then strategies designed to augment angiogenic responses may improve outcome in patients with severe burn wounds.

摘要

目的

在动物模型中对循环血管生成细胞(CACs)动员现象进行系统探究。这种现象已在皮肤烧伤患者中观察到,可能是烧伤创面愈合过程中血管生成的重要机制。

设计

我们使用了一种可精确改变烧伤深度的小鼠模型,以及一种经过验证的用于定量循环CACs的培养方法。

地点

马里兰州巴尔的摩市迈克尔·D·亨德里克斯烧伤研究中心。

参与者

8周龄的雄性129S1/SvImJ小鼠,以及31名年龄在19至59岁之间、烧伤面积为体表面积1%至64%且有血流动力学稳定证据的烧伤患者。

主要观察指标

烧伤创面组织学特征,包括用CD31和α平滑肌肌动蛋白抗体进行血管免疫组织化学检测、用激光多普勒灌注成像测量血流,以及用经过验证的培养技术测量CACs向循环血液中的动员情况。

结果

烧伤深度增加导致循环CACs动员时间逐渐延迟,且CACs动员减少。这种延迟和CACs动员减少与烧伤创面组织灌注和血管化减少有关。使用类似培养试验对人类患者外周血中的CACs进行分析,证实了先前通过流式细胞术获得的结果,即烧伤创面后早期CAC水平达到峰值。

结论

如果CACs动员和创面灌注是临床结局的重要决定因素,那么旨在增强血管生成反应的策略可能会改善重度烧伤患者的结局。

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