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未成熟大鼠控制性皮质撞击损伤的两个年龄损伤实验模型的莫里斯水迷宫功能和组织学特征

Morris water maze function and histologic characterization of two age-at-injury experimental models of controlled cortical impact in the immature rat.

作者信息

Adelson P David, Fellows-Mayle Wendy, Kochanek Patrick M, Dixon C Edward

机构信息

Barrow Neurological Institute at Phoenix Children's Hospital, 1919 East Thomas Road, Building B, 4th Floor, Phoenix, AZ 85016, USA.

出版信息

Childs Nerv Syst. 2013 Jan;29(1):43-53. doi: 10.1007/s00381-012-1932-4. Epub 2012 Oct 23.

DOI:10.1007/s00381-012-1932-4
PMID:23089934
Abstract

PURPOSE

Controlled cortical impact (CCI) is commonly used in adult animals to study focal traumatic brain injury (TBI). Our study aims to further study injury mechanisms in children and variable models of pathology in the developing brain.

METHODS

Develop a focal injury model of experimental TBI in the immature, postnatal days (PND) 7 and 17 rats that underwent a CCI at varying depths of deflection, 1.5-2.5 mm compared with sham and then tested using the Morris water maze (MWM) beginning on post-injury day (PID) 11. Histopathologic analysis was performed at PID 1 and 28.

RESULTS

In PND 7, the 1.75- and 2.0-mm deflections (diameter (d) = 3 mm; velocity = 4 m/s; and duration = 500 ms) resulted in significant MWM deficits while the 1.5-mm injury did not produce MWM deficits vs. sham controls. In PND 17, all injury levels resulted in significant MWM deficits vs. sham controls with a graded response; the 1.5-mm deflection (d = 6 mm; velocity = 4 m/s; and duration = 500 ms) produced significantly less deficits as compared WITH the 2.0- and 2.5-mm injuries. Histologically, a graded injury response was also seen in both ages at injury with cortical and more severe injuries, hippocampal damage. Cortical contusion volume increased in most injury severities from PID 1 to 28 in both ages at injury while hippocampal volumes subsequently decreased.

CONCLUSIONS

CCI in PND 7 and 17 rat results in significant MWM deficits and cortical histopathology providing two different and unique experimental models of TBI in immature rats that may be useful in further investigations into the mechanisms and treatments of pediatric TBI.

摘要

目的

控制性皮质撞击(CCI)常用于成年动物以研究局灶性创伤性脑损伤(TBI)。我们的研究旨在进一步研究儿童脑损伤机制以及发育中大脑不同的病理模型。

方法

在出生后第7天和第17天的未成熟大鼠中建立实验性TBI局灶性损伤模型,这些大鼠接受不同偏转深度(1.5 - 2.5毫米)的CCI,与假手术组对比,然后从损伤后第11天开始使用莫里斯水迷宫(MWM)进行测试。在损伤后第1天和第28天进行组织病理学分析。

结果

在出生后第7天,1.75毫米和2.0毫米的偏转(直径(d)= 3毫米;速度 = 4米/秒;持续时间 = 500毫秒)导致显著的MWM缺陷,而1.5毫米损伤与假手术对照组相比未产生MWM缺陷。在出生后第17天,与假手术对照组相比,所有损伤水平均导致显著的MWM缺陷且呈分级反应;与2.0毫米和2.5毫米损伤相比,1.5毫米偏转(d = 6毫米;速度 = 4米/秒;持续时间 = 500毫秒)产生的缺陷明显更少。组织学上,在两个年龄段损伤时均观察到分级损伤反应,包括皮质损伤以及更严重的损伤、海马损伤。在两个年龄段损伤时,从损伤后第1天到第28天,大多数损伤严重程度下皮质挫伤体积增加,而海马体积随后减小。

结论

出生后第7天和第17天大鼠的CCI导致显著的MWM缺陷和皮质组织病理学改变,为未成熟大鼠提供了两种不同且独特的TBI实验模型,可能有助于进一步研究小儿TBI的机制和治疗方法。

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