利用新型工程旋转加速度闭合性脑损伤模型(CHIMERA)表征脑白头雪貂创伤性脑损伤模型

IF 1.8 Q3 CLINICAL NEUROLOGY Neurotrauma reports Pub Date : 2023-11-01 DOI:10.1089/neur.2023.0047
Justin L. Krieg, Anna V. Leonard, Renee J. Tuner, Frances Corrigan
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引用次数: 1

摘要

创伤性脑损伤(TBI)是由机械力作用于大脑引起的,并导致一系列生化反应,进一步损害神经元和支持细胞。临床上,大多数脑损伤是由于对完整颅骨的冲击造成的,这使得闭合性脑损伤临床前模型具有很高的相关性。然而,大多数闭式脑损伤模型使用的是无脑啮齿动物,它们可能不会以与脑回动物相同的方式传递生物力学载荷。为了解决这一翻译空白,本研究旨在表征雪貂(最小的脑回哺乳动物)的急性轴突损伤和小胶质细胞反应。雄性雪貂(Mustela furo;1.20 - -1.51公斤;6-9个月大的婴儿)使用新型的封闭头部损伤模型的工程旋转加速度(CHIMERA)模型。动物被随机分配到假手术组(n = 4)、22J(焦耳)撞击组(n = 4)和27J撞击组(n = 4)。用淀粉样蛋白前体蛋白(APP)、神经丝M (RMO 14.9) (RMO-14)和磷酸化tau (AT180)检测轴突损伤,并在损伤后24小时在灰质和白质区域用离子钙结合接头分子1观察小胶质细胞的反应。在22J脑损伤组中,APP和RMO-14免疫反应性轻度增加,主要发生在胼胝体和穹窿内,而在27J脑损伤组中,更广泛的弥漫性轴索损伤包括丘脑和下丘脑等灰质结构。伴随的小胶质细胞激活仅在27J组中观察到,最明显的是在白质束中对大量轴突损伤做出反应。27J组损伤后脑沟底部的AT180增加,而22J组则没有。这可能表明该菌株可能在该区域最高,表明脑回畸形与无脑畸形大脑的反应不同。雪貂CHIMERA模型能较好地模拟人类闭合性脑损伤的许多组织病理特征,为研究脑损伤的病理生理学提供了一种有前景的模型。
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Characterization of Traumatic Brain Injury in a Gyrencephalic Ferret Model Using the Novel Closed Head Injury Model of Engineered Rotational Acceleration (CHIMERA)
Traumatic brain injury (TBI) results from mechanical force to the brain and leads to a series of biochemical responses that further damage neurons and supporting cells. Clinically, most TBIs result from an impact to the intact skull, making closed head TBI pre-clinical models highly relevant. However, most of these closed head TBI models use lissencephalic rodents, which may not transduce biomechanical load in the same manner as gyrencephalic humans. To address this translational gap, this study aimed to characterize acute axonal injury and microglial responses in ferrets—the smallest gyrencephalic mammal. Injury was induced in male ferrets (Mustela furo; 1.20–1.51 kg; 6–9 months old) with the novel Closed Head Injury Model of Engineered Rotational Acceleration (CHIMERA) model. Animals were randomly allocated to either sham (n = 4), a 22J (joules) impact (n = 4), or a 27J impact (n = 4). Axonal injury was examined histologically with amyloid precursor protein (APP), neurofilament M (RMO 14.9) (RMO-14), and phosphorylated tau (AT180) and the microglial response with ionized calcium-binding adaptor molecule 1 at 24 h post-injury in gray and white matter regions. Graded axonal injury was observed with modest increases in APP and RMO-14 immunoreactivity in the 22J TBI group, mostly within the corpus callosum and fornix and more extensive diffuse axonal injury encompassing gray matter structures like the thalamus and hypothalamus in the 27J group. Accompanying microglial activation was only observed in the 27J group, most prominently within the white matter tracts in response to the larger amounts of axonal injury. The 27J, but not the 22J, group showed an increase in AT180 within the base of the sulci post-injury. This could suggest that the strain may be highest in this region, demonstrating the different responses in gyrencephalic compared to lissencephalic brains. The CHIMERA model in ferrets mimic many of the histopathological features of human closed head TBI acutely and provides a promising model to investigate the pathophysiology of TBI.
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