绵羊闭合性颅脑损伤模型模拟人类高速闭合性颅脑损伤。

Central European Neurosurgery Pub Date : 2011-08-01 Epub Date: 2011-07-07 DOI:10.1055/s-0031-1271732
A-C Grimmelt, S Eitzen, I Balakhadze, B Fischer, J Wölfer, H Schiffbauer, A Gorji, C Greiner
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引用次数: 13

摘要

迄今为止,只有少数无证据基础的脑保护治疗策略用于治疗和预防严重闭合性头部创伤后的继发性脑损伤。为了开发新的治疗策略,需要改进现有的现实动物模型。目标是建立标准化小动物模型和实际病人医疗护理之间的桥梁,因为实验性小动物研究的结果往往不能转移到脑损伤的人身上。为了提高高速创伤的规范化程度,研制了一种新的绵羊闭合性颅脑损伤启动装置。测试了以下新设备:一种解剖形状的橡胶螺栓,集成振荡吸收器,用于预防颅骨骨折;2. 螺栓固定安装,保证实验条件稳定;3.不同程度的创伤严重程度,例如:轻、重度闭合性颅脑损伤,使用不同的枪弹;和4。通过高速录像进行创伤分析。术中测量颅内压、脑组织pH值、脑组织氧、二氧化碳压以及神经递质浓度。脑损伤用磁共振成像记录,并与神经病理结果进行比较。由于使用了新的创伤装置,避免了颅骨骨折。高速录像记录了车祸的真实创伤机制。细胞外谷氨酸、天冬氨酸和γ氨基丁酸浓度在创伤后60分钟开始增强。磁共振成像和神经病理学结果显示轻度、重度闭合性颅脑损伤的特征性损伤模式。重型闭合性颅脑损伤组表现为弥漫性轴索损伤、外伤性蛛网膜下腔出血、出血性挫伤,但分布不一致。本文提出的模型通过增加对现实的逼近,实现了重型闭合性创伤性脑损伤的标准化。仍然存在的脑病理异质性模拟了高能创伤后患者观察到的脑变化。这个模型似乎缩小了实验小动物模型和临床研究之间的差距。然而,需要进一步的研究来评估该模型是否可以用于测试这些患者的新治疗策略。
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Closed traumatic brain injury model in sheep mimicking high-velocity, closed head trauma in humans.

To date, there are only a few, non-evidence based, cerebroprotective therapeutic strategies for treatment and, accordingly, for prevention of secondary brain injuries following severe closed head trauma. In order to develop new therapy strategies, existing realistic animal models need to be advanced. The objective is to bridge standardized small animal models and actual patient medical care, since the results of experimental small animal studies often cannot be transferred to brain-injured humans. For improved standardization of high-velocity trauma, new trauma devices for initiating closed traumatic brain injury in sheep were developed. The following new devices were tested: 1. An anatomically shaped rubber bolt with an integrated oscillation absorber for prevention of skull fractures; 2. Stationary mounting of the bolt to guarantee stable experimental conditions; 3. Varying degrees of trauma severity, i. e., mild and severe closed traumatic brain injury, using different cartridges; and 4. Trauma analysis via high-speed video recording. Peritraumatic measurements of intracranial pressure, brain tissue pH, brain tissue oxygen, and carbon dioxide pressure, as well as neurotransmitter concentrations were performed. Cerebral injuries were documented with magnetic resonance imaging and compared to neuropathological results. Due to the new trauma devices, skull fractures were prevented. The high-speed video recording documented a realistic trauma mechanism for a car accident. Enhancement of extracellular glutamate, aspartate, and gamma amino butyric acid concentrations began 60 min after the trauma. Magnetic resonance imaging and neuropathological results showed characteristic injury patterns of mild, and severe, closed traumatic brain injury. The severe, closed traumatic brain injury group showed diffuse axonal injuries, traumatic subarachnoid hemorrhage, and hemorrhagic contusions with inconsistent distribution among the animals. The model presented here achieves a gain in standardization of severe, closed traumatic brain injury by increasing approximation to reality. The still existent heterogeneity of brain pathology mimics brain changes observed in patients after high-energy trauma. This model seems to close the gap between experimental small animal models and clinical studies. However, further investigations are needed to evaluate if this model can be used for testing new therapeutic strategies for these patients.

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Central European Neurosurgery
Central European Neurosurgery CLINICAL NEUROLOGY-NEUROSCIENCES
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