A Two-Hit Model of The Biological Origin of Posttraumatic Stress Disorder (PTSD)

Journal of mental health & clinical psychology Pub Date : 2018-09-01 DOI:10.29245/2578-2959/2018/5.1165

A. Georgopoulos, Lisa M. James, P. Christova, B. Engdahl

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引用次数: 4

Abstract

Posttraumatic stress disorder (PTSD) is a debilitating disorder that can develop following exposure to a traumatic event. Although the cause of PTSD is known, the brain mechanisms of its development remain unknown, especially why it arises in some people but not in others. Most of the research on PTSD has dealt with psychological and brain mechanisms underlying its symptomatology, including intrusive memories, fear and avoidance (see ref.1 for a broad coverage of PTSD research)1. Here we focus, instead, on the origin of PTSD, namely on the neural mechanisms underlying its development. Specifically, we propose a two-hit model for PTSD development, with the following components. (a) The 1st hit is a neuroimmune challenge, as a preexisting condition, and the 2nd hit is intense glutamatergic neurotransmission, induced by the traumatic event; (b) the key molecule that mediates the effects of these two hits is intercellular adhesion molecule 5 (ICAM-5) which was found to be differentially expressed in PTSD2. ICAM-5 is activated by neuroimmune challenge3,4 and glutamatergic neurotransmission5,6, it further enhances glutamatergic transmission6, and exerts a potent effect on synapse formation and neural plasticity, in addition to immunoregulatory functions3,4,7; and (c) with respect to the neural network(s) involved, the brain areas most involved are medial temporal cortical areas, and interconnected cortical and subcortical areas8–10. We hypothesize that the net result of intense glutamatergic transmission in those areas induced by a traumatic event in the presence of ongoing neuroimmune challenge leads to increased levels of ICAM-5 which further enhances glutamatergic transmission and thus leads to a state of a neural network with highly correlated neural interactions, as has been observed in functional neuroimaging studies8–10. We assume that such a “locked-in” network underlies the intrusive re-experiencing in PTSD and maintains associated symptomatology, such as fear and avoidance.

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创伤后应激障碍(PTSD)生物学起源的双重打击模型

创伤后应激障碍(PTSD)是一种使人衰弱的障碍，可能在经历创伤性事件后发展。虽然创伤后应激障碍的病因是已知的，但其发展的大脑机制仍然未知，特别是为什么它出现在一些人身上而不是在另一些人身上。大多数关于创伤后应激障碍的研究都涉及其症状背后的心理和大脑机制，包括侵入性记忆、恐惧和回避(见参考文献1，有关创伤后应激障碍研究的广泛报道)。在这里，我们关注的是创伤后应激障碍的起源，即其发展背后的神经机制。具体来说，我们提出了一个创伤后应激障碍发展的双重打击模型，包括以下组成部分。(a)第一个打击是神经免疫挑战，作为先前存在的疾病，第二个打击是创伤事件引起的强烈谷氨酸能神经传递;(二)介导这两种撞击作用的关键分子是细胞间粘附分子5 (ICAM-5)，该分子在PTSD2中被发现有差异表达。ICAM-5被神经免疫攻击3,4和谷氨酸能神经传递5,6激活，它进一步增强谷氨酸能传递6，并对突触形成和神经可塑性产生强有力的影响，除了免疫调节功能3,4,7;(c)就涉及的神经网络而言，最受影响的大脑区域是内侧颞叶皮层区域，以及相互连接的皮层和皮层下区域8 - 10。我们假设，正如功能性神经影像学研究中所观察到的那样，创伤事件在存在持续神经免疫挑战的情况下，在这些区域引起的强烈谷氨酸能传递的净结果导致ICAM-5水平增加，这进一步增强了谷氨酸能传递，从而导致神经网络处于高度相关的神经相互作用状态8 - 10。我们假设这样一个“封闭”的网络是创伤后应激障碍中侵入性再体验的基础，并维持相关的症状，如恐惧和回避。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of mental health & clinical psychology

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