Neuronal oscillations in cognition: Down syndrome as a model of mouse to human translation.

IF 3.5 3区 医学 Q1 CLINICAL NEUROLOGY Neuroscientist Pub Date : 2024-09-24 DOI:10.1177/10738584241271414
Pishan Chang, Marta Pérez-González, Jessica Constable, Daniel Bush, Karen Cleverley, Victor L J Tybulewicz, Elizabeth M C Fisher, Matthew C Walker
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Abstract

Down syndrome (DS), a prevalent cognitive disorder resulting from trisomy of human chromosome 21 (Hsa21), poses a significant global health concern. Affecting approximately 1 in 800 live births worldwide, DS is the leading genetic cause of intellectual disability and a major predisposing factor for early-onset Alzheimer's dementia. The estimated global population of individuals with DS is 6 million, with increasing prevalence due to advances in DS health care. Global efforts are dedicated to unraveling the mechanisms behind the varied clinical outcomes in DS. Recent studies on DS mouse models reveal disrupted neuronal circuits, providing insights into DS pathologies. Yet, translating these findings to humans faces challenges due to limited systematic electrophysiological analyses directly comparing human and mouse. Additionally, disparities in experimental procedures between the two species pose hurdles to successful translation. This review provides a concise overview of neuronal oscillations in human and rodent cognition. Focusing on recent DS mouse model studies, we highlight disruptions in associated brain function. We discuss various electrophysiological paradigms and suggest avenues for exploring molecular dysfunctions contributing to DS-related cognitive impairments. Deciphering neuronal oscillation intricacies holds promise for targeted therapies to alleviate cognitive disabilities in DS individuals.

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认知中的神经元振荡:唐氏综合征作为小鼠到人类的转化模型。
唐氏综合征(DS)是由人类 21 号染色体三体综合征(Hsa21)引起的一种普遍认知障碍,是一个重大的全球健康问题。全球每 800 名活产婴儿中约有 1 人患有唐氏综合征,它是导致智力残疾的主要遗传原因,也是早发性阿尔茨海默氏症痴呆症的主要诱发因素。据估计,全球有 600 万 DS 患者,由于 DS 医疗保健的进步,患病率正在不断上升。全球都在努力揭示 DS 不同临床结果背后的机制。最近对 DS 小鼠模型的研究揭示了神经元回路的紊乱,为了解 DS 的病理提供了线索。然而,由于直接比较人类和小鼠的系统电生理分析有限,将这些发现转化到人类面临挑战。此外,两个物种在实验程序上的差异也给成功转化带来了障碍。本综述简要概述了人类和啮齿类动物认知中的神经元振荡。我们以最近的 DS 小鼠模型研究为重点,强调了相关大脑功能的紊乱。我们讨论了各种电生理学范式,并提出了探索导致 DS 相关认知障碍的分子功能障碍的途径。破译神经元振荡的复杂性有望为缓解 DS 患者认知障碍的靶向疗法带来希望。
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来源期刊
Neuroscientist
Neuroscientist 医学-临床神经学
CiteScore
11.50
自引率
0.00%
发文量
68
期刊介绍: Edited by Stephen G. Waxman, The Neuroscientist (NRO) reviews and evaluates the noteworthy advances and key trends in molecular, cellular, developmental, behavioral systems, and cognitive neuroscience in a unique disease-relevant format. Aimed at basic neuroscientists, neurologists, neurosurgeons, and psychiatrists in research, academic, and clinical settings, The Neuroscientist reviews and updates the most important new and emerging basic and clinical neuroscience research.
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