Tactile information from the vibrissal system modulates hippocampal functioning

Nereida Ibarra-Castaneda , Norma A. Moy-Lopez , Oscar Gonzalez-Perez
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引用次数: 2

Abstract

Most mammals have sensory tactile hairs, also known as whiskers or vibrissae. Traditionally, whiskers are associated with diverse survival skills, including tactile discrimination, distance assessment, food acquisition, gap crossing, and social interaction. Vibrissae functions are processed in the somatosensorial cortex, commonly referred to as the barrel cortex. Hence, most of the whisker-related research has been focused on this cortical region. However, increasing evidence indicates that the vibrissal system modulates several aspects of hippocampal physiology. This graphical review aims to summarize cumulative evidence indicating that whiskers regulate the neural function and cellularity in several hippocampal subfields. Interestingly, lack of whiskers notably affects neuronal firing in CA1 and CA3 hippocampal subfields, alters spatial mapping, impairs navigational skills, modifies cytoarchitecture, and reduces the adult neurogenesis in the dentate gyrus. This evidence extends our understanding of how whiskers are related to hippocampal function and offers insights to explore novel associations between whisker functions and neural plasticity in the hippocampus.

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来自振动系统的触觉信息调节海马体的功能
大多数哺乳动物都有感觉触觉毛,也被称为胡须或触须。传统上,胡须与多种生存技能有关,包括触觉辨别、距离评估、食物获取、穿越缝隙和社会互动。触须的功能是在躯体感觉皮层中处理的,通常被称为桶状皮层。因此,大多数与须相关的研究都集中在这一皮层区域。然而,越来越多的证据表明,振动系统调节海马生理的几个方面。这篇图表综述旨在总结表明须调节海马体几个子区的神经功能和细胞结构的累积证据。有趣的是,缺乏须明显影响海马CA1和CA3亚区神经元放电,改变空间映射,损害导航技能,改变细胞结构,减少齿状回的成人神经发生。这一证据扩展了我们对须与海马体功能之间关系的理解,并为探索须功能与海马体神经可塑性之间的新联系提供了见解。
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