人类、猕猴和黑猩猩纹状皮质中微小柱的形态计量变异性。

Morphometric variability of minicolumns in the striate cortex of Homo sapiens, Macaca mulatta, and Pan troglodytes.

作者信息

Casanova Manuel F, Trippe Juan, Tillquist Christopher, Switala Andrew E

机构信息

Department of Psychiatry and Behavioral Sciences, University of Louisville, Kentucky 40292, USA.

出版信息

J Anat. 2009 Feb;214(2):226-34. doi: 10.1111/j.1469-7580.2008.01027.x.

DOI:10.1111/j.1469-7580.2008.01027.x

PMID:19207984

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2667880/

Abstract

Radially oriented ensembles of neurons and their projections, termed minicolumns, are hypothesized to be the basic microcircuit of mammalian cerebral cortex. Minicolumns can be divided into a core and a peripheral neuropil space compartment. The core of minicolumns is constrained by the migratory path of pyramidal cells and their attendant radially oriented projections. Variation in minicolumnar morphometry and density is observed both within and across species. Using a scale-independent measure of variability in minicolumnar width (V(CW)), we demonstrated a significant increase in V(CW) in layers III-V of striate cortex in humans relative to macaques and chimpanzees. Despite changes in minicolumnar width (CW) across species, their core space (w) remained the same. Given that cellular elements and processes within the peripheral neuropil space of minicolumns are derived from assorted sources, cross-species differences in VCW may result from genetic and epigenetic influences acting primarily on this compartment of the minicolumn.

摘要

呈放射状排列的神经元及其投射，即微柱，被认为是哺乳动物大脑皮层的基本微回路。微柱可分为一个核心和一个外周神经毡空间隔室。微柱的核心受锥体细胞及其伴随的放射状投射的迁移路径的限制。在物种内部和物种之间均观察到微柱形态测量和密度的变化。通过使用一种与尺度无关的微柱宽度变异性测量方法（V(CW)），我们证明，相对于猕猴和黑猩猩，人类纹状皮层III - V层的V(CW)显著增加。尽管不同物种间微柱宽度（CW）有所变化，但其核心空间（w）保持不变。鉴于微柱外周神经毡空间内的细胞成分和过程来自各种不同来源，VCW的跨物种差异可能主要是由基因和表观遗传影响作用于微柱的这个隔室所致。

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