人类的哪些神经发育过程在出生后仍在继续?

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-09-06 DOI:10.3389/fnins.2024.1434508
Shawn Fletcher Sorrells
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引用次数: 0

摘要

人一出生,大脑大部分区域神经细胞的数量和位置就会保持不变。因此,这些类型的结构变化对于发生这些变化的神经回路来说是一种重要的灵活性。在人类,神经元在出生后的迁移是有限的;但是,神经元会在整个婴儿期甚至青春期继续迁移到某些脑区。在人类婴儿期,多条迁移路径将中间神经元输送到额叶和颞叶皮层的各个目的地。兴奋性神经元的短程迁移似乎在青春期也在继续,尤其是在杏仁核旁核附近,该区域从婴儿期到成年期的生长轨迹是延迟的。不同脑区通过这些方法招募新神经元的时间意义尚不清楚;不过,在人类中,长期迁移和成熟这两个过程都很突出。类似这些重新配置神经元回路的机制是可塑性关键时期的基质,可能有助于人类大脑中独特的回路功能。
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Which neurodevelopmental processes continue in humans after birth?
Once we are born, the number and location of nerve cells in most parts of the brain remain unchanged. These types of structural changes are therefore a significant form of flexibility for the neural circuits where they occur. In humans, the postnatal birth of neurons is limited; however, neurons do continue to migrate into some brain regions throughout infancy and even into adolescence. In human infants, multiple migratory pathways deliver interneurons to destinations across the frontal and temporal lobe cortex. Shorter-range migration of excitatory neurons also appears to continue during adolescence, particularly near the amygdala paralaminar nucleus, a region that follows a delayed trajectory of growth from infancy to adulthood. The significance of the timing for when different brain regions recruit new neurons through these methods is unknown; however, both processes of protracted migration and maturation are prominent in humans. Mechanisms like these that reconfigure neuronal circuits are a substrate for critical periods of plasticity and could contribute to distinctive circuit functionality in human brains.
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CiteScore
7.20
自引率
4.30%
发文量
567
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