Fiber Track Length Gradients in the Avian Sound Localization Circuit Require Conduction Velocity Gradients to Maintain Isochronicity.

IF 2.1 4区医学 Q3 NEUROSCIENCES

Journal of Comparative Neurology Pub Date : 2026-04-01 DOI:10.1002/cne.70162

David M Harris

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引用次数: 0

Abstract

The chicken brainstem sound localization neural network exhibits a case where fiber length varies continuously across the fiber arrays connecting n. magnocellularis and n. laminaris. Detailed morphometric measurements were taken to quantify these length gradients. For both ipsilateral and contralateral projections, the path lengths connecting the caudal low-frequency segments are longer than those at the rostral high-frequency end, with a linear path length gradient between them. The length and the length gradient of the contralateral projection increase from hatchling to 2-4 weeks. Synchronous transmission of information is achieved if there is a conduction velocity gradient across both the ipsilateral and contralateral fiber tracts. Adjustments of conduction velocity are required at both the cellular and population levels. A model is proposed that balances conduction distances and velocities by varying the number of nodes of Ranvier along a gradient to achieve isochronicity across the entire network. Continued differential growth between fiber arrays requires a continuous timing adjustment during development and maturation. Control is assigned to the oligodendrocytes that produce and maintain myelin.

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鸟类声音定位电路中的光纤轨迹长度梯度需要传导速度梯度来维持等时性。

鸡脑干声音定位神经网络显示，在连接大细胞棘球蚴和层状棘球蚴的纤维阵列中，纤维长度连续变化。采用详细的形态测量来量化这些长度梯度。对于同侧和对侧投影，连接尾侧低频段的路径长度比连接吻侧高频端的路径长度长，两者之间存在线性路径长度梯度。对侧投影的长度和长度梯度从孵化到2-4周逐渐增加。如果在同侧和对侧纤维束之间存在传导速度梯度，则实现信息的同步传输。在细胞和群体水平上都需要调节传导速度。提出了一种平衡传导距离和传导速度的模型，该模型通过改变Ranvier节点沿梯度的数量来实现整个网络的等时性。光纤阵列之间的持续差异增长需要在发展和成熟过程中不断调整时间。控制被分配给产生和维持髓磷脂的少突细胞。

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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来源期刊

Journal of Comparative Neurology 医学-动物学

CiteScore

5.80

自引率

8.00%

发文量

158

审稿时长

3-6 weeks

期刊介绍： Established in 1891, JCN is the oldest continually published basic neuroscience journal. Historically, as the name suggests, the journal focused on a comparison among species to uncover the intricacies of how the brain functions. In modern times, this research is called systems neuroscience where animal models are used to mimic core cognitive processes with the ultimate goal of understanding neural circuits and connections that give rise to behavioral patterns and different neural states. Research published in JCN covers all species from invertebrates to humans, and the reports inform the readers about the function and organization of nervous systems in species with an emphasis on the way that species adaptations inform about the function or organization of the nervous systems, rather than on their evolution per se. JCN publishes primary research articles and critical commentaries and review-type articles offering expert insight in to cutting edge research in the field of systems neuroscience; a complete list of contribution types is given in the Author Guidelines. For primary research contributions, only full-length investigative reports are desired; the journal does not accept short communications.