Sensory feedback and central neuronal interactions in mouse locomotion.

IF 2.9 3区 综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES
Royal Society Open Science Pub Date : 2024-08-21 eCollection Date: 2024-08-01 DOI:10.1098/rsos.240207
Yaroslav I Molkov, Guoning Yu, Jessica Ausborn, Julien Bouvier, Simon M Danner, Ilya A Rybak
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引用次数: 0

Abstract

Locomotion is a complex process involving specific interactions between the central neural controller and the mechanical components of the system. The basic rhythmic activity generated by locomotor circuits in the spinal cord defines rhythmic limb movements and their central coordination. The operation of these circuits is modulated by sensory feedback from the limbs providing information about the state of the limbs and the body. However, the specific role and contribution of central interactions and sensory feedback in the control of locomotor gait and posture remain poorly understood. We use biomechanical data on quadrupedal locomotion in mice and recent findings on the organization of neural interactions within the spinal locomotor circuitry to create and analyse a tractable mathematical model of mouse locomotion. The model includes a simplified mechanical model of the mouse body with four limbs and a central controller composed of four rhythm generators, each operating as a state machine controlling the state of one limb. Feedback signals characterize the load and extension of each limb as well as postural stability (balance). We systematically investigate and compare several model versions and compare their behaviour to existing experimental data on mouse locomotion. Our results highlight the specific roles of sensory feedback and some central propriospinal interactions between circuits controlling fore and hind limbs for speed-dependent gait expression. Our models suggest that postural imbalance feedback may be critically involved in the control of swing-to-stance transitions in each limb and the stabilization of walking direction.

小鼠运动中的感觉反馈和中枢神经元相互作用
运动是一个复杂的过程,涉及中枢神经控制器与系统机械部件之间的特定互动。脊髓运动回路产生的基本节律活动决定了有节律的肢体运动及其中枢协调。来自肢体的感觉反馈提供了有关肢体和身体状态的信息,从而调节了这些回路的运行。然而,人们对中枢互动和感觉反馈在控制运动步态和姿势中的具体作用和贡献仍然知之甚少。我们利用小鼠四足运动的生物力学数据和脊柱运动回路内神经交互组织的最新研究成果,创建并分析了小鼠运动的可控数学模型。该模型包括一个简化的小鼠四肢机械模型和一个由四个节奏发生器组成的中央控制器,每个节奏发生器作为一个状态机控制一个肢体的状态。反馈信号描述了每个肢体的负荷和伸展以及姿势稳定性(平衡)。我们系统地研究和比较了几个模型版本,并将它们的行为与现有的小鼠运动实验数据进行了比较。我们的研究结果凸显了感觉反馈以及控制前肢和后肢的回路之间的一些中枢本体神经相互作用在速度依赖性步态表达中的特殊作用。我们的模型表明,姿势不平衡反馈可能在控制每个肢体从摆动到站立的转换以及稳定行走方向方面起着关键作用。
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
Royal Society Open Science
Royal Society Open Science Multidisciplinary-Multidisciplinary
CiteScore
6.00
自引率
0.00%
发文量
508
审稿时长
14 weeks
期刊介绍: Royal Society Open Science is a new open journal publishing high-quality original research across the entire range of science on the basis of objective peer-review. The journal covers the entire range of science and mathematics and will allow the Society to publish all the high-quality work it receives without the usual restrictions on scope, length or impact.
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