Sensorimotor control of swimming Polypterus senegalus is preserved during sensory deprivation conditions across altered environments

Hainer Jeffrey; Lutek Keegan; Maki HaileyStanden Emily M.

首页> 外文期刊>The Journal of Experimental Biology >Sensorimotor control of swimming Polypterus senegalus is preserved during sensory deprivation conditions across altered environments

【24h】

Sensorimotor control of swimming Polypterus senegalus is preserved during sensory deprivation conditions across altered environments

机译：Sensorimotor control of swimming Polypterus senegalus is preserved during sensory deprivation conditions across altered environments

获取原文

获取原文并翻译 | 示例

掌桥外文数据库（机构版） >>

开具论文收录证明 >>

文献代查 >>

页面导航

摘要
著录项
相关主题

摘要

Control of locomotion involves the interplay of sensory signals and motor commands. Sensory information is essential for adjusting locomotion in response to environmental changes. A previous study using mathematical modelling of lamprey swimming has shown that, in the absence of sensory feedback, increasing fluid viscosity constrains swimming kinematics, limiting tail amplitude and body wavelength, resulting in decreased swimming speed. In contrast, previous experiments with Polypterus senegalus reported increased magnitude swimming kinematics (increased body curvature, body wave speed and frequency, and pectoral fin frequency) in high viscosity water suggesting that sensory information is used to adjust swimming form. It is not known what sensory systems are providing the necessary information to respond to these environmental changes. We tested the hypothesis that lateral line and visual input are responsible for the sensory-driven increase in swimming kinematics in response to experimentally increased fluid viscosity. The kinematics of five P. senegalus were recorded in two different viscosities of water while removing lateral line and visual sensory feedback. Unlike the mathematical model devoid of sensory feedback, P. senegalus with lateral line and/or visual senses removed did not reduce the magnitude of swimming kinematic variables, suggesting that additional sensory feedback mechanisms are present in these fish to help overcome increased fluid viscosity. Increases in swimming speed when both lateral line and visual sensory feedback were removed suggest that lateral line and visual information may be used to regulate swimming speed in P. senegalus, possibly using an internal model of predictions to adjust swimming form.

著录项

来源
《The Journal of Experimental Biology》 |2023年第9期|共9页
作者
Hainer Jeffrey; Lutek Keegan; Maki HaileyStanden Emily M.;
展开▼
作者单位

Univ Ottawa;

Villanova Univ;

展开▼
收录信息
原文格式 PDF
正文语种英语
中图分类生物学实验与生物学技术;
关键词
Fish; Lateral line; Vision; Viscosity; Sensorimotor; Locomotion; Polypterus; LATERAL-LINE; BEHAVIOR; VISCOSITY; LAMPREY; PERSPECTIVE; KINEMATICS; STIFFNESS; PATTERN; TROUT;

Sensorimotor control of swimming Polypterus senegalus is preserved during sensory deprivation conditions across altered environments

摘要

著录项

相关主题

期刊订阅