CRCNS: An Integrated Locomotion Model for Lamprey Swimming

CRCNS：七鳃鳗游泳的综合运动模型

• 批准号: 7237159
• 负责人: AVIS H COHEN
• 金额: $ 27.38万
• 依托单位: UNIV OF MARYLAND, COLLEGE PARK
• 依托单位国家: 美国
• 财政年份: 2005
• 资助国家: 美国
• 起止时间: 2005-09-15 至 2010-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7237159
• 关键词: Acute; Animals; Automobile Driving; Behavior; Biological Models; Body Fluids; Cells; Complex; Computer Simulation; Condition; Consultations; Coupling; Data; Decompression Sickness; Elements; Encapsulated; Environment; Excision; Face; Feedback; Healed; Knowledge; Lampreys; Lesion; Life; Liquid substance; Locomotion; London; Maps; Measurement; Measures; Mechanics; Mechanoreceptors; Modeling; Motion; Motor; Movement; Muscle; Nerve; Neuromechanics; Organ; Organism; Output; Pattern; Performance; Peripheral; Phase; Physiological; Preparation; Protocols documentation; Range; Reaction; Research Personnel; Role; Running; Sensory; Simulate; Skin; Spinal; Spinal Cord; Swimming; System; Testing; Travel; Universities; Variant; Water; Work; analog; body mechanics; central pattern generator; data modeling; healing; kinematics; lateral line; lateral line (brain); mathematical model; neuroregulation; pressure; receptor; relating to nervous system; research study; response; sensory feedback; sensory system; spinal tract

DESCRIPTION (provided by applicant): Locomotion is the product of neural output acting on muscles driving a mechanically complex body in an unpredictable environment. The lamprey is a simple, well-studied and relatively tractable vertebrate model with which to probe this neuromechanical system. We hypothesize that steady locomotion in a predictable environment requires only the central pattern generator (CPG) without the necessity of other input. We also hypothesize that in an unpredictable environment sensory feedback combined with strong intersegmental coupling is necessary. To investigate these hypotheses we will develop an integrated model, of lamprey swimming LAMPREYCOMP with Thelma Williams, from London, and researchers Philip Holmes and Alexander Smits from Princeton University. The model spans CPG, sensory feedback, muscle mechanics, body mechanics, and fluid mechanics, and is a full model of a complex behavior in a vertebrate, albeit a simple one. Cohen and colleagues will perform experimental studies of the CPG and its response to sensory feedback from spinal mechanoreceptors, skin and lateral line and will develop the component of LAMPREYCOMP that maps sensory input to motor nerve output. Work on muscle and body mechanics will be done by Holmes and Williams. Smits and Holmes will study the fluid mechanics of the swimming animals both experimentally and theoretically. The experimental work will include developing a mechanical analog, P-RAY, whose motion will be adjusted to reproduce that of live animals, allowing measurements of fluid motion and pressure variations along the body. The theoretical work will include developing the fluid dynamical component of LAMPREYCOMP, in consultation with C. Peskin, L. Fauci and colleagues. LAMPREYCOMP will be tested to insure that it reproduces the behavior of whole animal swimming, various reduced preparations and P-RAY. It will then be used to investigate the effect of manipulations, such as removing sensory feedback from spinal mechanoreceptors that are not experimentally possible. We also show that all components of the protocol are possible. Because the lamprey is a model system for all of vertebrate locomotion, our hypotheses and models will have broad implications for more advanced organisms in which such a complete approach is not presently feasible.

描述（由申请人提供）：运动是作用于肌肉的神经输出的产物，在不可预测的环境中驱动机械复杂的身体。七鳃鳗是一种简单、经过充分研究且相对容易处理的脊椎动物模型，可以用来探测这种神经力学系统。我们假设在可预测环境中的稳定运动仅需要中央模式生成器（CPG），而不需要其他输入。我们还假设，在不可预测的环境中，感官反馈与强段间耦合相结合是必要的。为了研究这些假设，我们将与来自伦敦的 Thelma Williams 以及普林斯顿大学的研究人员 Philip Holmes 和 Alexander Smits 一起开发一个七鳃鳗游泳 LAMPREYCOMP 的综合模型。该模型涵盖 CPG、感觉反馈、肌肉力学、身体力学和流体力学，是脊椎动物复杂行为的完整模型，尽管行为很简单。 Cohen 及其同事将对 CPG 及其对来自脊髓机械感受器、皮肤和侧线的感觉反馈的反应进行实验研究，并将开发 LAMPREYCOMP 组件，将感觉输入映射到运动神经输出。肌肉和身体力学方面的工作将由霍姆斯和威廉姆斯完成。斯密茨和霍姆斯将从实验和理论上研究游泳动物的流体力学。实验工作将包括开发一种机械模拟装置 P-RAY，其运动将被调整以重现活体动物的运动，从而可以测量沿身体的流体运动和压力变化。理论工作将包括与 C. Peskin、L. Fauci 及其同事协商开发 LAMPREYCOMP 的流体动力学组件。 LAMPREYCOMP 将经过测试，以确保它能够重现整个动物游泳、各种简化准备和 P-RAY 的行为。然后它将用于研究操作的效果，例如消除实验上不可能的脊髓机械感受器的感觉反馈。我们还表明该协议的所有组成部分都是可能的。由于七鳃鳗是所有脊椎动物运动的模型系统，因此我们的假设和模型将对更先进的生物体产生广泛的影响，而在这些生物体中，这种完整的方法目前尚不可行。