The Metastability of the Double-Tripod Gait in Locust Locomotion

Overview

Journal iScience

Publisher Cell Press

Date 2019 Jan 25

PMID 30677739

Citations 5

Authors

Eran Reches

Daniel Knebel

Jan Rillich

Amir Ayali

Baruch Barzel

Affiliations

Soon will be listed here.

Abstract

Insect locomotion represents a fundamental example of neuronal oscillating circuits generating different motor patterns or gaits by controlling their phase coordination. Walking gaits are assumed to represent stable states of the system, often modeled as coupled oscillators. This view is challenged, however, by recent experimental observations, in which in vitro locust preparations consistently converged to synchronous rhythms (all legs oscillating as one), a locomotive pattern never seen in vivo. To reconcile this inconsistency, we developed a modeling framework to capture the trade-off between the two competing mechanisms: the endogenous neuronal circuitry, expressed in vitro, and the feedback mechanisms from sensory and descending inputs, active only in vivo. We show that the ubiquitously observed double-tripod walking gait emerges precisely from this balance. The outcome is a short-lived meta-stable double-tripod gait, which transitions and alternates with stable idling, thus recovering the observed intermittent bouts of locomotion, typical of many insects' locomotion behavior.

Citing Articles

From Motor-Output to Connectivity: An In-Depth Study of Rhythmic Patterns in the Cockroach .

David I, Ayali A Front Insect Sci. 2024; 1:655933.

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Aidan Y, Bleichman I, Ayali A Biol Lett. 2024; 20(2):20230468.

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Motorized Treadmill and Optical Recording System for Gait Analysis of Grasshoppers.

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Leg amputation modifies coordinated activation of the middle leg muscles in the cricket Gryllus bimaculatus.

Owaki D, Aonuma H, Sugimoto Y, Ishiguro A Sci Rep. 2021; 11(1):1327.

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Flexible Spiking CPGs for Online Manipulation During Hexapod Walking.

Strohmer B, Manoonpong P, Larsen L Front Neurorobot. 2020; 14:41.

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