Related papers: Musculoskeletal simulation of limb movement biomechanics in Drosophila melanogaster

Musculoskeletal simulation of limb movement biomechanics in Drosophila melanogaster

URL: http://arxiv.org/abs/2509.06426v2
Date: Thu, 11 Sep 2025 21:45:17 GMT
Title: Musculoskeletal simulation of limb movement biomechanics in Drosophila melanogaster
Authors: Pembe Gizem Özdil, Chuanfang Ning, Jasper S. Phelps, Sibo Wang-Chen, Guy Elisha, Alexander Blanke, Auke Ijspeert, Pavan Ramdya,
Abstract summary: We introduce the first 3D, data-driven musculoskeletal model of Drosophila legs.<n>Our model incorporates a Hill-type muscle representation based on high-resolution X-ray scans from multiple fixed specimens.<n>Our model enables the investigation of motor control in an experimentally tractable model organism.
Score: 32.89880065783502
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Computational models are critical to advance our understanding of how neural, biomechanical, and physical systems interact to orchestrate animal behaviors. Despite the availability of near-complete reconstructions of the Drosophila melanogaster central nervous system, musculature, and exoskeleton, anatomically and physically grounded models of fly leg muscles are still missing. These models provide an indispensable bridge between motor neuron activity and joint movements. Here, we introduce the first 3D, data-driven musculoskeletal model of Drosophila legs, implemented in both OpenSim and MuJoCo simulation environments. Our model incorporates a Hill-type muscle representation based on high-resolution X-ray scans from multiple fixed specimens. We present a pipeline for constructing muscle models using morphological imaging data and for optimizing unknown muscle parameters specific to the fly. We then combine our musculoskeletal models with detailed 3D pose estimation data from behaving flies to achieve muscle-actuated behavioral replay in OpenSim. Simulations of muscle activity across diverse walking and grooming behaviors predict coordinated muscle synergies that can be tested experimentally. Furthermore, by training imitation learning policies in MuJoCo, we test the effect of different passive joint properties on learning speed and find that damping and stiffness facilitate learning. Overall, our model enables the investigation of motor control in an experimentally tractable model organism, providing insights into how biomechanics contribute to generation of complex limb movements. Moreover, our model can be used to control embodied artificial agents to generate naturalistic and compliant locomotion in simulated environments.

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