Beyond locomotion: how specialized motor patterns enable a vertebrate to struggle free from capture

Saeed Farjami; Andrey Palyanov; Hong-Yan Zhang; Valentina Saccomanno; Robert Merrison-Hort; Andrea Ferrario; Roman Borisyuk; Joel Tabak; Wen-Chang Li

doi:10.1101/2025.09.08.674955

Beyond locomotion: how specialized motor patterns enable a vertebrate to struggle free from capture

Saeed Farjami, Andrey Palyanov, Hong-Yan Zhang, Valentina Saccomanno, Robert Merrison-Hort, Andrea Ferrario, Roman Borisyuk, Joel Tabak^*, Wen-Chang Li^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Animals captured by predators can still survive the attack by struggling to release themselves. We investigated how Xenopus tadpoles use struggling movements to free themselves from head restraint. High-speed video tracking revealed a stereotyped sequence of body flexions with distinct kinematics during capture and release. We further recorded motoneuron activities along the body axis during fictive struggling to reconstruct biologically realistic spatio-temporal motoneuronal firing patterns, to drive the movement of a 3D biomechanically detailed tadpole model. Simulations showed that struggling - characterized by long-duration, low-frequency, caudorostral muscle activation - was optimized to generate freeing forces. Notably, hydrodynamic thrust alone proved insufficient for release. However, direct mechanical interactions between the tadpole’s body and the restraining object generated additional reactive forces that facilitated escape. These findings demonstrate how animals use coordinated motor outputs and body mechanics to interact with the gripping object to generate maximal freeing forces as the fundamental survival strategy.

Original language	English
Article number	114068
Journal	iScience
Volume	28
Issue number	12
Early online date	19 Dec 2025
DOIs	https://doi.org/10.1101/2025.09.08.674955 https://doi.org/10.1016/j.isci.2025.114068
Publication status	E-pub ahead of print - 19 Dec 2025

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Farjami_2025_iSci_Beyond-locomotion_CC
Copyright © 2025 The Author(s). Published by Elsevier Inc. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).
Final published version, 8.49 MBLicence: CC BY

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Farjami, S., Palyanov, A., Zhang, H.-Y., Saccomanno, V., Merrison-Hort, R., Ferrario, A., Borisyuk, R., Tabak, J., & Li, W.-C. (2025). Beyond locomotion: how specialized motor patterns enable a vertebrate to struggle free from capture. iScience, 28(12), Article 114068. Advance online publication. https://doi.org/10.1101/2025.09.08.674955, https://doi.org/10.1016/j.isci.2025.114068

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abstract = "Animals captured by predators can still survive the attack by struggling to release themselves. We investigated how Xenopus tadpoles use struggling movements to free themselves from head restraint. High-speed video tracking revealed a stereotyped sequence of body flexions with distinct kinematics during capture and release. We further recorded motoneuron activities along the body axis during fictive struggling to reconstruct biologically realistic spatio-temporal motoneuronal firing patterns, to drive the movement of a 3D biomechanically detailed tadpole model. Simulations showed that struggling - characterized by long-duration, low-frequency, caudorostral muscle activation - was optimized to generate freeing forces. Notably, hydrodynamic thrust alone proved insufficient for release. However, direct mechanical interactions between the tadpole{\textquoteright}s body and the restraining object generated additional reactive forces that facilitated escape. These findings demonstrate how animals use coordinated motor outputs and body mechanics to interact with the gripping object to generate maximal freeing forces as the fundamental survival strategy.",

author = "Saeed Farjami and Andrey Palyanov and Hong-Yan Zhang and Valentina Saccomanno and Robert Merrison-Hort and Andrea Ferrario and Roman Borisyuk and Joel Tabak and Wen-Chang Li",

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AU - Merrison-Hort, Robert

AU - Ferrario, Andrea

AU - Borisyuk, Roman

AU - Tabak, Joel

AU - Li, Wen-Chang

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N2 - Animals captured by predators can still survive the attack by struggling to release themselves. We investigated how Xenopus tadpoles use struggling movements to free themselves from head restraint. High-speed video tracking revealed a stereotyped sequence of body flexions with distinct kinematics during capture and release. We further recorded motoneuron activities along the body axis during fictive struggling to reconstruct biologically realistic spatio-temporal motoneuronal firing patterns, to drive the movement of a 3D biomechanically detailed tadpole model. Simulations showed that struggling - characterized by long-duration, low-frequency, caudorostral muscle activation - was optimized to generate freeing forces. Notably, hydrodynamic thrust alone proved insufficient for release. However, direct mechanical interactions between the tadpole’s body and the restraining object generated additional reactive forces that facilitated escape. These findings demonstrate how animals use coordinated motor outputs and body mechanics to interact with the gripping object to generate maximal freeing forces as the fundamental survival strategy.

AB - Animals captured by predators can still survive the attack by struggling to release themselves. We investigated how Xenopus tadpoles use struggling movements to free themselves from head restraint. High-speed video tracking revealed a stereotyped sequence of body flexions with distinct kinematics during capture and release. We further recorded motoneuron activities along the body axis during fictive struggling to reconstruct biologically realistic spatio-temporal motoneuronal firing patterns, to drive the movement of a 3D biomechanically detailed tadpole model. Simulations showed that struggling - characterized by long-duration, low-frequency, caudorostral muscle activation - was optimized to generate freeing forces. Notably, hydrodynamic thrust alone proved insufficient for release. However, direct mechanical interactions between the tadpole’s body and the restraining object generated additional reactive forces that facilitated escape. These findings demonstrate how animals use coordinated motor outputs and body mechanics to interact with the gripping object to generate maximal freeing forces as the fundamental survival strategy.

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Beyond locomotion: how specialized motor patterns enable a vertebrate to struggle free from capture

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