The self-oscillation paradox in the flight motor of<i>Drosophila melanogaster</i>

Pons, Arion

doi:10.1098/rsif.2023.0421

J. R. Soc. Interface.

2023

DOI: 10.1098/rsif.2023.0421

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The self-oscillation paradox in the flight motor ofDrosophila melanogaster

Arion Pons

Abstract: Tiny flying insects, such as Drosophila melanogaster , fly by flapping their wings at frequencies faster than their brains are able to process. To do so, they rely on self-oscillation: dynamic instability, leading to emergent oscillation, arising from muscle stretch-activation. Many questions concerning this vital natural instability remain open. Does flight motor self-oscillation necessarily lead to resonance—a state optimal in efficiency and/or performance? If so, what state? And is s… Show more

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Cited by 3 publications

References 75 publications

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The evolution of flight in an early winged insect ancestral lineage is recognized as a key adaptation explaining the unparalleled success and diversification of insects. Subsequent transitions and modifications to flight machinery, including secondary reductions and losses, also play a central role in shaping the impacts of insects on broadscale geographic and ecological processes and patterns in the present and future. Given the importance of insect flight, there has been a centuries-long history of research and debate on the evolutionary origins and biological mechanisms of flight. Here, we revisit this history from an interdisciplinary perspective, discussing recent discoveries regarding the developmental origins, physiology, biomechanics, and neurobiology and sensory control of flight in a diverse set of insect models. We also identify major outstanding questions yet to be addressed and provide recommendations for overcoming current methodological challenges faced when studying insect flight, which will allow the field to continue to move forward in new and exciting directions. By integrating mechanistic work into ecological and evolutionary contexts, we hope that this synthesis promotes and stimulates new interdisciplinary research efforts necessary to close the many existing gaps about the causes and consequences of insect flight evolution.

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The self-oscillation paradox in the flight motor ofDrosophila melanogaster

Pons

2023

J. R. Soc. Interface.

Self Cite

View full text Add to dashboard Cite

Tiny flying insects, such as Drosophila melanogaster , fly by flapping their wings at frequencies faster than their brains are able to process. To do so, they rely on self-oscillation: dynamic instability, leading to emergent oscillation, arising from muscle stretch-activation. Many questions concerning this vital natural instability remain open. Does flight motor self-oscillation necessarily lead to resonance—a state optimal in efficiency and/or performance? If so, what state? And is self-oscillation even guaranteed in a motor driven by stretch-activated muscle, or are there limiting conditions? In this work, we use data-driven models of wingbeat and muscle behaviour to answer these questions. Developing and leveraging novel analysis techniques, including symbolic computation, we establish a fundamental condition for motor self-oscillation common to a wide range of motor models. Remarkably, D. melanogaster flight apparently defies this condition: a paradox of motor operation. We explore potential resolutions to this paradox, and, within its confines, establish that the D. melanogaster flight motor is probably not resonant with respect to exoskeletal elasticity: instead, the muscular elasticity plays a dominant role. Contrary to common supposition, the stiffness of stretch-activated muscle is an obstacle to, rather than an enabler of, the operation of the D. melanogaster flight motor.

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The self-oscillation paradox in the flight motor ofDrosophila melanogaster

Cited by 3 publications

References 75 publications

Distribution-Theoretic Basis for Hidden Deltas in Frequency-Domain Structural Modeling

Distribution-Theoretic Basis for Hidden Deltas in Frequency-Domain Structural Modeling

Insect Flight: State of the Field and Future Directions

The self-oscillation paradox in the flight motor ofDrosophila melanogaster

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