Limit-cycle-based control of the myogenic wingbeat rhythm in the fruit fly<i>Drosophila</i>

Bartussek, Jan; Mutlu, A. Kadir; Zapotocky, Martin; Fry, Steven N.

doi:10.1098/rsif.2012.1013

Cited by 18 publications

(37 citation statements)

References 55 publications

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“…The complexity of this feedback control loop, including all its facets, is still under investigation and understanding the integration process of signals coming from the compound eyes, ocelli, antennae, campaniform sensilla on wings and body, and the gyroscopic halteres remains a challenge. Thus, there is a continuing debate on which sensory feedback is needed for flight and how sensory information, for example, from halteres and eyes are temporally encoded to provide the desired precision for body posture, flight course control, and equilibrium reflexes (Sherman and Dickinson 2003, 2004; Frye and Dickinson Michael 2004; Bender and Dickinson 2006a; Huston and Krapp 2009; Frye 2010; Bartussek et al 2013; Bartussek and Lehmann 2016). A fairly comprehensive review on sensory control of insect flight was previously published by Taylor and Krapp (2007).…”

Section: Timing Of Flight Control Muscle Activation By Proprioceptivementioning

confidence: 99%

Neural control and precision of flight muscle activation in Drosophila

Lehmann

Bartussek

2016

J Comp Physiol A

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Precision of motor commands is highly relevant in a large context of various locomotor behaviors, including stabilization of body posture, heading control and directed escape responses. While posture stability and heading control in walking and swimming animals benefit from high friction via ground reaction forces and elevated viscosity of water, respectively, flying animals have to cope with comparatively little aerodynamic friction on body and wings. Although low frictional damping in flight is the key to the extraordinary aerial performance and agility of flying birds, bats and insects, it challenges these animals with extraordinary demands on sensory integration and motor precision. Our review focuses on the dynamic precision with which Drosophila activates its flight muscular system during maneuvering flight, considering relevant studies on neural and muscular mechanisms of thoracic propulsion. In particular, we tackle the precision with which flies adjust power output of asynchronous power muscles and synchronous flight control muscles by monitoring muscle calcium and spike timing within the stroke cycle. A substantial proportion of the review is engaged in the significance of visual and proprioceptive feedback loops for wing motion control including sensory integration at the cellular level. We highlight that sensory feedback is the basis for precise heading control and body stability in flies.

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Section: Timing Of Flight Control Muscle Activation By Proprioceptivementioning

confidence: 99%

Neural control and precision of flight muscle activation in Drosophila

Lehmann

Bartussek

2016

J Comp Physiol A

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“…1(a) and (b)). Halteres provide proprioceptive feedback by detecting Coriolis forces and play a crucial role in the neuromuscular circuit generating the wingbeat rhythm in Dipterans (Bartussek et al, 2013;Bender and Dickinson, 2006). By activating the motor neurons of minuscule steering muscles, halteres help regulate wing motion through a reflexive feedback loop with these muscles.…”

Section: Introductionmentioning

confidence: 99%

Fog and dense gas disrupt mosquito flight due to increased aerodynamic drag on halteres

Dickerson

Shankles

Berry

et al. 2015

Journal of Fluids and Structures

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a b s t r a c tChemical insecticide foggers have long been used to control mosquito populations and reduce the spread of malaria, West Nile virus, and dengue fever. In this study, we show that simple fogs of water droplets, devoid of chemicals, are effective at obstructing the flight of Anopheles freeborni mosquitoes. Using high-speed video, we film the flight of mosquitoes in denser-than-air fluids such as fogs produced by household humidifiers and heavy gas. In gases with more than twice the density of air, mosquitoes cannot maintain flight stability, but pitch and roll uncontrollably until they fall to the ground. We here show that the increased drag of denser-than-air flight environments is sufficient to render a mosquito's gyroscopic sensors and wingbeat controllers, their halteres, ineffective. Anomalous drag forces are estimated with steady and unsteady drag analyses. We glue masses of 10 ng to each haltere, equivalent to 0.0005% the mass of the mosquito. Mosquitoes with such a minor treatment executed flight patterns, similar to mosquitoes in fog, indicating a mosquito's haltere are highly tuned to aerodynamic properties of normal air, making them sensitive to contaminants. The failure of mosquito flight in fog reveals potential new methods for mosquito control that do not require insecticide-laced particles.

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“…Other indirect steering muscles act by modifying the deformation of the thorax. Besides the obvious function of the direct steering muscles in changing the trajectory of the wing tip, or altering the amplitude and phase of the wing's pitching rotation and torsional deformation, indirect steering muscle activity may be important in controlling the frequency of the limit cycle oscillations of the stretchactivated power muscles [4]. In summary, the power muscles can be thought of as driving a limit cycle oscillation of the wing; the form and frequency of which is controlled by the steering muscles [6], [4].…”

Section: Introductionmentioning

confidence: 99%

Motor output and control input in flapping flight: a compact model of the deforming wing kinematics of manoeuvring hoverflies

Nagesh

Walker

Taylor

2019

Preprint

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Insects are conventionally modelled as controlling flight by varying a few summary kinematic parameters that are defined on a per-wingbeat basis, such as the stroke amplitude, mean stroke angle, and mean wing pitch angle. Nevertheless, as insects have tens of flight muscles and vary their kinematics continuously, the true dimension of their control input subspace is likely to be much higher. Here we present a compact description of the deforming wing kinematics of 36 manoeuvring Eristalis hoverflies, applying functional principal components analysis to Fourier series fits of the wingtip position and wing twist measured over 26,541 wingbeats. This analysis offers a high degree of data reduction, in addition to insight into the natural kinematic couplings. We used statistical resampling techniques to verify that the principal components were repeatable features of the data, and analysed their coefficient vectors to provide insight into the form of these natural couplings. Conceptually, the dominant principal components provide a natural set of control input variables that span the control input subspace of this species, but they can also be thought of as output states of the flight motor. This functional description of the wing kinematics is appropriate to modelling insect flight as a form of limit cycle control.

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Limit-cycle-based control of the myogenic wingbeat rhythm in the fruit flyDrosophila

Cited by 18 publications

References 55 publications

Neural control and precision of flight muscle activation in Drosophila

Neural control and precision of flight muscle activation in Drosophila

Fog and dense gas disrupt mosquito flight due to increased aerodynamic drag on halteres

Motor output and control input in flapping flight: a compact model of the deforming wing kinematics of manoeuvring hoverflies

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