A neuromechanical model for<i>Drosophila</i>larval crawling based on physical measurements

Sun, Xiyang; Liu, Yingtao; Liu, Chang; Mayumi, Koichi; Ito, K.; Nose, Akinao; Kohsaka, Hiroshi

doi:10.1101/2020.07.17.208611

Cited by 6 publications

(15 citation statements)

References 93 publications

(229 reference statements)

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“…Furthermore, kinematics of the larval locomotion have been measured and investigated quantitatively in detail (Gepner et al, 2015;Gershow et al, 2012;Gomez-Marin et al, 2011;Gomez-Marin & Louis, 2014;Heckscher et al, 2012;Hernandez-Nunez et al, 2015;Lahiri et al, 2011;Luo et al, 2010) and analysed by mathematical modelling (Gjorgjieva et al, 2013;Loveless et al, 2019;Loveless & Webb, 2018;Pehlevan et al, 2016;Sun et al, 2020).…”

Section: Discussionmentioning

confidence: 99%

“…Proprioceptive feedback and neuromodulation are both important for the normal crawling speed (Fox et al, 2006; Hughes & Thomas, 2007). Furthermore, kinematics of the larval locomotion have been measured and investigated quantitatively in detail (Gepner et al, 2015; Gershow et al, 2012; Gomez-Marin et al, 2011; Gomez-Marin & Louis, 2014; Heckscher et al, 2012; Hernandez-Nunez et al, 2015; Lahiri et al, 2011; Luo et al, 2010) and analysed by mathematical modelling (Gjorgjieva et al, 2013; Loveless et al, 2019; Loveless & Webb, 2018; Pehlevan et al, 2016; Sun et al, 2020). Regarding temperature sensing, neuronal and molecular mechanisms on temperature-guided behaviour have been clarified (Dillon et al, 2009; Klein et al, 2015; Kwon et al, 2008, 2010; Liu et al, 2003; Ni et al, 2016; Rosenzweig et al, 2005b, 2008; Shen et al, 2011).…”

Section: Discussionmentioning

confidence: 99%

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Interspecies variation of larval locomotion kinematics in the genusDrosophilaand its relation to habitat temperature

Matsuo

Nose

Kohsaka

2020

Preprint

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Speed and trajectory of locomotion are characteristic traits of individual species. During evolution, locomotion kinematics is likely to have been tuned for survival in the habitats of each species. Although kinematics of locomotion is thought to be influenced by habitats, the quantitative relation between the kinematics and environmental factors has not been fully revealed. Here, we performed comparative analyses of larval locomotion in 11 Drosophila species. We found that larval locomotion kinematics are divergent among the species. The diversity is not correlated to the body length but is correlated instead to the minimum habitat temperature of the species. Phylogenetic analyses using Bayesian inference suggest that the evolutionary rate of the kinematics is diverse among phylogenetic trees. The results of this study imply that the kinematics of larval locomotion has diverged in the evolutionary history of the genus Drosophila and evolved under the effects of the minimum ambient temperature of habitats.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Interspecies variation of larval locomotion kinematics in the genusDrosophilaand its relation to habitat temperature

Matsuo

Nose

Kohsaka

2020

Preprint

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“…As well as extensive behavioural data, there is currently a concerted effort to map the neural connectome of the larva, and to link observed neural anatomy and dynamics to behaviour [16][17][18][19][20][21][22][23][24][25][26][27]. Moreover, recent modelling studies have already explored the importance of biomechanics in understanding the animal's crawling (in 1 spatial dimension) [28][29][30][31] and substrate exploration/taxis behaviours (in 2 spatial dimensions) [30,32,33], emphasising the crucial role that sensory feedback, which conveys some measurement of the physical state of the animal to its nervous system, plays during behaviour [28][29][30][31]33]. Cutting-edge research is beginning to experimentally probe the physics of the animal's body [31].…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, recent modelling studies have already explored the importance of biomechanics in understanding the animal's crawling (in 1 spatial dimension) [28][29][30][31] and substrate exploration/taxis behaviours (in 2 spatial dimensions) [30,32,33], emphasising the crucial role that sensory feedback, which conveys some measurement of the physical state of the animal to its nervous system, plays during behaviour [28][29][30][31]33]. Cutting-edge research is beginning to experimentally probe the physics of the animal's body [31]. The larva thus offers a number of advantages as a model system for studying the physics of behaviour.…”

Section: Introductionmentioning

confidence: 99%

“…Correspondingly, Drosophila larvae are able to perform a wide repertoire of behaviours under experimental conditions [20], including: peristaltic crawling [21], rolling [22–24], self-righting [16, 25, 26], rearing [20], hunching [23], and digging [27–30]. Recent modelling studies have exploited this system to explore the importance of biomechanics in understanding the animal’s crawling (in one spatial dimension, 1D) [19, 31–33] and substrate exploration/taxis behaviours (in two spatial dimensions, 2D) [18, 19, 34]. Additionally, the larva provides a prototypical example of the bilaterally-symmetric, slender, soft, segmented body physics that are common to many animals, and that are increasingly being exploited in the design of robotic systems [4, 5].…”

Section: Introductionmentioning

confidence: 99%

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A physical theory of movement in small animals

Loveless

Garner

Issa

et al. 2020

Preprint

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All animal movement must ultimately be governed by physical laws. As a basis for understanding the interactions between the nervous system, musculature, body mechanics and the environment that govern behaviour in the fruit fly larva, we here develop an effective theory for the physics of its motion in three dimensions. We start by defining a set of fields which quantify stretching, bending and twisting along the larva's anteroposterior (AP) axis. We then perform a search in the space of possible physical theories that could govern these fields, by using symmetry considerations, stability requirements and physical reasoning to rule out possible terms in our theory's Lagrangian (which governs its energy-conservative physics) and Rayleigh function (which governs its energy-dissipative physics). We restrict attention to the physics that dominates at long-wavelengths, which allows us to arrive at a unique, simple theory of the larval midline, governed by a minimum of phenomenological parameters that capture both purely biomechanical as well as neuromuscular effects. Owing to the simplicity of our theory, we are able to derive most of our results analytically. The model makes strong quantitative predictions for the dynamics of peristalsis, rolling, and self-righting, and also successfully predicts statistical properties of these behaviours and of unbiased substrate exploration.

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Study of Optimal Stimulation Parameters in Drosophila Based on a Baseline Control Model

Wang

2024

Learning and Analytics in Intelligent Systems

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A neuromechanical model forDrosophilalarval crawling based on physical measurements

Cited by 6 publications

References 93 publications

Interspecies variation of larval locomotion kinematics in the genusDrosophilaand its relation to habitat temperature

Interspecies variation of larval locomotion kinematics in the genusDrosophilaand its relation to habitat temperature

A physical theory of movement in small animals

Study of Optimal Stimulation Parameters in Drosophila Based on a Baseline Control Model

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