A deep learning analysis of Drosophila body kinematics during magnetically tethered flight.

IF 1.8 4区 医学 Q3 GENETICS & HEREDITY Journal of neurogenetics Pub Date : 2023-03-01 DOI:10.1080/01677063.2023.2210682
Geonil Kim, JoonHu An, Subin Ha, Anmo J Kim
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引用次数: 2

Abstract

Flying Drosophila rely on their vision to detect visual objects and adjust their flight course. Despite their robust fixation on a dark, vertical bar, our understanding of the underlying visuomotor neural circuits remains limited, in part due to difficulties in analyzing detailed body kinematics in a sensitive behavioral assay. In this study, we observed the body kinematics of flying Drosophila using a magnetically tethered flight assay, in which flies are free to rotate around their yaw axis, enabling naturalistic visual and proprioceptive feedback. Additionally, we used deep learning-based video analyses to characterize the kinematics of multiple body parts in flying animals. By applying this pipeline of behavioral experiments and analyses, we characterized the detailed body kinematics during rapid flight turns (or saccades) in two different visual conditions: spontaneous flight saccades under static screen and bar-fixating saccades while tracking a rotating bar. We found that both types of saccades involved movements of multiple body parts and that the overall dynamics were comparable. Our study highlights the importance of sensitive behavioral assays and analysis tools for characterizing complex visual behaviors.

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果蝇在磁系飞行过程中身体运动学的深度学习分析。
果蝇依靠它们的视觉来探测视觉物体并调整它们的飞行路线。尽管他们牢固地固定在一个黑暗的垂直条上,我们对潜在的视觉运动神经回路的理解仍然有限,部分原因是难以在敏感的行为分析中分析详细的身体运动学。在这项研究中,我们使用磁系飞行实验观察飞行果蝇的身体运动学,其中苍蝇可以围绕其偏航轴自由旋转,从而实现自然的视觉和本体感觉反馈。此外,我们使用基于深度学习的视频分析来表征飞行动物多个身体部位的运动学。通过应用这些行为实验和分析,我们在两种不同的视觉条件下描述了快速飞行转弯(或扫视)时的详细身体运动学:静态屏幕下的自发飞行扫视和跟踪旋转杆时注视杆的扫视。我们发现,两种类型的扫视都涉及到多个身体部位的运动,而且总体动态是相似的。我们的研究强调了敏感的行为分析和分析工具对表征复杂视觉行为的重要性。
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来源期刊
Journal of neurogenetics
Journal of neurogenetics 医学-神经科学
CiteScore
4.40
自引率
0.00%
发文量
13
审稿时长
>12 weeks
期刊介绍: The Journal is appropriate for papers on behavioral, biochemical, or cellular aspects of neural function, plasticity, aging or disease. In addition to analyses in the traditional genetic-model organisms, C. elegans, Drosophila, mouse and the zebrafish, the Journal encourages submission of neurogenetic investigations performed in organisms not easily amenable to experimental genetics. Such investigations might, for instance, describe behavioral differences deriving from genetic variation within a species, or report human disease studies that provide exceptional insights into biological mechanisms
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