量化斑马鱼幼体在不同实验条件下的运动行为变异性基于学习的追踪器

IF 2.1 3区 农林科学 Q2 FISHERIES
Fishes Pub Date : 2024-05-23 DOI:10.3390/fishes9060193
Zhuo Zhang, Xinyu Chai, Guoning Si, Xuping Zhang
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引用次数: 0

摘要

本研究通过单因素实验和正交实验来评估温度和 pH 值变化时的运动情况,从而研究环境变化对斑马鱼幼体行为的影响。在单因素实验中,斑马鱼幼体暴露于温度(22 至 30 °C)和 pH 值(6.0、7.0、9.0)的变化中。温度和 pH 值的同时变化则通过正交试验进行研究。在这两项实验中,每条斑马鱼幼体在不同阶段(暴露前、短期暴露期间(10 分钟)和长期暴露后(60 分钟))都被录制成三段 5 分钟的视频。采用 "只看一次"(YOLOv5)和 "深度简单在线实时跟踪"(DeepSORT)模型开发了斑马鱼幼虫跟踪系统,并在锚聚类和网络结构两个方面对YOLOv5进行了改进。跟踪系统对小目标的跟踪精度得到有效提高,MOTA(多目标跟踪精度)达到98%以上。我们采用主成分分析法(PCA)从13个运动参数中提取了三个行为特征,即运动活动、边缘行为和运动方向偏好。我们的研究结果表明,较低的温度和酸性条件都会导致运动行为活动减少,前者还会增加边缘行为。相反,温度升高和碱性条件对这些行为的影响不大。有趣的是,同时改变温度和酸碱度会显著改变方向偏好。此外,我们还观察到,在 pH 值不变的情况下,较低的温度会引起不同的时间行为模式。总之,我们建议在饲养装置和实验井中精确控制和明确报告环境温度和 pH 值,以尽量减少环境对斑马鱼行为的影响,提高实验的可重复性和可靠性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Quantifying Variability in Zebrafish Larvae Locomotor Behavior across Experimental Conditions: A Learning-Based Tracker
This study investigated the effects of environmental changes on zebrafish larval behavior, using single-factor and orthogonal experiments to assess locomotion during temperature and pH changes. In single-factor experiments, zebrafish larvae were exposed to variations in temperature (22 to 30 °C) and pH levels (6.0, 7.0, 9.0). The simultaneous temperature and pH changes were investigated by orthogonal tests. In both experiments, each zebrafish larva was recorded in three 5 min videos at different stages (before exposure, during short-term exposure (10 min), and after long-term exposure (60 min)). You Look Only Once (YOLOv5) and Deep Simple Online Real Time Tracking (DeepSORT) models were adopted to develop a zebrafish larva tracking system, and YOLOv5 was improved in two aspects of anchor clustering and network structure. The tracking accuracy of the tracking system for small targets effectively improved, reaching more than 98% MOTA (Multiple Object Tracking Accuracy). Principal Component Analysis (PCA) was employed to extract three behavioral features from 13 motion parameters, namely motion activity, edge behavior, and motion direction preference. Our findings reveal that lower temperatures and acidic conditions both led to a decrease in motion behavioral activity, and the former also increased edge behavior. Conversely, elevated temperatures and alkaline conditions had a muted impact on these behaviors. Interestingly, concurrent changes in temperature and pH significantly altered directional preference. Additionally, we observed that lower temperatures elicited distinct temporal behavioral patterns at a constant pH level. In summary, we recommend the precise control and explicit reporting of ambient temperature and pH in both breeding devices and experimental wells to minimize the environmental impact on zebrafish behavior and enhance experiment repeatability and reliability.
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来源期刊
Fishes
Fishes Multiple-
CiteScore
1.90
自引率
8.70%
发文量
311
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