利用基于深度学习的自动视频跟踪技术测量海洋鱼类在不同适应期的活动-休息节律。

IF 2.2 4区 医学 Q2 BIOLOGY Chronobiology International Pub Date : 2024-07-01 Epub Date: 2024-07-08 DOI:10.1080/07420528.2024.2371143
Mourad Akaarir, Martina Martorell-Barceló, Bernat Morro, Margalida Suau, Josep Alós, Eneko Aspillaga, Antoni Gamundí, Amalia Grau, Arancha Lana, M Cristina Nicolau, Aina Pons, Rubén V Rial, Marco Signaroli, Margarida Barcelo-Serra
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引用次数: 0

摘要

大多数生物的活动节律约为 24 小时(昼夜节律)。本研究介绍了一种新型的深度学习驱动的视频跟踪方法,用于评估Xyrichtys novacula活动节律的稳定性、片段化、稳健性和同步性。实验中,X. novacula 被分为三组,并监测其与 14/10 小时光照/黑暗的同步性,以评估其对实验室条件的适应性。GP7组适应1周,在第7至14天进行测试;GP14组适应14天,在第14至21天进行测试;GP21组适应21天,在第21至28天进行测试。野外个体的遥测数据描述了它们的自然行为。野生鱼类的活动节律强健且极不分散,与自然光周期一致。在实验室条件下,明暗阶段的活动水平存在差异。然而,实验组之间的活动节律指标没有观察到与适应期有关的差异。值得注意的是,较长的适应期(GP14和GP21)会导致更大比例的个体表现出与强加光周期同步的节律。我们的工作介绍了一种在实验室条件下监测生物节律的新方法,该方法采用了基于深度学习的专门设计的视频跟踪系统,可适用于其他物种。
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Measuring activity-rest rhythms under different acclimation periods in a marine fish using automatic deep learning-based video tracking.

Most organisms synchronize to an approximately 24-hour (circadian) rhythm. This study introduces a novel deep learning-powered video tracking method to assess the stability, fragmentation, robustness and synchronization of activity rhythms in Xyrichtys novacula. Experimental X. novacula were distributed into three groups and monitored for synchronization to a 14/10 hours of light/dark to assess acclimation to laboratory conditions. Group GP7 acclimated for 1 week and was tested from days 7 to 14, GP14 acclimated for 14 days and was tested from days 14 to 21 and GP21 acclimated for 21 days and was tested from days 21 to 28. Telemetry data from individuals in the wild depicted their natural behavior. Wild fish displayed a robust and minimally fragmented rhythm, entrained to the natural photoperiod. Under laboratory conditions, differences in activity levels were observed between light and dark phases. However, no differences were observed in activity rhythm metrics among laboratory groups related to acclimation period. Notably, longer acclimation (GP14 and GP21) led to a larger proportion of individuals displaying rhythm synchronization with the imposed photoperiod. Our work introduces a novel approach for monitoring biological rhythms in laboratory conditions, employing a specifically engineered video tracking system based on deep learning, adaptable for other species.

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来源期刊
Chronobiology International
Chronobiology International 生物-生理学
CiteScore
5.60
自引率
7.10%
发文量
110
审稿时长
1 months
期刊介绍: Chronobiology International is the journal of biological and medical rhythm research. It is a transdisciplinary journal focusing on biological rhythm phenomena of all life forms. The journal publishes groundbreaking articles plus authoritative review papers, short communications of work in progress, case studies, and letters to the editor, for example, on genetic and molecular mechanisms of insect, animal and human biological timekeeping, including melatonin and pineal gland rhythms. It also publishes applied topics, for example, shiftwork, chronotypes, and associated personality traits; chronobiology and chronotherapy of sleep, cardiovascular, pulmonary, psychiatric, and other medical conditions. Articles in the journal pertain to basic and applied chronobiology, and to methods, statistics, and instrumentation for biological rhythm study. Read More: http://informahealthcare.com/page/cbi/Description
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