微尺度导航中的主动振荡。

IF 1.9 2区 生物学 Q3 BEHAVIORAL SCIENCES
Kirsty Y. Wan
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引用次数: 0

摘要

生物经常在周围环境中穿梭,以寻找更好的环境、更多的食物或躲避捕食者。通常情况下,动物通过将来自环境的感官线索与运动装置相结合来实现这一目的。对于单细胞或具有运动能力的小型生物来说,由于其体积小而受到基本的物理限制,这就导致了微观世界特有的其他导航策略。耐人寻味的是,在这些无数的探索行为或感官功能的背后,是多种尺度的周期性活动的开始,例如纤毛和鞭毛的起伏、毛细胞的振动或迁移的中性粒细胞的振荡形状模式。在这里,我探讨了基底微真核细胞的振荡动力学,并假设这些活跃的振荡在提高适应性感觉运动整合的保真度方面发挥着关键作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Active oscillations in microscale navigation

Active oscillations in microscale navigation

Living organisms routinely navigate their surroundings in search of better conditions, more food, or to avoid predators. Typically, animals do so by integrating sensory cues from the environment with their locomotor apparatuses. For single cells or small organisms that possess motility, fundamental physical constraints imposed by their small size have led to alternative navigation strategies that are specific to the microscopic world. Intriguingly, underlying these myriad exploratory behaviours or sensory functions is the onset of periodic activity at multiple scales, such as the undulations of cilia and flagella, the vibrations of hair cells, or the oscillatory shape modes of migrating neutrophils. Here, I explore oscillatory dynamics in basal microeukaryotes and hypothesize that these active oscillations play a critical role in enhancing the fidelity of adaptive sensorimotor integration.

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来源期刊
Animal Cognition
Animal Cognition 生物-动物学
CiteScore
4.50
自引率
18.50%
发文量
125
审稿时长
4-8 weeks
期刊介绍: Animal Cognition is an interdisciplinary journal offering current research from many disciplines (ethology, behavioral ecology, animal behavior and learning, cognitive sciences, comparative psychology and evolutionary psychology) on all aspects of animal (and human) cognition in an evolutionary framework. Animal Cognition publishes original empirical and theoretical work, reviews, methods papers, short communications and correspondence on the mechanisms and evolution of biologically rooted cognitive-intellectual structures. The journal explores animal time perception and use; causality detection; innate reaction patterns and innate bases of learning; numerical competence and frequency expectancies; symbol use; communication; problem solving, animal thinking and use of tools, and the modularity of the mind.
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