Sensory Cues Modulate Smooth Pursuit and Active Sensing Movements

Uyanik, Ismail; Stamper, Sarah A.; Cowan, Noah J.; Fortune, Eric S.

doi:10.3389/fnbeh.2019.00059

Cited by 13 publications

(28 citation statements)

References 33 publications

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“…We further studied the optically relevant effects by examining the v of the test individuals because swimming speed can timely represent the real‐time biological status of fish. The evidence from zebrafish ( Danio rerio ) denoted that evoked anxiety could be characterised by faster swimming with spontaneous rapid turns and increased maximum swimming speed (Egan et al, 2009; Pozo Cano & Sánchez Vázquez, 2015), while the fish also used the active longitudinal movement to locate positions in case of refuge tracking (Uyanik et al, 2019). In this study, the dissimilar light‐induced accelerated swimming of the two species possibly originated from different physiological mechanisms.…”

Section: Discussionmentioning

confidence: 99%

Mutually promoting or constraining? Disentangling the superimposed effect of velocity and illuminance on fish motion in low‐velocity flows with a novel metric

et al. 2022

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Global climate change, species invasion, and human activities such as the construction of hydraulic facilities are contributing to the worldwide degradation of fish stocks. As a pivotal environmental factor that affects fish migration and population distribution, the low‐velocity flow has not drawn enough attention despite its extensive presence in various ecoregions. To understand the behavioural profiles of fish in low‐velocity flow, we examined the motility and swimming performance of two representative cyprinids, grass carp (GC, Ctenopharyngodon idella) and silver carp (SC, Hypophthalmichthys molitrix), under the combined effect of different flow velocities and illuminance ranges. The two species were exposed to two flow velocities (0.15 and 0.25 m/s) and three illuminance ranges (100.0–0.9 lx, 300.0–2.5 lx, and 700.0–4.9 lx). A novel behavioural metric, composed of light preference, swimming speed, rheotaxis index (RI), swimming stability (SS), and the probability of moving forwards/backwards over a certain distance (PMf‐0.1 and PMb‐0.1), was developed to fully characterise the motion strategy of fish. By analysing the individual distribution in light gradient, we confirmed the scototaxis of GC and found the oscillating light preference in SC that changed from 84.41–10.18 to 6.00–2.08 lx and disappeared with increasing illuminance. The RI and SS increased at the fast flow velocity (0.25 m/s) for both species, and SC was more forward‐prone and more stable than GC. Despite the fluctuating light preference, the higher illuminances heightened the RI and SS in SC, while in GC, higher illuminances inhibited the SS and had no impact on the RI. The results of PMf‐0.1 and PMb‐0.1 indicated that a higher flow velocity could facilitate the temporary upstream swimming in both species, while illuminance could only promote the same effect in SC. Finally, our study proposed possible manoeuvres in fine‐scale spatio‐temporal scenarios such as attraction flow and non‐traditional passages and provided valuable insights into fish community dynamics, laying the groundwork for alleviating the threat from invasive species and for future fish population recovery.

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Section: Discussionmentioning

confidence: 99%

Mutually promoting or constraining? Disentangling the superimposed effect of velocity and illuminance on fish motion in low‐velocity flows with a novel metric

et al. 2022

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“…A key difference would be that the signal in question would arise from an internal representation of sensory uncertainty, rather than overall level of sensory excitation. Such a reflex-like action could produce stereotyped forms of interactions with the external environment in relation to sensing [14].…”

Section: Discussionmentioning

confidence: 99%

“…For example, neurophysiological recordings show that sensory salience can be encoded in brain circuits via synchronization and desynchronization of spiking activity [39]. Such population coding of salience [40][41][42], when coupled with a threshold, could trigger discrete bursts of motor activity for sensing [14]. Motor circuits for the production of discrete bursts of movement occur in spinal circuits [43].…”

Section: Discussionmentioning

confidence: 99%

“…The experimental apparatus was similar to that used in previous studies [2,[10][11][12]14]. See [2] for more detailed description of the apparatus.…”

Section: Experimental Apparatus and Proceduresmentioning

confidence: 99%

“…and goal-driven exploitative movements [10,13] using the same locomotor system [14,15]. Critically, this behavior illustrates how explore and exploit movements are often in conflict with one another: fish produce back-and-forth exploratory movements [2,3,9] to detect and maintain their position within a stationary refuge.…”

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confidence: 95%

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Organisms use mode-switching to solve the explore-vs-exploit problem

Biswas

Lamperski

et al. 2023

Preprint

Self Cite

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Movement and sensing are linked in organisms as their sensors are embedded in their bodies. This inescapable link results in a behavioral conflict between producing costly movements for gathering information ("explore") [1-3] versus using previously acquired information to achieve a goal ("exploit") [4]. Optimally trading-off exploration and exploitation is an intractable problem [6-8], and the strategies that animals utilize to resolve this conflict are poorly understood [5]. Here we show that weakly electric fish (\textit{Eigenmannia virescens}) [2, 3, 9] use a mode-switching strategy that solves the explore-exploit conflict [5] during a refuge tracking task [10-13] and show that this strategy is modulated by sensory salience. Fish produced distinctive non-Gaussian (i.e., non-normal) distributions of movement velocities characterized by sharp peaks for slower, task-oriented "exploit" movements and broad shoulders for faster, "explore" movements. Surprisingly, measures of non-normality increased (rather than decreased) in relation to increased sensory salience. Reanalysis of published data revealed that this distinctive distribution of movement velocities is produced by phylogenetically diverse organisms, from amoeba to humans. Further, other species exhibited the same counter-intuitive modulation of mode-switching in relation to sensory salience. We propose a parsimonious, state-uncertainty based mode-switching heuristic that reproduces the distinctive velocity distribution and explains its relationship to sensory salience. This mode-switching strategy likely manifests in diverse biological mechanisms, from cellular processes for single-cell motility to network-level processes for the control of movement in animals.

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Active Control of Sensing Through Movements in Active Electrolocation

Engelmann¹,

Lucks²

2020

The Senses: A Comprehensive Reference

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Sensory Cues Modulate Smooth Pursuit and Active Sensing Movements

Cited by 13 publications

References 33 publications

Mutually promoting or constraining? Disentangling the superimposed effect of velocity and illuminance on fish motion in low‐velocity flows with a novel metric

Mutually promoting or constraining? Disentangling the superimposed effect of velocity and illuminance on fish motion in low‐velocity flows with a novel metric

Organisms use mode-switching to solve the explore-vs-exploit problem

Active Control of Sensing Through Movements in Active Electrolocation

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