Assessment of long-range correlation in animal behavior time series: The temporal pattern of locomotor activity of Japanese quail (Coturnix coturnix) and mosquito larva (Culex quinquefasciatus)

Kembro, Jackelyn Melissa; Flesia, Ana Georgina; Gleiser, Raquel M.; Perillo, Marı́a A.; Marín, Raúl Héctor

doi:10.1016/j.physa.2013.08.017

Cited by 19 publications

(31 citation statements)

References 45 publications

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“…64 and is described in detail elsewhere 18, 55 and in section SI Detrended Fluctuation Analysis. Briefly, DFA estimates the self-similarity parameter α that measures the autocorrelation structure of the time series.…”

Section: Methodsmentioning

confidence: 99%

The fractal organization of ultradian rhythms in avian behavior

Guzmán

Flesia

Aon

et al. 2017

Sci Rep

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Living systems exhibit non-randomly organized biochemical, physiological, and behavioral processes that follow distinctive patterns. In particular, animal behavior displays both fractal dynamics and periodic rhythms yet the relationship between these two dynamic regimens remain unexplored. Herein we studied locomotor time series of visually isolated Japanese quails sampled every 0.5 s during 6.5 days (>106 data points). These high-resolution, week-long, time series enabled simultaneous evaluation of ultradian rhythms as well as fractal organization according to six different analytical methods that included Power Spectrum, Enright, Empirical Mode Decomposition, Wavelet, and Detrended Fluctuation analyses. Time series analyses showed that all birds exhibit circadian rhythms. Although interindividual differences were detected, animals presented ultradian behavioral rhythms of 12, 8, 6, 4.8, 4 h and/or lower and, irrespective of visual isolation, synchronization between these ultradian rhythms was observed. Moreover, all birds presented similar overall fractal dynamics (for scales ∼30 s to >4.4 h). This is the first demonstration that avian behavior presents fractal organization that predominates at shorter time scales and coexists with synchronized ultradian rhythms. This chronobiological pattern is advantageous for keeping the organism’s endogenous rhythms in phase with internal and environmental periodicities, notably the feeding, light-dark and sleep-wake cycles.

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Section: Methodsmentioning

confidence: 99%

The fractal organization of ultradian rhythms in avian behavior

Guzmán

Flesia

Aon

et al. 2017

Sci Rep

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“…Fractal geometry provides a mathematical framework for characterizing scale-free and self-similar patterns 3 – 5 . Fractal temporal patterns of behavior and physiology have been reported in the locomotion of birds, mosquito larvae, and flies 6 – 8 , crawling of cultured C. elegans worms 9 , clicking sounds produced by feeding sea horses 10 , and swimming of zooplankton 11 , 12 . In humans, temporal fractal patterns have been observed in wrist movements during habitual sleep/wake cycles 13 , gait 14 , 15 , heartbeats 16 , 17 , and brain activity 18 , 19 .…”

Section: Introductionmentioning

confidence: 99%

C. elegans episodic swimming is driven by multifractal kinetics

Ikeda

Jurica

Kimura

et al. 2020

Sci Rep

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Fractal scaling is a common property of temporal change in various modes of animal behavior. The molecular mechanisms of fractal scaling in animal behaviors remain largely unexplored. The nematode C. elegans alternates between swimming and resting states in a liquid solution. Here, we report that C. elegans episodic swimming is characterized by scale-free kinetics with long-range temporal correlation and local temporal clusterization, namely consistent with multifractal kinetics. Residence times in actively-moving and inactive states were distributed in a power law-based scale-free manner. Multifractal analysis showed that temporal correlation and temporal clusterization were distinct between the actively-moving state and the inactive state. These results indicate that C. elegans episodic swimming is driven by transition between two behavioral states, in which each of two transition kinetics follows distinct multifractal kinetics. We found that a conserved behavioral modulator, cyclic GMP dependent kinase (PKG) may regulate the multifractal kinetics underlying an animal behavior. Our combinatorial analysis approach involving molecular genetics and kinetics provides a platform for the molecular dissection of the fractal nature of physiological and behavioral phenomena.

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“…A scale-free distribution of actively-moving and inactive residence times has been reported for episodic Drosophila behavior 9 ; modeling suggested that the scale-free nature of these residence times contributes to maximizing the food exploitation area while optimizing food intake time. Previous analyses have shown long-range temporal correlations in scale-free properties of the behaviors of many species, including fractal (but not multifractal) analysis of C. elegans crawling 7,8,10–13 . The fractal nature of C. elegans crawling in agar (Alves et al, 2017) is consistent with our long-range memory and clusterization finding.…”

Section: Discussionmentioning

confidence: 99%

“…Fractal geometry provides a mathematical framework for characterizing scale-free and self-similar patterns 4–6 . Fractal temporal patterns of behavior and physiology have been reported in the locomotion of birds, mosquito larvae, and flies 7–9 , crawling of cultured C. elegans worms 10 , clicking sounds produced by feeding sea horses 11 , and swimming of zooplankton 12,13 . In humans, temporal fractal patterns have been observed in wrist movements during habitual sleep/wake cycles 14 , gait 15,16 , heartbeats 17,18 , and brain activity 19,20 .…”

Section: Introductionmentioning

confidence: 99%

C. elegansepisodic swimming is driven by multifractal kinetics

Ikeda

Jurica

Kimurâ

et al. 2020

Preprint

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Fractal scaling is a common property of temporal change in various modes of animal behavior. The molecular mechanisms of fractal scaling in animal behaviors remain largely unexplored. The nematode C. elegans alternates between swimming and resting states in a liquid solution. Here, we report that C. elegans episodic swimming is characterized by scale-free kinetics with long-range temporal correlation and local temporal clusterization, which is characterized as multifractal kinetics. Residence times in actively-moving and inactive states were distributed in a power law-based scale-free manner. Multifractal analysis showed that temporal correlation and temporal clusterization were distinct between the actively-moving state and the inactive state. These results indicate that C. elegans episodic swimming is driven by transition between two behavioral states, in which each of two transition kinetics follows distinct multifractal kinetics. We found that a conserved behavioral modulator, cyclic GMP dependent kinase (PKG) may regulate the multifractal kinetics underlying an animal behavior. Our combinatorial analysis approach involving molecular genetics and kinetics provides a platform for the molecular dissection of the fractal nature of physiological and behavioral phenomena.

show abstract

Assessment of long-range correlation in animal behavior time series: The temporal pattern of locomotor activity of Japanese quail (Coturnix coturnix) and mosquito larva (Culex quinquefasciatus)

Cited by 19 publications

References 45 publications

The fractal organization of ultradian rhythms in avian behavior

The fractal organization of ultradian rhythms in avian behavior

C. elegans episodic swimming is driven by multifractal kinetics

C. elegansepisodic swimming is driven by multifractal kinetics

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