1998
DOI: 10.1103/physrevlett.81.3038
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Exponential Distribution of Locomotion Activity in Cell Cultures

Abstract: In vitro velocities of several cell types have been measured using computer controlled video microscopy, which allowed to record the cells' trajectories over several days. On the basis of our large data sets we show that the locomotion activity displays a universal exponential distribution. Thus, motion resulting from complex cellular processes can be well described by an unexpected, but very simple distribution function. A simple phenomenological model based on the interaction of various cellular processes an… Show more

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Cited by 100 publications
(98 citation statements)
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“…At long times, however, it will tend to a Gaussian distribution, as the central limit theorem requires. So, we see that, provided our window of experimental times cannot reach the asymptotic regime t κ −1 an exponential decay of the velocities will be found, as observed in [10,33]. This cannot explain, however, why power-law tails have been observed in other experimental works.…”
Section: D) Speed and Velocity Distributionsmentioning
confidence: 59%
See 1 more Smart Citation
“…At long times, however, it will tend to a Gaussian distribution, as the central limit theorem requires. So, we see that, provided our window of experimental times cannot reach the asymptotic regime t κ −1 an exponential decay of the velocities will be found, as observed in [10,33]. This cannot explain, however, why power-law tails have been observed in other experimental works.…”
Section: D) Speed and Velocity Distributionsmentioning
confidence: 59%
“…To be more specific, one of the components of the velocity (for example, v x ) is observed to exhibit this unexpected behavior [8,10,25,26,33]. This is clearly a departure from the OU process, where all the components of the velocity are Gaussian variables.…”
Section: D) Speed and Velocity Distributionsmentioning
confidence: 99%
“…2A), and the average single-cell distribution from one experiment displays a distinct non-Gaussian tail (Fig. 2B) that has previously been shown to be a general feature of non-sheet-forming motile cells (37). The existence of similar non-Gaussian single-cell speed distributions suggests by the central limit theorem that each cell does not have an inherent velocity scale, but rather that cell speed is a dependent variable.…”
Section: Resultsmentioning
confidence: 85%
“…This is shown below through a number of statistical tests. Although simpler theoretical models have been presented in the past with the objective of investigating certain traits of the collective migration phenomena (21,22,37,(42)(43)(44)(45), none of these models is able to simultaneously account for a wide variety of the migration data such as ours, and our model thus provides one of the simplest ways of incorporating all of our observations in a physically transparent formulation.…”
Section: Resultsmentioning
confidence: 99%
“…Since then, several problems involving cell movement have been addressed by computational means, including neuron displacement (4-6), flagellar movement (7), migration of tumor cells (8), congregation at point sources of food (9), sperm displacement (10)(11)(12)(13)(14)(15), white blood cell motion (16), and chromosome movement (17). The investigation by Czir ok (18) represents one of the few approaches to general cell movement considering large databases, which resulted in the interesting verification that the cumulative velocity magnitudes follow an exponential distribution. Interesting results regarding 3D trajectory characterization have been reported by Crenshaw (19).…”
mentioning
confidence: 99%