info:eu-repo/semantics/article
Influence of individual cell motility on the 2D front roughness dynamics of tumour cell colonies
Fecha
2014-06Registro en:
Muzzio, Nicolás Eduardo; Pasquale, Miguel Angel; González, P. H.; Arvia, A. J.; Influence of individual cell motility on the 2D front roughness dynamics of tumour cell colonies; Springer; Journal Of Biological Physics; 40; 3; 6-2014; 285-308
0092-0606
CONICET Digital
CONICET
Autor
Muzzio, Nicolás Eduardo
Pasquale, Miguel Angel
González, P. H.
Arvia, A. J.
Resumen
The dynamics of in situ 2D HeLa cell quasi-linear and quasi-radial colony fronts in a standard culture medium is investigated. For quasi-radial colonies, as the cell population increased, a kinetic transition from an exponential to a constant front average velocity regime was observed. Special attention was paid to individual cell motility evolution under constant average colony front velocity looking for its impact on the dynamics of the 2D colony front roughness. From the directionalities and velocity components of cell trajectories in colonies with different cell populations, the influence of both local cell density and cell crowding effects on individual cell motility was determined. The average dynamic behaviour of individual cells in the colony and its dependence on both local spatio-temporal heterogeneities and growth geometry suggested that cell motion undergoes under a concerted cell migration mechanism, in which both a limiting random walk-like and a limiting ballistic-like contribution were involved. These results were interesting to infer how biased cell trajectories influenced both the 2D colony spreading dynamics and the front roughness characteristics by local biased contributions to individual cell motion. These data are consistent with previous experimental and theoretical cell colony spreading data and provide additional evidence of the validity of the Kardar-Parisi-Zhang equation, within a certain range of time and colony front size, for describing the dynamics of 2D colony front roughness. © 2014 Springer Science+Business Media Dordrecht.