Engineering of silicon surfaces at the micro- and nanoscales for cell adhesion and migration control

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Engineering of silicon surfaces at the micro- and nanoscales for cell adhesion and migration control

Vicente Torres-Costa1, Gonzalo Mart&iacute;nez-Mu&ntilde;oz2, Vanessa S&aacute;nchez-Vaquero3, &Aacute;lvaro Mu&ntilde;oz-Noval1, Laura Gonz&aacute;lez-M&eacute;ndez3, Esther Punz&oacute;n-Quijorna1,4, Dar&iacute;o Gallach-P&...

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Detalles Bibliográficos
Autores principales:	Torres-Costa V, Mart&iacute;nez-Mu&ntilde;oz G, S&aacute;nchez-Vaquero V, Mu&ntilde;oz-Noval A, Gonz&aacute;lez-M&eacute;ndez L, Punz&oacute;n-Quijorna E, Gallach-P&eacute;rez D, Manso-Silv&aacute;n M, Climent-Font A, Garc&iacute;a-Ruiz JP, Mart&iacute;n-Palma RJ
Formato:	article
Lenguaje:	EN
Publicado:	Dove Medical Press 2012
Materias:	Medicine (General) R5-920
Acceso en línea:	https://doaj.org/article/3cdbafceb7494f738474a60baaf3fd72
Etiquetas:	Agregar Etiqueta Sin Etiquetas, Sea el primero en etiquetar este registro!

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Sumario:	Vicente Torres-Costa1, Gonzalo Mart&iacute;nez-Mu&ntilde;oz2, Vanessa S&aacute;nchez-Vaquero3, &Aacute;lvaro Mu&ntilde;oz-Noval1, Laura Gonz&aacute;lez-M&eacute;ndez3, Esther Punz&oacute;n-Quijorna1,4, Dar&iacute;o Gallach-P&eacute;rez1, Miguel Manso-Silv&aacute;n1, Aurelio Climent-Font1,4, Josefa P Garc&iacute;a-Ruiz3, Ra&uacute;l J Mart&iacute;n-Palma11Department of Applied Physics, 2Department of Computer Science, 3Department of Molecular Biology, 4Centre for Micro Analysis of Materials, Universidad Aut&oacute;noma de Madrid, Madrid, SpainAbstract: The engineering of surface patterns is a powerful tool for analyzing cellular communication factors involved in the processes of adhesion, migration, and expansion, which can have a notable impact on therapeutic applications including tissue engineering. In this regard, the main objective of this research was to fabricate patterned and textured surfaces at micron- and nanoscale levels, respectively, with very different chemical and topographic characteristics to control cell&ndash;substrate interactions. For this task, one-dimensional (1-D) and two-dimensional (2-D) patterns combining silicon and nanostructured porous silicon were engineered by ion beam irradiation and subsequent electrochemical etch. The experimental results show that under the influence of chemical and morphological stimuli, human mesenchymal stem cells polarize and move directionally toward or away from the particular stimulus. Furthermore, a computational model was developed aiming at understanding cell behavior by reproducing the surface distribution and migration of human mesenchymal stem cells observed experimentally.Keywords: surface patterns, silicon, hMSCs, ion-beam patterning