The influence of nanoscale topographical cues on initial osteoblast morphology and migration

The natural environment of a living cell is not only organized on a micrometer, but also on a nanometer scale. Mimicking such a nanoscale topography in implantable biomaterials is critical to guide cellular behavior. Also, a correct positioning of cells on biomaterials is supposed to be very importa...

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Bibliographic Details
Published in:European cells & materials 2010-11, Vol.20, p.329-343
Main Authors: Lamers, E, van Horssen, R, te Riet, J, van Delft, F Cmjm, Luttge, R, Walboomers, X F, Jansen, J A
Format: Article
Language:English
Subjects:
Animals
Anisotropy
cell adhesion
cell motility
Cell Movement
Cells, Cultured
Focal Adhesions - metabolism
Nanostructures - chemistry
nanotopography
osteoblasts
Osteoblasts - cytology
Osteoblasts - physiology
Osteoblasts - ultrastructure
Rats
Surface Properties
surface texturing
Time-Lapse Imaging
Tissue Engineering - methods
Tissue-material interactions
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Summary:The natural environment of a living cell is not only organized on a micrometer, but also on a nanometer scale. Mimicking such a nanoscale topography in implantable biomaterials is critical to guide cellular behavior. Also, a correct positioning of cells on biomaterials is supposed to be very important for promoting wound healing and tissue regeneration. The exact mechanism by which nanotextures can control cellular behavior are thus far not well understood and it is thus far unknown how cells recognize and respond to certain surface patterns, whereas a directed response appears to be absent on other pattern types. Focal adhesions (FAs) are known to be involved in the process of specific pattern recognition and subsequent response by cells. In this study, we used a high throughput screening "Biochip" containing 40 different nanopatterns to evaluate the influence of several nanotopographical cues like depth, width, (an)isotropy and spacing (ridge-groove ratio) on osteoblast behavior. Microscopical analysis and time lapse imaging revealed that an isotropic topography did not alter cell morphology, but it highly induced cell motility. Cells cultured on anisotropic topographies on the other hand, were highly elongated and aligned. Time-lapse imaging revealed that cell motility is highly dependent on the ridge-groove ratio of anisotropic patterns. The highest motility was observed on grooves with a ratio of 1:3, whereas the lowest motility was observed on ratios of 1:1 and 3:1. FA measurements demonstrated that FA-length decreased with increasing motility. From the study it can be concluded that osteoblast behavior is tightly controlled by nanometer surface features.
ISSN:1473-2262
1473-2262
DOI:10.22203/ecm.v020a27