Cellular attachment and the establishing of cell-cell contacts is one of the key questions in the development of advanced biomaterials. Many parameters that influence cell attachment, motility, and retention under external forces have already been established. Among these are the chemical properties and the presentation of specific functionalities and factors, but also geometric aspects of the distribution of cellular attachment sites (focal contacts) and the cellular geometry, both of which induce cellular responses and changes in phenotype. A systematic investigation of the influence of the nanoscopic distribution and size of focal contacts and of the microscopic cell shape on the stability of cellular adhesion will use a versatile, topography-free nanopatterned substrate produced by self-assembly. Using vascular endothelial cells as a naturally two-dimensional cell type of great clinical significance for the seeding of vascular grafts, this nanopatterning approach will shed light on how endothelial cells attach to surfaces, establish the required phenotype, and build a complete vessel lining by forming well-defined and stable cell-cell contacts. The hypothesis driving this work is that a nanopatterned distribution of well-defined attachment sites for the anchoring of endothelial cells results in a stable endothelium under physiologic shear stress. This hypothesis will be tested by (1) designing and fabricating smooth nanopatterned surfaces of controlled size and biological functionality using self-assembly methods, (2) seeding endothelial cells onto nanopatterns and analyzing their adhesion, cytoskeletal arrangement, and intercellular contact development and dynamics under both static and flow conditions, (3) contrasting the results of (2) with observations and measurements on topographic nanopatterned surfaces created by micromachining or molding processes. This study will reveal systematic relationships between endothelial cell differentiation and activity and the geometric and chemical properties of the underlying surface. The results will provide new design principles to enhance the seeding processes for either traditional polymeric or modern tissue-engineered graft materials to establish an endothelial cell lining that is capable of long-term prevention of vascular occlusion. Such principles could lead to the long-sought designed arteries that are tissue-engineered in their main structural components as well as in the inner lining, and shed light in general on the mechanisms of cell-biomaterial interactions.

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21EB003038-01
Application #
6737333
Study Section
Special Emphasis Panel (ZRG1-SSS-M (56))
Program Officer
Moy, Peter
Project Start
2003-09-30
Project End
2005-08-31
Budget Start
2003-09-30
Budget End
2004-08-31
Support Year
1
Fiscal Year
2003
Total Cost
$195,000
Indirect Cost
Name
University of Texas Austin
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
170230239
City
Austin
State
TX
Country
United States
Zip Code
78712
Slater, John H; Boyce, Patrick J; Jancaitis, Matthew P et al. (2015) Modulation of endothelial cell migration via manipulation of adhesion site growth using nanopatterned surfaces. ACS Appl Mater Interfaces 7:4390-400
Park, Soyeun; Frey, Wolfgang (2011) Polymer nanogels grafted from nanopatterned surfaces studied by AFM force spectroscopy. Langmuir 27:8956-66
Slater, John H; Frey, Wolfgang (2008) Nanopatterning of fibronectin and the influence of integrin clustering on endothelial cell spreading and proliferation. J Biomed Mater Res A 87:176-95