Mehdi Farsad, Ph.D.
Affiliations: | 2011 | Civil Engineering | University of Colorado, Boulder, Boulder, CO, United States |
Area:
Civil Engineering, Biomechanics Biophysics, Mechanical EngineeringGoogle:
"Mehdi Farsad"Parents
Sign in to add mentor| Franck J. Vernerey | grad student | 2011 | CU Boulder | |
| (A Chemo-Mechanical Approach to Model Cell Contraction and Spreading on Elastic Substrates.) | ||||
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Publications
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| Farsad M, Zeinali-Davarani S, Choi J, et al. (2015) Computational growth and remodeling of abdominal aortic aneurysms constrained by the spine Journal of Biomechanical Engineering. 137 |
| Farsad M, Zambrano BA, Baek S. (2015) Data-guided growth and remodeling model of abdominal aortic aneurysm accounting for the bio-chemical effects of intraluminal thrombus Computational Biomechanics For Medicine: New Approaches and New Applications. 13-23 |
| Vernerey FJ, Farsad M. (2014) A mathematical model of the coupled mechanisms of cell adhesion, contraction and spreading. Journal of Mathematical Biology. 68: 989-1022 |
| Farsad M, Vernerey FJ. (2012) An XFEM-based numerical strategy to model mechanical interactions between biological cells and a deformable substrate International Journal For Numerical Methods in Engineering. 92: 238-267 |
| Vernerey FJ, Farsad M. (2011) A constrained mixture approach to mechano-sensing and force generation in contractile cells. Journal of the Mechanical Behavior of Biomedical Materials. 4: 1683-99 |
| Vernerey FJ, Farsad M. (2011) An Eulerian/XFEM formulation for the large deformation of cortical cell membrane. Computer Methods in Biomechanics and Biomedical Engineering. 14: 433-45 |
| Vernerey FJ, Foucard L, Farsad M. (2011) Bridging the Scales to Explore Cellular Adaptation and Remodeling Bionanoscience. 1: 110-115 |
| Farsad M, Vernerey FJ, Park HS. (2010) An extended finite element/level set method to study surface effects on the mechanical behavior and properties of nanomaterials International Journal For Numerical Methods in Engineering. 84: 1466-1489 |