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multiphysics computational environment comsol v4.0  (COMSOL Inc)
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COMSOL Inc multiphysics computational environment comsol v4.0
Step wise, time-sequenced volumetric cytoskeletal deformations due to applied microfluidic stresses created within an optohydrodynamic trap environment. Simulated deformations were modeled with a multiphysics computational software (COMSOL <t>v4.0).</t> Minimum deformation is indicated by dark blue while maximum deformation is in dark red. Units for the deformation scale are in micrometers ( μ m).
Multiphysics Computational Environment Comsol V4.0, supplied by COMSOL Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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Step wise, time-sequenced volumetric cytoskeletal deformations due to applied microfluidic stresses created within an optohydrodynamic trap environment. Simulated deformations were modeled with a multiphysics computational software (COMSOL v4.0). Minimum deformation is indicated by dark blue while maximum deformation is in dark red. Units for the deformation scale are in micrometers ( μ m).

Journal: Journal of Biophysics

Article Title: Cytoskeletal Strains in Modeled Optohydrodynamically Stressed Healthy and Diseased Biological Cells

doi: 10.1155/2012/830741

Figure Lengend Snippet: Step wise, time-sequenced volumetric cytoskeletal deformations due to applied microfluidic stresses created within an optohydrodynamic trap environment. Simulated deformations were modeled with a multiphysics computational software (COMSOL v4.0). Minimum deformation is indicated by dark blue while maximum deformation is in dark red. Units for the deformation scale are in micrometers ( μ m).

Article Snippet: The optohydrodynamic deviatoric stress state was applied to an isotropic, homogenous biological cell (20 μ m in diameter) within a multiphysics computational environment (COMSOL v4.0, Palo Alto, CA, USA) in order to determine the individual principal strains and in turn the volumetric strains.

Techniques: Software