Image-based biomechanics of collagen-based tissue equivalents

Author

Sander, Edward A. ; Stylianopoulos, Triantafyllos ; Tranquillo, Robert T. ; Barocas, Victor H.

Author_Institution

Univ. of Minnesota, MN

Volume

28

Issue

3

fYear

2009

Firstpage

10

Lastpage

18

Abstract

In this study, we compared experimentally measured fiber network kinematics and the macroscopic mechanical response from cell-compacted, cross-shaped collagen gels (cruciforms), with the predictions from our multiscale modeling technique. The macroscopic finite element model matched the physical dimensions and boundary conditions of the experimental cruciform to be modeled. Different microscale network models were constructed for each finite element that matched fiber microstructure described by maps of the local direction and strength of alignment obtained from polarimetric alignment imaging. The outputs of the multiscale model included the macroscopic load-deformation response and the microscopic (fiber) kinematics.

Keywords

biomechanics; biomedical optical imaging; cellular biophysics; finite element analysis; polarimetry; proteins; tissue engineering; collagen-based tissue equivalent; cross-shaped collagen gels; fiber microstructure; fiber network kinematics measurement; image-based biomechanics; macroscopic finite element model; macroscopic load-deformation response; macroscopic mechanical response; multiscale network modeling technique; polarimetric alignment imaging; Biomechanics; Bovine; Finite element methods; Kinematics; Mechanical variables measurement; Microscopy; Microstructure; Optical fiber polarization; Optical fiber testing; Predictive models; Animals; Biocompatible Materials; Biomechanics; Biomedical Engineering; Cattle; Fibrillar Collagens; Finite Element Analysis; Gels; Models, Biological; Stress, Mechanical;

fLanguage

English

Journal_Title

Engineering in Medicine and Biology Magazine, IEEE

Publisher

ieee

ISSN

0739-5175

Type

jour

DOI

10.1109/MEMB.2009.932486

Filename

4939184