Your search keyword '"Robinson, J. Paul"' showing total 2 results

1. Local, three-dimensional strain measurements within largely deformed extracellular matrix constructs

Author

Roeder, Blayne A., Kokini, Klod, Robinson, J. Paul, and Voytik-Harbin, Sherry L.

Subjects

Tissues -- Research, Extracellular matrix -- Research, Biomechanics -- Research, Algorithms, Algorithm, Engineering and manufacturing industries, Science and technology

Abstract

The ability to create extracellular matrix (ECM) constructs that are mechanically and biochemically similar to those found in vivo and to understand how their properties affect cellular responses will drive the next generation of tissue engineering strategies. To date, many mechanisms by which cells biochemically communicate with the ECM are known. However, the mechanisms by which mechanical information is transmitted between cells and their ECM remain to be elucidated. ''Self-assembled' collagen matrices provide an in vitro-model system to study the mechanical behavior of ECM. To begin to understand how the ECM and the cells interact mechanically, the three-dimensional (3D) mechanical properties of the ECM must be quantified at the micro-(local) level in addition to information measured at the macro-(global) level. Here we describe an incremental digital volume correlation (IDVC) algorithm to quantify large (>0.05) 3D mechanical strains in the microstructure of 3D collagen matrices in response to applied mechanical loads. Strain measurements from the 1DVC algorithm rely on 3D confocal images acquired from collagen matrices under applied mechanical loads. The accuracy and the precision of the IDVC algorithm was verified by comparing both image volumes collected in succession when no deformation was applied to the ECM (zero strain) and image volumes to which simulated deformations were applied in both 1D and 3D (simulated strains). Results indicate that the IDVC algorithm can accurately and precisely determine the 3D strain state inside largely deformed collagen ECMs. Finally, the usefulness of the algorithm was demonstrated by measuring the microlevel 3D strain response of a collagen ECM loaded in tension. Keywords: Extracellular Matrix, Large-Strain, Three-Dimensional, Collagen Fibrils, Biomechanics, Digital Volume Correlation, Digital Image Processing

Published

2004

2. Tensile mechanical properties of three-dimensional type I collagen extracellular matrices with varied microstructure

Author

Roeder, Blayne A., Kokini, Klod, Stargis, Jennifer E., Robinson, J. Paul, and Harbin-Voytik, Sherry L.

Subjects

Collagen -- Testing, Tissue engineering -- Methods, Engineering and manufacturing industries, Science and technology

Abstract

The importance and priority of specific micro-structural and mechanical design parameters must be established to effectively engineer scaffolds (biomaterials) that mimic the extracellular matrix (ECM) environment of cells and have clinical applications as tissue substitutes. In this study, three-dimensional (3-D) matrices were prepared from type I collagen, the predominant compositional and structural component of connective tissue ECMs, and structural-mechanical relationships were studied. Polymerization conditions, including collagen concentration (0.3-3 mg/mL) and pH (6-9), were varied to obtain matrices of collagen fibrils with different microstructures. Confocal reflection microscopy was used to assess specific micro-structural features (e.g., diameter and length) and organization of component fibrils in 3-D. Microstructural analyses revealed that changes in collagen concentration affected fibril density while maintaining a relatively constant fibril diameter. On the other hand, both fibril length and diameter were affected by the pH of the polymerization reaction. Mechanically, all matrices exhibited a similar stress-strain curve with identifiable 'toe,' 'linear,' and 'failure' regions. However, the linear modulus and failure stress increased with collagen concentration and were correlated with an increase in fibril density. Additionally, both the linear modulus and failure stress showed an increase with pH, which was related to an increased fibril length and a decreased fibril diameter. The tensile mechanical properties of the collagen matrices also showed strain rate dependence. Such fundamental information regarding the 3-D microstructural-mechanical properties of the ECM and its component molecules are important to our overall understanding of cell-ECM interactions (e.g., mechanotransduction) and the development of novel strategies for tissue repair and replacement. [DOI: 10.1115/1.1449904] Keywords: Collagen, Extracellular Matrix, Three-Dimensional, Microstructure, Confocal Reflection Microscopy, Mechanical Properties

Published

2002