In Situ Quantification of Surface Chemistry in Porous Collagen Biomaterials

Author(s)

Tzeranis, Dimitrios; Soller, Eric Charles; Buydash, Melissa Christine; So, Peter T. C.; Yannas, Ioannis V

Abstract

Cells inside a 3D matrix (such as tissue extracellular matrix or biomaterials) sense their insoluble environment through specific binding interactions between their adhesion receptors and ligands present on the matrix surface. Despite the critical role of the insoluble matrix in cell regulation, there exist no widely-applicable methods for quantifying the chemical stimuli provided by a matrix to cells. Here, we describe a general-purpose technique for quantifying in situ the density of ligands for specific cell adhesion receptors of interest on the surface of a 3D matrix. This paper improves significantly the accuracy of the procedure introduced in a previous publication by detailed marker characterization, optimized staining, and improved data interpretation. The optimized methodology is utilized to quantify the ligands of integrins α[subscript 1]β[subscript 1], α[subscript 2]β[subscript 1] on two kinds of matched porous collagen scaffolds, which are shown to possess significantly different ligand density, and significantly different ability to induce peripheral nerve regeneration in vivo. Data support the hypothesis that cell adhesion regulates contractile cell phenotypes, recently shown to be inversely related to organ regeneration. The technique provides a standardized way to quantify the surface chemistry of 3D matrices, and a means for introducing matrix effects in quantitative biological models.

Date issued

2015-09

URI

http://hdl.handle.net/1721.1/105254

Department

Massachusetts Institute of Technology. Department of Biological Engineering
Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Annals of Biomedical Engineering

Publisher

Springer US

Citation

Tzeranis, Dimitrios S. et al. “In Situ Quantification of Surface Chemistry in Porous Collagen Biomaterials.” Annals of Biomedical Engineering 44.3 (2016): 803–815.

Version: Author's final manuscript

ISSN

0090-6964

1573-9686