Issue 40, 2015

Designer hydrogels for precision control of oxygen tension and mechanical properties

Abstract

Oxygen levels and mechanical properties provide vital cues to regulate myriad cellular functions and stem cell fate decisions. Here, we present a hybrid hydrogel system in which we can control independently oxygen levels and mechanical properties. We designed, synthesized and analyzed a hybrid hydrogel system comprised of two polymer backbones, gelatin and dextran. Both polymers were crosslinked via a laccase-mediated, oxygen consuming reaction. By specifically controlling the concentration of phenolic molecules available to react in our hydrogel, we could precisely control the time in which the hydrogel remained hypoxic (TH). We were able to achieve a range of TH from the order of minutes to greater than 10 hours. Additionally, by incorporating a secondary crosslinker, transglutaminase, mechanical properties could be adjusted in a user-defined fashion, with dynamic elastic modulus (G′) values ranging from <20 Pa to >1 kPa. Importantly, oxygen levels and substrate mechanical properties could be individually tuned and decoupled in our hybrid hydrogels, while retaining the potential to study possible synergistic effects between the two parameters. By precisely controlling oxygen tension and mechanical properties, we expect that research utilizing the new hybrid hydrogels will enhance our understanding of the complex 3D cellular processes mediated by each parameter individually and may also hold clinical interest as acellular therapies.

Graphical abstract: Designer hydrogels for precision control of oxygen tension and mechanical properties

Article information

Article type
Paper
Submitted
29 may. 2015
Accepted
05 ago. 2015
First published
05 ago. 2015

J. Mater. Chem. B, 2015,3, 7939-7949

Author version available

Designer hydrogels for precision control of oxygen tension and mechanical properties

M. Blatchley, K. M. Park and S. Gerecht, J. Mater. Chem. B, 2015, 3, 7939 DOI: 10.1039/C5TB01038A

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