Bifunctional Proteinaceous Hydrogels for Bioelectrocatalysis
Self-assembly is an essential process for all forms of life. For example, proteins spontaneously fold into well-defined 3-dimensional structures, and cellular organelles form that spatially segregate diverse cellular processes. As engineers aim to create new devices and systems at ever decreasing size scales, self-assembly processes become increasingly attractive techniques.
We are interested in using protein self-assembly in bioelectrocatalytic applications including biofuel cells and biosensors. In these devices it is critical to have a high loading of enzymes on the electrode and to address transport issues including electrical communication with the electrode and substrate and product transport to and from the enzyme.
We have developed a technology where self-assembly domains are genetically appended to globular proteins and this enables the proteins to self-assemble into bifunctional hydrogels. We have performed this modification on over a dozen different proteins and in all cases the proteins retain their biological function (activity) while gaining the ability to form a biomaterial. We have demonstrated the use of these materials as electrode modifications for biofuel cells and biosensors. We are continuing to develop this approach to make catalytic biomaterials for additional applications.
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