Engineering Silk-based Materials into Living

Abstract

Biological systems have developed Water-Responsive (WR) actuators that can adapt to the surrounding environment and power their essential tasks. These WR actuators that mechanically swell and shrink in response to changes in Relative Humidity (RH) can have significantly higher energy and power densities over existing actuators and artificial muscles. Despite the great potential of using these biological WR materials as efficient and powerful actuators, mimicking their properties and integrating them into modern engineering systems remains a challenge. This proposal’s goal is to examine the fundamental behavior of living WR biomaterials that self-adapt to external loads. Our approach couples two biomaterials, Bacillus (B.) spores and silk fibroin proteins. Using this approach, we can simultaneously deepen our understanding of water transport and confinement in biomolecular systems and engineer robust new living biocomposites. Our experimental plan has three aims 1) examine silk fibroin’s WR properties, 2) investigate interfacial interactions between spores and silk to engineer biocomposites, and 3) create living WR muscles for dynamic control over actuation. Our proposed work could not only lead to actuators with high energy and power densities, but we believe that the outcomes will enable new opportunities to integrate living components into active systems.

Document Details

Document Type

DoD Grant Award

Publication Date

Mar 07, 2023

Source ID

FA95502110144

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