Abstract
AbstractThe field of engineered living materials (ELMs) seeks to pair living organisms with synthetic materials to generate biocomposite materials with augmented function since living systems can provide highly-programmable and complex behavior. ELMs have typically been fabricated using techniques in benign aqueous environments, limiting their application. In this work, biocomposite fabrication was demonstrated in which spores from polymer-degrading bacteria were incorporated into a thermoplastic polyurethane (TPU) using high-temperature melt processing. Bacteria were engineered using adaptive laboratory evolution to improve their heat tolerance to ensure nearly complete cell survivability during manufacturing at 135 °C. Furthermore, the overall tensile properties of spore-filled TPUs were substantially improved, resulting in a significant improvement in toughness. The biocomposites facilitated disintegration in compost in the absence of a microbe-rich environment. Finally, spores retained a programmed function, expressing green fluorescent protein. This research provides a scalable method to fabricate advanced biocomposite materials in industrially-compatible processes.
Publisher
Cold Spring Harbor Laboratory