(601a) Polymer Platforms for 3D Printing Engineered Living Materials

The convergence of synthetic biology with polymer science has led to the rapid emergence of engineered living materials (ELMs), which are composite materials of engineered cells encapsulated within a polymeric matrix. ELMs have the potential to attain a level of precision, control, and sustainability that is not achieved with traditional abiotic materials. While the minimum requirements for fully living ELMs are cell viability and metabolic activity, the integration of ELMs at their fullest potential in future biomanufacturing also requires processing into desired form factors and spatial control over multiple engineered cell populations.

Additive manufacturing (or 3D printing) has re-emerged into the spotlight in the last 10 years driven by the rapid progress in hardware and software. While off-the-shelf polymeric materials have been utilized as inks and resins for additive manufacturing, there is still a need to develop functional materials that are specifically designed for these processes. In this seminar, I will present two different polymer platforms that we have developed to 3D print ELMs. In the first part of my seminar, I will discuss the development of stimuli-responsive triblock copolymer hydrogels for fabricating immobilized cell bioreactors. These hydrogels were used to incorporate engineered microbes that served as cellular factories for the on-demand bio-production of chemical products. In the second part of my seminar, I will discuss a two-step additive manufacturing process to fabricate protein-based constructs using a commercially available laser-scanning SLA printer. Methacrylated bovine serum albumin (MA-BSA) was synthesized and formulated into aqueous resins that was used to print complex 3D geometrical constructs with a resolution comparable to a commercially available resin. Compression studies of hydrated and dehydrated constructs demonstrated a broad range of compressive strengths and Young’s moduli that could be further modulated by adjusting the type and amount of co-monomer. These protein-based matrices served as biodegradable scaffolds for 3D printing ELMs, and I will present strategies for fabricating bio-augmented and bio-sustained ELMs.