3D-Printed Protein-Based Bioplastics with Tunable Mechanical Properties Using Glycerol or Hyperbranched Poly(glycerol)s as Plasticizers.

Protein-based materials can be engineered to derive utility from the structures and functions of the incorporated proteins. Modern methods of protein engineering bring promise of unprecedented control over molecular and network design, which will enable new and improved functionalities in materials that incorporate proteins as functional building blocks. For these advantages to be fully realized, there is a need for robust methods for producing protein-based networks, as well as methods for tuning their mechanical properties. Light-based 3D-printing techniques afford high-resolution fabrication capability with unparalleled design freedom in an inexpensive and decentralized capacity. This work features 3D-printed serum albumin-based bioplastics with mechanical properties modulated through the incorporation of glycerol or hyperbranched poly(glycerol)s (HPGs) as plasticizers. These materials capitalize upon important features of serum albumin, including its low intrinsic viscosity, high aqueous solubility, and relatively low cost. The incorporation of glycerol or HPGs of different sizes resulted in softer and more ductile bioplastics than those obtained natively without additives. These bioplastics showed shape-memory behavior and could be used to fabricate functional objects. These materials are accessible, possess minimal chemical hazards, and can be used for fabricating rigid and strong as well as soft and ductile parts using inexpensive commercial 3D printers.