Stimuli-responsive hydrogels represent a promising class of inks for use in 3D-bioprinting. These materials respond to external stimuli such as heat, light, pH, and pressure, and researchers have utilized these different stimuli responses to develop inks for direct-write 3D printing. The objective of our work is to understand how the composition of poly(alkyl glycidyl ethers)--more specifically, allyl-, ethyl-, isopropyl, n-propyl-, and methyl-glycidyl ether homopolymers--affects their thermal response in aqueous solutions. UV-Vis Spectroscopy was used to determine the lower critical solution temperature (LCST) of each homopolymer, varying the molecular weight, concentration and polymer composition to demonstrate poly(alkyl glycidyl ethers) versatility as a platform for synthesis of stimuli-responsive hydrogels. We determined that the identity of the alkyl group significantly affected the temperature-response of the respective hydrogel. These studies will guide our work toward developing temperature and shear-responsive inks for 3D-bioprinting. In particular, these materials can be used to develop printed hydrogel lattices for whole-cell catalysis to produce medicinal compounds.