Light-induced tailoring of PEG-hydrogel properties

Abstract

We have previously reported (Andreopoulos et al. J Am Chem Soc 118 (1996) 6235–6240) the synthesis of hydrogels via the photopolymerization of water-soluble PEG molecules. In this paper, PEG-hydrogel membranes were prepared by the irradiation (>300 nm) of aqueous solutions of photosensitive 4-armed PEG (nominal molecular weight of 20 000), in the absence of photoinitiators. The hydroxyl termini of the PEG’s were functionalized with cinnamylidene acetate groups to form photosensitive PEG macromers (PEG-CA), which upon irradiation (>300 nm) formed crosslinks between adjacent cinnamylidene groups resulting in highly crosslinked networks (hydrogels) (Andreopoulos et al. J Am Chem Soc 118 (1996) 6235–6240). The hydrogel membranes were highly swellable with equilibrium volume fractions ranging from 0.02 to 0.05. Their swellability was a function of irradiation light (>300 nm) and degree of modification of the PEG molecules. The effect of light on the permeation fluxes of myoglobin (Mb), hemoglobin (Hb), and lactate dehydrogenase-L (LDH) through PEG membranes was also assessed and the diffusion coefficients of the proteins were determined accordingly. The PEG-CA membranes exhibited photoscissive behavior upon exposure to UV irradiation (254 nm). Therefore, UV light was used as a trigger to control the mesh size of the membranes, and thereby the permeation fluxes of Mb, Hb, and LDH. Equilibrium swelling experiments with membranes prepared under different irradiation conditions were performed, and the Flory–Huggins model was utilized to determine the mesh size and the average molecular weight between crosslinks of the synthesized hydrogels.