Structural Regulation at Poly(ethylene glycol) Termini Facilitates the Formation of Injectable Hydrogels with Modulated Degradation and Release of Biomacromolecules

Hydrogels possessing modulated degradation and release behaviors are beneficial for the biological field. However, modulating the degradability and release behavior of a particular class of hydrogels requires a major structural alteration of a cross-linker as well as an adjustment in concentration, both of which affect the initial modulus and gelation kinetics. Herein, we address this shortcoming by a single step installation of a leaving nucleophile at the termini of PEG via the ether (O–CH2–Ph–, Cl′-PEG-Cl′) and ester (−Ph–COO–, Cl-PEG-Cl) spacers separately. These two PEG derivatives separately or in combination lead to the rapid formation of hydrogels when combined with a variety of macromolecules with tertiary amine functional group. The hydrogels exhibit a wide variation in degradation properties and time-dependent water swelling depending on the type and proportion of the PEG derivatives. The gelation kinetics is faster when the termini of the PEG derivative contain benzyl chloride groups connected through the ether spacer and is explained by density functional theory. Importantly, the ultimate moduli of the as prepared hydrogels are almost similar irrespective of the termini structure of the PEG derivatives and their proportion. The hydrogels exhibit modulated release profiles of model dextran and bovine serum albumin at pH 7.4. Prolonged delivery of biomacromolecules is achieved with the hydrogel prepared with Cl′-PEG-Cl′ or the combination Cl′-PEG-Cl′+Cl-PEG-Cl. More importantly, hydrogels prepared with Cl′-PEG-Cl′ or the Cl′-PEG-Cl′+Cl-PEG-Cl combination exhibit triggered release (60–100%) of a model protein (isoelectric point ≤ 7.4) and high molecular weight dextran (neutral) at a constant pH of 5 when compared to that at pH 7.4. The key advantages of our design are the access to a library of biological relevant hydrogels from easily available/synthesized amine-functional macromolecules and PEG derivatives with slight variations in the termini structures.