Diels–Alder hydrogels with enhanced stability: First step toward controlled release of bevacizumab

Abstract

Eight-armed PEG was functionalized with furyl and maleimide groups (8armPEG20k-Fur and 8armPEG20k-Mal); degradable hydrogels were obtained by cross-linking via Diels–Alder chemistry. To increase the stability to degradation, the macromonomers were modified by introducing a hydrophobic 6-aminohexanoic acid spacer between PEG and the reactive end-groups (8armPEG20k-Ahx-Fur and 8armPEG20k-Ahx-Mal). In an alternative approach, the number of reactive groups per macromonomer was increased by branching the terminal ends of eight-armed PEG with lysine (Lys) and Ahx residues (8armPEG20k-Lys-Ahx-Fur2 and 8armPEG20k-Lys-Ahx-Mal2). The hydrolytic resistance of the synthesized macromonomers was determined by UV spectroscopy; the obtained hydrogels were characterized by rheology and degradation studies. The degradation time of 5% (w/v) 8armPEG20k-Ahx hydrogels (28days) was twice as long as the degradation time of 5% (w/v) 8armPEG20k hydrogels (14days); this is explained by increased hydrolytic resistance of the maleimide group. Using dendritic 8armPEG20k-Lys-Ahx macromonomers substantially increased the stability of the resulting hydrogels; degradation of 5% (w/v) 8armPEG20k-Lys-Ahx hydrogels occurred after 34weeks. 8armPEG20k hydrogels had the largest mesh size of all tested hydrogels, while hydrogels made from dendritic 8armPEG20k-Lys-Ahx macromonomers showed the smallest value. To evaluate their potential for the controlled release of therapeutic antibodies, the hydrogels were loaded with bevacizumab. The incorporated bevacizumab was released over 10days (8armPEG20k) and 42days (8armPEG20k-Ahx), respectively; release from 8armPEG20k-Lys-Ahx hydrogels was not completed after 105days. In summary, we believe that 8armPEG20k-Ahx or 8armPEG20k-Lys-Ahx hydrogels could serve as controlled release system for therapeutic antibodies such as bevacizumab.