posted on 2020-09-11, 12:09authored byBruno Marco-Dufort, Jack Willi, Felipe Vielba-Gomez, Francesco Gatti, Mark W. Tibbitt
Moldable hydrogels composed of dynamic
covalent bonds are attractive
biomaterials for controlled release, as the dynamic exchange of bonds
in these networks enables minimally invasive application via injection.
Despite the growing interest in the biomedical application of dynamic
covalent hydrogels, there is a lack of fundamental understanding as
to how the network design and local environment control the release
of biomolecules from these materials. In this work, we fabricated
boronic-ester-based dynamic covalent hydrogels for the encapsulation
and in vitro release of a model biologic (β-galactosidase).
We systematically investigated the role of network properties and
of the external environment (temperature and presence of competitive
binders) on release from these dynamic covalent hydrogels. We observed
that surface erosion (and associated mass loss) governed biomolecule
release. In addition, we developed a statistical model of surface
erosion based on the binding equilibria in a boundary layer that described
the rates of release. In total, our results will guide the design
of dynamic covalent hydrogels as biomaterials for drug delivery applications.