posted on 2019-10-18, 16:04authored byStephen
E. Miller, Yuji Yamada, Nimit Patel, Ernesto Suárez, Caroline Andrews, Steven Tau, Brian T. Luke, Raul E. Cachau, Joel P. Schneider
Protein
biologics are an important class of drugs, but the necessity
for frequent parenteral administration is a major limitation. Drug-delivery
materials offer a potential solution, but protein-material adsorption
can cause denaturation, which reduces their effectiveness. Here, we
describe a new protein delivery platform that limits direct contact
between globular protein domains and material matrix, yet from a single
subcutaneous administration can be tuned for long-term drug release.
The strategy utilizes complementary electrostatic interactions made
between a suite of designed interaction domains (IDs), installed onto
the terminus of a protein of interest, and a negatively charged self-assembled
fibrillar hydrogel. These intermolecular interactions can be easily
modulated by choice of ID to control material interaction and desorption
energies, which allows regulation of protein release kinetics to fit
desired release profiles. Molecular dynamics studies provided a molecular-level
understanding of the mechanisms that govern release and identified
optimal binding zones on the gel fibrils that facilitate strong ID–material
interactions, which are crucial for sustained release of protein.
This delivery platform can be easily loaded with cargo, is shear-thin
syringe implantable, provides improved protein stability, is capable
of a diverse range of in vitro release rates, and most importantly,
can accomplish long-term control over in vivo protein delivery.