posted on 2021-10-29, 09:04authored byChan-Jin Kim, Francesca Ercole, Yi Ju, Shuaijun Pan, Jingqu Chen, Yijiao Qu, John F. Quinn, Frank Caruso
Metal–phenolic
networks (MPNs), formed through coordination
bonding between phenolic molecules and metal ions, are a promising
class of materials for engineering particle systems for diverse applications.
However, the properties of such MPNs are inherently restricted due
to the finite properties of naturally occurring phenolic molecules.
Herein, we report a simple and robust approach to incorporate phenolic
moieties into polymers, thereby providing customizable phenolic ligand
building blocks that can be used to assemble capsules with a range
of tailorable properties. The phenolic ligand building blocks were
synthesized via carbonic anhydride coupling to terminal amines, a
conjugation approach typically used for peptide coupling but applied
herein for functionalizing polymers. The chemistry enabled optimized
end-group purity, thus affording a robust and efficient strategy to
generate a library of macromolecular poly(ethylene glycol) (PEG) catechol
building blocks with different architectures (i.e., 2-, 4-, and 8-arm)
and molecular weights (from 2.5 to 20 kDa). The resulting phenolic
building blocks were applied to fabricate capsules with shell thickness,
permeability, and cell association properties that were controlled
via the variation of the macromolecular catechol architecture and
molecular weight. Specifically, the shell thickness was varied more
than 19-fold (i.e., between ∼9 and 169 nm) by judicious selection
of the polymer molecular weight, arm number, and template. Similarly,
the permeability of the resulting MPN capsules to 500 kDa dextran
was tuned from >90 to <5% by varying the number of arms in the
polymer structure while maintaining a constant PEG Mn-to-catechol group ratio. Furthermore, the cell association
was reduced by a factor of 2.5 by employing 20 kDa 8-arm PEG instead
of 2.5 kDa 2-arm PEG during film assembly. These results demonstrate
that the applied macromolecular conjugation approach can be used to
customize particle properties, potentially facilitating applications
in therapeutic delivery, imaging, separations, and catalysis.