Although
poly(ethylene glycol) (PEG) is commonly used in nanoparticle
design, the impact of surface topography on nanoparticle performance
in biomedical applications has received little attention, despite
showing significant promise in the study of inorganic nanoparticles.
Control of the surface topography of polymeric nanoparticles is a
formidable challenge due to the limited conformational control of
linear polymers that form the nanoparticle surface. In this work,
we establish a straightforward method to precisely tailor the surface
topography of PEGylated polymeric nanoparticles based on tuning the
architecture of shape-persistent amphiphilic bottlebrush block copolymer
(BBCP) building blocks. We demonstrate that nanoparticle formation
and surface topography can be controlled by systematically changing
the structural parameters of BBCP architecture. Furthermore, we reveal
that the surface topography of PEGylated nanoparticles significantly
affects their performance. In particular, the adsorption of a model
protein and the uptake into HeLa cells were closely correlated to
surface roughness and BBCP terminal PEG block brush width. Overall,
our work elucidates the importance of surface topography in nanoparticle
research as well as provides an approach to improve the performance
of PEGylated nanoparticles.
The efficient synthesis of complex functional polymeric nanomaterials is often challenging. Ru-initiated ring-opening metathesis polymerization (ROMP) of multivalent macromonomers followed by cross-linking to form brush-arm star (BASP) polymers enables access to well-defined nano-structures with diverse functionality. This “brush-first” method leaves active Ru in the BASP microgel core, which could potentially be used in a subsequent “ROMP-out” (RO) step to introduce further modifications to the BASP structure via the addition of (macro)monomers. Here, we study this RO approach in depth. The efficiency of RO is assessed for a variety of BASP compositions using a combination of inductively coupled plasma mass spectrometry and gel permeation chromatography. To demonstrate the modularity of the RO process, arylboronic acid-functionalized BASPs were prepared; uptake of these RO-BASPs into hypersialylated cancer cells was enhanced relative to non-functionalized BASPs as determined by flow cytometry and fluorescence microscopy. In addition, the self-assembly of miktoarm BASPs prepared via brush-first and RO with different macromonomers is demonstrated. The combination of brush-first ROMP with RO provides a simple, modular strategy for access to a wide array of functional nanomaterials.
An inhalable platform for messenger RNA (mRNA) therapeutics would enable minimally invasive and lung-targeted delivery for a host of pulmonary diseases. Development of lung-targeted mRNA therapeutics has been limited by poor transfection efficiency and risk of vehicle-induced pathology. Here, we report an inhalable polymer-based vehicle for delivery of therapeutic mRNAs to the lung. We optimized biodegradable poly(amine-
co
-ester) (PACE) polyplexes for mRNA delivery using end-group modifications and polyethylene glycol. These polyplexes achieved high transfection of mRNA throughout the lung, particularly in epithelial and antigen-presenting cells. We applied this technology to develop a mucosal vaccine for severe acute respiratory syndrome coronavirus 2 and found that intranasal vaccination with spike protein–encoding mRNA polyplexes induced potent cellular and humoral adaptive immunity and protected susceptible mice from lethal viral challenge. Together, these results demonstrate the translational potential of PACE polyplexes for therapeutic delivery of mRNA to the lungs.
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