In this study, we report detailed information on the internal structure of PNIPAM-b-PEG-b-PNIPAM nanoparticles formed from self-assembly in aqueous solutions upon increase in temperature. NMR spectroscopy, light scattering, and small-angle neutron scattering (SANS) were used to monitor different stages of nanoparticle formation as a function of temperature, providing insight into the fundamental processes involved. The presence of PEG in a copolymer structure significantly affects the formation of nanoparticles, making their transition to occur over a broader temperature range. The crucial parameter that controls the transition is the ratio of PEG/PNIPAM. For pure PNIPAM, the transition is sharp; the higher the PEG/PNIPAM ratio results in a broader transition. This behavior is explained by different mechanisms of PNIPAM block incorporation during nanoparticle formation at different PEG/PNIPAM ratios. Contrast variation experiments using SANS show that the structure of nanoparticles above cloud point temperatures for PNIPAM-b-PEG-b-PNIPAM copolymers is drastically different from the structure of PNIPAM mesoglobules. In contrast with pure PNIPAM mesoglobules, where solidlike particles and chain network with a mesh size of 1-3 nm are present, nanoparticles formed from PNIPAM-b-PEG-b-PNIPAM copolymers have nonuniform structure with "frozen" areas interconnected by single chains in Gaussian conformation. SANS data with deuterated "invisible" PEG blocks imply that PEG is uniformly distributed inside of a nanoparticle. It is kinetically flexible PEG blocks which affect the nanoparticle formation by prevention of PNIPAM microphase separation.
Since the time of Faraday’s experiments, the optical response of plasmonic nanofluids has been tailored by the shape, size, concentration, and material of nanoparticles (NPs), or by mixing different types...
Fluorine-19
magnetic resonance imaging (19F MRI) enables
detailed in vivo tracking of fluorine-containing
tracers and is therefore becoming a particularly useful tool in noninvasive
medical imaging. In previous studies, we introduced biocompatible
polymers based on the hydrophilic monomer N-(2-hydroxypropyl)methacrylamide
(HPMA) and the thermoresponsive monomer N-(2,2-difluoroethyl)acrylamide
(DFEA). These polymers have abundant magnetically equivalent fluorine
atoms and advantageous properties as 19F MRI tracers. Furthermore,
in this pilot study, we modified these polymers by introducing a redox-responsive
monomer. As a result, our polymers changed their physicochemical properties
once exposed to an oxidative environment. Reactive oxygen species
(ROS)-responsive polymers were prepared by incorporating small amounts
(0.9–4.5 mol %) of the N-[2-(ferrocenylcarboxamido)ethyl]acrylamide
(FcCEA) monomer, which is hydrophobic and diamagnetic in the reduced
electroneutral (Fe(II), ferrocene) state but hydrophilic and paramagnetic
in the oxidized (Fe(III), ferrocenium cation) state. This property
can be useful for theranostic purposes (therapy and diagnostic purposes),
especially, in terms of ROS-responsive drug-delivery systems. In the
reduced state, these nanoparticles remain self-assembled with the
encapsulated drug but release the drug upon oxidation in ROS-rich
tumors or inflamed tissues.
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