The effect of Fe ion concentration on the morphological, structural, and optical properties of TiO2 films supported on silica (SiO2) opals has been studied. TiO2:Fe2O3 films were prepared by the sol-gel method in combination with a vertical dip coating procedure; precursor solutions of Ti and Fe were deposited on a monolayer of SiO2 opals previously deposited on a glass substrate by the same procedure. After the dip coating process has been carried out, the samples were thermally treated to obtain the TiO2:Fe2O3/SiO2 composites at the Fe ion concentrations of 1, 3, and 5 wt%. Scanning electron microscopy (SEM) micrographs show the formation of colloidal silica microspheres of about 50 nm diameter autoensembled in a hexagonal close-packed fashion. Although the X-ray diffractograms show no significant effect of Fe ion concentration on the crystal structure of TiO2, the μ-Raman and reflectance spectra do show that the intensity of a phonon vibration mode and the energy bandgap of TiO2 decrease as the Fe+3 ion concentration increases.
Curcumin is a promising natural drug in cancer therapy. However, its therapeutic applicability is limited by its low solubility, short half‐life, and low bioavailability. In this work curcumin is encapsulated in stimuli‐responsive magneto‐polymeric nanoplatforms aiming at improving its bioavailability and efficiency for delivery in biological media. MnFe2O4 magnetic nanoparticles (MNPs) were synthesized via thermal decomposition, coated with sodium citrate and then functionalized with multilayers of chitosan and sodium alginate, by means of the layer‐by‐layer deposition technique. A mesoporous polymeric‐magnetic nanoplatform was produced capable of a controlled and sustained release of curcumin under temperature, pH and alternating magnetic field (magnetic hyperthermia) stimuli. As the temperature and pH of the medium increased, an increase in the rate of curcumin release was observed in a two‐stage process, following the Gallagher‐Corrigan mathematical model. The use of magnetic hyperthermia resulted in a faster diffusion‐based release of curcumin. Increasing the number of polymer layers assembled on top of MNPs hinders the release of the curcumin molecules from innermost regions of the multilayers. These results show that magnetic hyperthermia provides a means for the controlled heat‐induced release of curcumin, which can lead to an enhanced therapeutic action for curcumin.
In this work, we describe the preparation
and characterization
of highly magnetizable chloromethylated polystyrene-based nanocomposite
beads. For synthesis optimization, acid-resistant core–shelled
maghemite (γ-Fe
2
O
3
) nanoparticles are
coated with sodium oleate and directly incorporated into the organic
medium during a suspension polymerization process. A crosslinking
agent, ethylene glycol dimethacrylate, is used for copolymerization
with 4-vinylbenzyl chloride to increase the resistance of the microbeads
against leaching. X-ray diffraction, inductively coupled plasma atomic
emission spectroscopy, thermogravimetric analysis, scanning electron
microscopy, transmission electron microscopy, and optical microscopy
are used for bead characterization. The beads form a magnetic composite
consisting of ∼500 nm-sized crosslinked polymeric microspheres,
embedding ∼8 nm γ-Fe
2
O
3
nanoparticles.
This nanocomposite shows large room temperature magnetization (∼24
emu/g) due to the high content of maghemite (∼45 wt %) and
resistance against leaching even in acidic media. Moreover, the presence
of superficial chloromethyl groups is probed by Fourier transform
infrared and X-ray photoelectron spectroscopy. The nanocomposite beads
displaying chloromethyl groups can be used to selectively remove aminated
compounds that are adsorbed on the beads, as is shown here for the
molecular separation of 4-aminobenzoic acid from a mixture with benzoic
acid. The high magnetization of the composite beads makes them suitable
for in situ molecular separations in environmental and biological
applications.
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