A folic
acid (FA) functional drug delivery system (MT@L-PTX@FA)
based on in situ formation of tellurium nanodots (Te NDs) in paclitaxel
(PTX)-loaded MgAl layered double hydroxide (LDHs) gated mesoporous
silica nanoparticles (MSNs) has been designed and fabricated for targeted
chemo/PDT/PTT trimode combinatorial therapy. X-ray diffraction (XRD),
X-ray photoelectron spectroscopy (XPS), scanning electron microscopy
(SEM), high-resolution transmission electron microscopy (HRTEM), N2 adsorption–desorption, Fourier transform infrared
(FT-IR) spectra, and UV–vis spectra were used to demonstrate
the successful fabrication of MT@L-PTX@FA. In particular, the in situ
generated Te NDs showed a homogeneous ultrasmall size. Reactive oxygen
species (ROS) generation, photothermal effects, and photostability
evaluations indicated that the in situ generated homogeneous Te NDs
could serve as the phototherapeutic agent, converting the photon energy
to ROS and heat under near-infrared (NIR) irradiation efficiently.
The drug-release test revealed that MT@L-PTX@FA showed an apparent
sustained release character in a pH-sensitive manner. In addition,
cell imaging experiments demonstrated that MT@L-PTX@FA could selectively
enter into cancer cells owing to the function of FA and release of
PTX efficiently for chemotherapy for the reason that the low intracellular
pH would dissolve MgAl LDHs to Mg2+ and Al3+. Cytotoxicity tests also indicated that MT@L-PTX@FA exhibited enhanced
therapeutic effect in cancer cells under NIR irradiation, benefiting
from the synergy based on targeted chemo/PDT/PTT trimode combinatorial
therapy. The preliminary results reported here will shed new light
on the future design and applications of nanosystems for synergistic
combinatorial therapy.
Background: Biodegradation of toxic organic dye using nanomaterial-based microbial biocatalyst is an ecofriendly and promising technique. Materials and Methods: Here, we have investigated the novel properties of functionalized Au-Ag bimetallic nanoparticles using extremophilic Deinococcus radiodurans proteins (Drp-Au-AgNPs) and their degradation efficiency on the toxic triphenylmethane dye malachite green (MG). Results and Discussion: The prepared Drp-Au-AgNPs with an average particle size of 149.8 nm were capped by proteins through groups including hydroxyl and amide. Drp-Au-AgNPs demonstrated greater degradation ability (83.68%) of MG than D. radiodurans cells and monometallic AuNPs. The major degradation product was identified as 4-(dimethylamino) benzophenone, which is less toxic than MG. The degradation of MG was mainly attributed to the capping proteins on Drp-Au-AgNPs. The bimetallic NPs could be reused and maintained MG degradation ability (>64%) after 2 cycles. Conclusion: These results suggest that the easily prepared Drp-Au-AgNPs have potential applications as novel nanomedicine for MG detoxification, and nanomaterial for biotreatment of a toxic polyphenyl dye-containing wastewater.
A screened waveguide with a 90° elbow, which had a rubber surface to reduce noise generations and a steel/air interface to block noise propagations, was designed to measure local particle movements in certain directions. In the riser of circulating fluidized bed, the noise energy only accounted for 2.1% of the total energy received by the waveguide. Besides, the radial acoustic emission energy distribution detected via the waveguide was highly consistent with the radial solid flux distribution measured by the extraction probe. Furthermore, the radial flow patterns in the riser with Geldart D particles were measured under dense phase conveying by this new method, which always demonstrated as core‐annulus flows and the transition points (r/R) increased with decreasing solid–gas ratios.
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