An efficient method for the synthesis of dibenzofuran from o-iododiaryl ether using reusable Pd/C under ligand-free conditions has been developed. Synthesis of o-iododiaryl ether was achieved in one pot through sequential iodination and O-arylation of phenol under mild reaction conditions.
Silver-mediated annulation of 2-iodo enol esters leading to 4- and 3,4-substituted isocoumarins was accomplished selectively at room temperature. Coupling of 2-iodo benzoic acids with enolates that were produced in situ from the simple esters was also performed to produce isocoumarins under analogous reaction conditions. Owing to the mildness of the current protocol, 4-acyl 3-substituted isocoumarins were efficiently produced without any deacylation.
In
an attempt to integrate photodynamic therapy (PDT) with photothermal
therapy and chemotherapy for enhanced anticancer activity, we have
rationally synthesized a multifunctional upconversion nanoplatform
using NaYF4:Yb/Tm/Er/Fe nanoparticles (NPs) as the core
and NaYbF4:1% Tm as a shell. The as-synthesized core–shell
upconversion (CSU) NPs exhibited diverse and enhanced photoluminescence
emissions in a wide range (UV to NIR) consequent upon Fe3+ doping in the core and fabrication of an active shell. Subsequently,
CSU was first decorated with titania NPs as photosensitizers. Next,
the mesoporous silica (MS) shell loaded with doxorubicin (DOX) via
a photocleavable Ru complex as the gating molecule was developed around
titania-containing CSU. Finally, gold nanorods (GNRs) with localized
surface plasmon resonance (LSPR) at 800 nm were incorporated around
the MS layer to obtain the multifunctional nanoplatform. We demonstrated
that the UV, blue, and NIR emissions from the CSU produced ROS-mediated
PDT through titania activation, induced DOX release through photocleavage
of the Ru complex, and generated hyperthermia by LSPR activity of
GNRs, respectively, upon a single NIR excitation through FRET. The
therapeutic efficacy was validated on HeLa cell lines in vitro by
various microscopic and biochemical studies under a significantly
milder NIR irradiation and lower dosage of the nanoplatforms, which
have been further demonstrated as diagnostic nanoprobes for cell imaging.
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