This feature article covers the recent applications of metal‐organic framework nanoparticles (MOF NPs) in photodynamic therapy (PDT) of cancer. It aims at giving the reader an overview about these two current research fields, i.e., MOF and PDT, and at highlighting the potential synergistic effect that could result from their association. After describing the general photophysics and photochemistry that underlie PDT, the relationship between photosensitizer (PS) properties and PDT requirements is discussed throughout the PSs historical development. This development reveals the advantages of using nanotechnology platforms for the creation of the ideal PS and leads us to define the fourth generation of PSs, which includes NPs built from the PS itself as porphysomes or PS‐based MOF NPs. Especially, the precise spatial control over the PS assembly into well‐defined MOF NPs, which keeps the PS in its monomeric form and prevents PS self‐quenching, appears as a notable feature to solve PS solubility and aggregation issues and therefore improves the PDT efficiency. Finally, we discuss the future perspectives of MOF NPs in PDT and shed light on how promising these nanomaterials are.
Two-color sum-frequency generation spectroscopy (2C-SFG) is used to probe the molecular and electronic properties of an adsorbed layer of the green fluorescent protein mutant 2 (GFPmut2) on a platinum (111) substrate. First, the spectroscopic measurements, performed under different polarization combinations, and atomic force microscopy (AFM) show that the GFPmut2 proteins form a fairly ordered monolayer on the platinum surface. Next, the nonlinear spectroscopic data provide evidence of particular coupling phenomena between the GFPmut2 vibrational and electronic properties. This is revealed by the occurrence of two doubly resonant sum-frequency generation processes for molecules having both their Raman and infrared transition moments in a direction perpendicular to the sample plane. Finally, our 2C-SFG analysis reveals two electronic transitions corresponding to the absorption and fluorescence energy levels which are related to two different GFPmut2 conformations: the B (anionic) and I forms, respectively. Their observation and wavelength positions attest the keeping of the GFPmut2 electronic properties upon adsorption on the metallic surface.
We show that sum-frequency generation spectroscopy performed in the total internal
reflection configuration (TIR–SFG) combined with a dense gold nanoparticles monolayer
allows us to study, with an excellent signal to noise ratio and high signal to background
ratio, the conformation of adsorbed molecules. Dodecanethiol (DDT) was used as probe
molecules in order to assess the potentialities of the approach. An enhancement of more
than one order of magnitude of the SFG signals arising from the adsorbed species is
observed with the TIR geometry compared to the external reflection one while
the SFG non-resonant contribution remains the same for both configurations.
Although further work is required to fully understand the origin of the SFG process
on nanoparticles, our work opens new possibilities for studying nanostructures.
Within semiconductor quantum dots (QDs), exciton recombination processes are noteworthy for depending on the nature of surface coordination and nanocrystal/ligand bonding. The influence of the molecular surroundings on QDs optoelectronic properties is therefore intensively studied. Here, from the converse point of view, we analyse and model the influence of QDs optoelectronic properties on their ligands. As revealed by sum-frequency generation spectroscopy, the vibrational structure of ligands is critically correlated to QDs electronic structure when these are pumped into their excitonic states. Given the different hypotheses commonly put forward, such a correlation is expected to derive from either a direct overlap between the electronic wavefunctions, a charge transfer, or an energy transfer. Assuming that the polarizability of ligands is subordinate to the local electric field induced by excitons through dipolar interaction, our classical model based on nonlinear optics unambiguously supports the latter hypothesis.
Highly
efficient and chemoselective singlet oxygen oxidation of
unprotected methionine was performed in water using a continuous mesofluidic
reactor. Sustainable process engineering and conditions were combined
to maximize process efficiency and atom economy, with virtually no
waste generation and safe operating conditions. Three water-soluble
metal-free photosensitizers [Rose Bengal, Methylene Blue, and tetrakis(4-carboxyphenyl)porphyrin]
were assessed. The best results were obtained with Rose Bengal (0.1
mol %) at room temperature under white light irradiation and a slight
excess of oxygen. Process and reaction parameters were monitored in
real-time with in-line NMR. Other classical organic substrates (α-terpinene
and citronellol) were oxidized under similar conditions with excellent
performances.
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