How
to deliver nitric oxide (NO) to a physiological target and
control its release quantitatively is a key issue for biomedical applications.
Here, a water-soluble nitrosylruthenium complex, [(CH3)4N][RuCl3(5cqn)(NO)] (H5cqn = 5-chloro-8-quinoline),
was synthesized, and its structure was confirmed with 1H NMR and X-ray crystal diffraction. Photoinduced NO release was
investigated with time-resolved Fourier transform infrared and electron
paramagnetic resonance (EPR) spectroscopies. The binding constant
of the [RuCl3(5cqn)(NO)]− complex with
human serum albumin (HSA) was determined by fluorescence spectroscopy,
and the binding mode was identified by X-ray crystallography of the
HSA and Ru-NO complex adduct. The crystal structure reveals that two
molecules of the Ru-NO complex are located in the subdomain IB, which
is one of the major drug binding regions of HSA. The chemical structures
of the Ru complexes were [RuCl3(5cqn)(NO)]− and [RuCl3(Glycerin)NO]−, in which
the electron densities for all ligands to Ru are unambiguously identified.
EPR spin-trapping data showed that photoirradiation triggered NO radical
generation from the HSA complex adduct. Moreover, the near-infrared
image of exogenous NO from the nitrosylruthenium complex in living
cells was observed using a NO-selective fluorescent probe. This study
provides a strategy to design an appropriate delivery system to transport
NO and metallodrugs in vivo for potential applications.
The structures and spectral properties of three ruthenium complexes with 8-hydroxyquinoline (Hhqn) and their derivatives 2-methyl-8-quinolinoline (H2mqn) and 2-chloro-8-quiolinoline (H2cqn) as ligands (QN = hqn, 2mqn, or 2cqn) were calculated with density functional theory (DFT) at the B3LYP level. The UV-Vis and IR spectra of the three [RuCl(QN)NO]− complexes were theoretically assigned via DFT calculations. The calculated spectra reasonably correspond to the experimentally measured spectra. Photoinduced NO release was confirmed through spin trapping of the electron paramagnetic resonance spectroscopy (EPR), and the dynamic process of the NO dissociation upon photoirradiation was monitored using time-resolved infrared (IR) spectroscopy. Moreover, the energy levels and related components of frontier orbitals were further analyzed to understand the electronic effects of the substituent groups at the 2nd position of the ligands on their photochemical reactivity. This study provides the basis for the design of NO donors with potential applications in photodynamic therapy.
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