Electronic absorption, emission, and excitation spectra, and fluorescence lifetimes of two H1 antihistamines--tripelennamine and mepyramine--are investigated in detail to ascertain their usefulness as fluorescent probes for ligand binding to G-protein coupled receptors. The photophysical behavior of these compounds in aqueous solution is complex due to the presence of three protonable nitrogens, intramolecular hydrogen bonding, quenching due to the formation of a charge transfer state, and intramolecular fluorescence resonance energy transfer. At physiological pH values, anomalous photophysical behavior is observed: the compounds are found to be in a ground-state equilibrium mixture of two species, one with the alkylamine tail involved in an intramolecular hydrogen bond and a second without such a bond. This internal hydrogen-bonded tail has a profound effect on the ground and excited-state properties of both tripelennamine and mepyramine, which is further elucidated by comparing them to the reference compounds 2-aminopyridine and 2-(N,N-dimethylamino)pyridine.
Ultraviolet Resonance Raman (UVRR) spectroscopy -a Raman technique that combines high sensitivity with high selectivity and does not suffer from background fluorescence -is applied to the fluorescent H 1 antihistamines tripelennamine (TRP) and mepyramine (MEP) in aqueous solution to elucidate their molecular structure as a function of pH. In a previous investigation of these compounds (C. Tardioli, G. Gooijer G. van der Zwan, J. Phys. Chem. B, 113, (2009), 6949), the presence of gauche conformers caused by intramolecular interaction of the protonated alkylamine tail with the pyridine nitrogen was assumed to explain the pH dependence of the fluorescence properties. In order to validate this assumption, use is made of the resonant excitation of the aminopyridine chromophore in TRP and MEP. In that way, structural information associated with the vibrations of that moiety can be obtained, and the changes it undergoes upon protonation can be monitored. Assignment of the vibrations was achieved with the help of a number of other compounds, and quantum chemical calculations. N,N-Dimethylaminopyridine (2DMP) and its mono-protonated form (2DMPH + ) were investigated, since this molecule was shown to have optical properties closely resembling those of the aminopyridine moiety in TRP and MEP. Assignment of the vibrations of 2DMP was accomplished by comparison with the resonance Raman spectra of two other reference structures, 2-aminopyridine and dimethylaniline -for which ordinary Raman data are available -and by Gaussian calculations. UVRR spectra of TRP and MEP could be readily interpreted on the basis of vibrational assignments of the parent chromophores, i.e. 2DMP and 2DMPH + . Vibrations of the aminopyridine chromophore in TRP and MEP at neutral pH, where the aminoalkyl chain is protonated, are modified when compared to the vibrational pattern recorded for a fully neutral molecule in alkaline solution. This implies an electronic redistribution in the ring originating from internal hydrogen bonding between the aminoalkyl tail and the aminopyridine chromophore.
Binding of the antihistamine drug brompheniramine (BPA) to human serum albumin (HSA) is studied by measuring quenching of the fluorescence and room temperature phosphorescence (RTP) of tryptophan. The modified Stern-Volmer equation was used to derive association constants and accessible fractions from the steady-state fluorescence data. Decay associated spectra (DAS) revealed three tryptophan fluorescence lifetimes, indicating the presence of three HSA conformations. BPA causes mainly static quenching of the long-living, solvent-exposed conformer. RTP spectra and lifetimes, recorded under deoxygenated conditions in the presence of 0.2 M KI, provided additional kinetic information about the HSA-BPA interactions. Fluorescence DAS that were also recorded in the presence of 0.2 M KI revealed that the solvent-exposed conformer is the major contributor to the RTP signal. The phosphorescence quenching is mostly dynamic at pH 7 and mostly static at pH 9, presumably related to the protonation state of the alkylamino chain of BPA. This provides direct insight into the binding mode of the antihistamine drug, as well as kinetic information at both the nanosecond and the millisecond time scales.
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