Fluorescence Anisotropy in Radachlorin and Chlorin e6 in Water–Methanol Solutions under One- and Two-Photon Excitation

Abstract

The fluorescence anisotropy of photosensitizers Radachlorin and chlorin e6 was studied using the time-resolved single photon-counting technique under one- and two-photon excitation within the Soret absorption band. A very small negative anisotropy was observed in both photosensitizers under one-photon excitation in the vicinity of the absorption maximum within the wavelength range of 395–405 nm. Meanwhile, two-photon excitation of the photosensitizers in the same spectral range demonstrated high fluorescence anisotropy with the maximum value of about 0.43. The drastic difference of the fluorescence anisotropy parameters at one- and two-photon excitation modes was suggested to be due to the different symmetries of one- and two-photon absorption tensors when two-photon absorption tensor components have comparable values. The variation of excitation wavelengths in the spectral range of 375–425 nm demonstrated nonlinear wavelength dependence of anisotropy of both Radachlorin and chlorin e6, with opposite tendencies at one- and two-photon excitation. The data obtained suggest that one-photon excitation at about 405 nm often utilized in FLIM experiments is not sensitive to fluorescence anisotropy in Radachlorin and chlorin e6 and therefore cannot be used for the determination of anisotropy/rotational diffusion time in these molecules. Meanwhile, two-photon excitation can provide high fluorescence anisotropy and accurate determination of the rotational diffusion time. At the same time, one-photon excitation at about 405 nm can be used for the accurate evaluation of fluorescence lifetimes within the standard FLIM schematic where fluorescence polarization is not taken into account.