Introduction: Advanced multiphoton and fluorescence lifetime imaging techniques

## Abstract In vivo and in vitro multiphoton imaging was used to perform high resolution optical sectioning of human hair by nonlinear excitation of endogenous as well as exogenous fluorophores. Multiphoton fluorescence lifetime imaging (FLIM) based on time‐resolved single photon counting and near‐

## Abstract Long‐term high‐resolution multiphoton imaging of nonlabeled human salivary gland stem cell spheroids has been performed with submicron spatial resolution, 10.5‐nm spectral resolution, and picosecond temporal resolution. In particular, the two‐photon‐excited coenzyme NAD(P)H and flavins

## Abstract We report a rapid hyperspectral fluorescence lifetime imaging (FLIM) instrument that exploits high‐speed FLIM technology in a line‐scanning microscope. We demonstrate the acquisition of whole‐field optically sectioned hyperspectral fluorescence lifetime image stacks (with 32 spectral bi

## Abstract We present a fluorescence lifetime imaging technique with simultaneous spectral and temporal resolution. The technique is fully compatible with the commonly used multiphoton microscopes and nondescanned (direct) detection. An image of the back‐aperture of the microscope lens is projecte

## Abstract We describe a fluorescence lifetime imaging endomicroscope employing a fibre bundle probe and time correlated single photon counting. Preliminary images of stained pollen grains, eGFP‐labelled cells exhibiting Förster resonant energy transfer and tissue autofluorescence are presented. (

## Abstract Corals, like many other coelenterates, contain fluorescent pigments that show considerable homology with the well known green fluorescent protein of the jellyfish __Aequoria.__ In corals, unlike jellyfish, multiple proteins are present and the range of excitations and emissions suggest