Abstract: When the studied motion is periodic, such as for a beating heart, it is possible to acquire successive sets of two dimensional plus time data slice-sequences at increasing depths over at least one time period which are later rearranged to recover a three dimensional time sequence. Since gating signals are either unavailable or cumbersome to acquire in microscopic organisms, the invention is a method for reconstructing volumes based solely on the information contained in the image sequences. The central part of the algorithm is a least-squares minimization of an objective criterion that depends on the similarity between the data from neighboring depths. Owing to a wavelet-based multiresolution approach, the method is robust to common confocal microscopy artifacts. The method is validated on both simulated data and in-vivo measurements.

Abstract: A method for the detection and evaluation of the light generated in a fluorescing specimen by a short pulse laser, wherein at least a first and a second fluorophore and/or a self-fluorescing specimen are separately irradiated with different wavelengths and the specimen light is recorded in a wavelength-dependent manner with at least one nondescanned detector as reference spectrum and a separation into individual spectra is carried out during the irradiation of at least two fluorophores and/or self-fluorescing specimens simultaneously from the measured spectrum and the reference spectra through regression analysis, wherein the wavelength of the short pulse laser is advantageously changed continuously in at least one wavelength region.

Abstract: When the studied motion is periodic, such as for a beating heart, it is possible to acquire successive sets of two dimensional plus time data slice-sequences at increasing depths over at least one time period which are later rearranged to recover a three dimensional time sequence. Since gating signals are either unavailable or cumbersome to acquire in microscopic organisms, the invention is a method for reconstructing volumes based solely on the information contained in the image sequences. The central part of the algorithm is a least-squares minimization of an objective criterion that depends on the similarity between the data from neighboring depths. Owing to a wavelet-based multiresolution approach, the method is robust to common confocal microscopy artifacts.

Abstract: A method for the detection and evaluation of the light generated in a fluorescing specimen by a short pulse laser, wherein at least a first and a second fluorophore and/or a self-fluorescing specimen are separately irradiated with different wavelengths and the specimen light is recorded in a wavelength-dependent manner with at least one nondescanned detector as reference spectrum and a separation into individual spectra is carried out during the irradiation of at least two fluorophores and/or self-fluorescing specimens simultaneously from the measured spectrum and the reference spectra through regression analysis, wherein the wavelength of the short pulse laser is advantageously changed continuously in at least one wavelength region.