Abstract: According to the present invention, a measurement device includes a light emitting part configured to emit a plurality of spectral lights each including two or more spectra distributed at mutually different frequencies by causing adjacent frequency intervals to be different from each other, a focusing part configured to focus light by causing two or more spectra to overlap in an overlapping region in each of a plurality of different focal point regions of a sample and to be shifted from each other, and a detecting part configured to acquire a signal of fluorescence beats which emits light by interference light beats in each of a plurality of overlapping regions in the sample and includes information of the sample.

Abstract: According to the present invention, a measurement device includes a light emitting part configured to emit a plurality of spectral lights each including two or more spectra distributed at mutually different frequencies by causing adjacent frequency intervals to be different from each other, a focusing part configured to focus light by causing two or more spectra to overlap in an overlapping region in each of a plurality of different focal point regions of a sample and to be shifted from each other, and a detecting part configured to acquire a signal of fluorescence beats which emits light by interference light beats in each of a plurality of overlapping regions in the sample and includes information of the sample.

Abstract: The present invention provides a method of detecting nerves, including: step 1 of irradiating a sample with excitation light; step 2 of detecting Raman scattering light from the sample; step 3 of calculating an intensity ratio of a wave number within a specific range of the Raman scattering light detected in the step 2 or extracting a feature of the intensity ratio and subjecting the feature to multivariate analysis and/or statistical analysis; and step 4 of specifically displaying nerves containing unmyelinated nerves, using as an index the intensity ratio or a result from the multivariate analysis and/or the statistical analysis.

Abstract: The present invention provides a method of detecting nerves, including: step 1 of irradiating a sample with excitation light; step 2 of detecting Raman scattering light from the sample; step 3 of calculating an intensity ratio of a wave number within a specific range of the Raman scattering light detected in the step 2 or extracting a feature of the intensity ratio and subjecting the feature to multivariate analysis and/or statistical analysis; and step 4 of specifically displaying nerves containing unmyelinated nerves, using as an index the intensity ratio or a result from the multivariate analysis and/or the statistical analysis.

Abstract: A method and an apparatus for discriminating a cardiac tissue using Raman scattering are provided which enable a noninvasive discrimination of the cardiac tissue to be accurately performed. The discrimination method includes: a step of irradiating a sample containing a cardiac tissue with excitation light; a step of detecting Raman scattering light from the sample; an analysis step of analyzing the detected Raman scattering light by a multivariate analysis using as an index, Raman scattering spectra which are specific to at least a living myocardial tissue, a necrotic myocardial tissue, a granulation tissue and a fibrotic tissue, respectively; and a step of discriminating the cardiac tissue in accordance with analysis results obtained in the analysis step.

Abstract: To provide a pulse laser light timing adjusting device capable of easily adjusting pulse laser light timing, a timing adjusting method, and an optical microscope. An optical microscope in accordance with the present invention includes mirror pairs 21 and 31 to generates the first timing adjusting optical beam in which the first pulse laser light ?1 is delayed from the second pulse laser light ?2 and the second timing adjusting optical beam in which the second pulse laser light ?2 is delayed from the first pulse laser light having a first wavelength from the optical beam extracted at the beam samplers 15 and 16, a first detector 23 and a second detector 33 to output a first detection signal and a second detection signal based on a nonlinear optical effect, and timing adjusting means 42 to adjust the timing based on the first detection signal and the second detection signal.