Double-mode Raman-optical projection tomography system

Abstract

The invention belongs to the technical field of testing or analyzing materials by means of the chemical or physical properties of determination materials, and discloses a double-mode Raman-optical projection tomography system. A laser beam subjected to beam expanding through a beam expander shines a sample, all modal optical signals are separated through a spectroscope, signal collection is conducted by adopting sparse sampling, an optical transmission projection signal collection module collects sample transmission light, and an optical projection image is formed; a multispectral Raman scattered signal collection module collects Raman scattered signal generated by the sample; collected data is subjected to background noise removing; sparse sampling data is rebuilt by adopting ART based ona TV minimization algebraic reconstruction method; a three-dimensional structure image and a three-dimensional chemical composition image which are obtained through rebuilding are blended, and a three-dimensional volume image containing multiple information is obtained. Accordingly, Raman spectral imaging and optical projection tomography are skillfully combined to the same system, triple information is provided, and information fit is high; the large scale sample imaging speed is high, and operation is easy and flexible.

Description

technical field [0001] The invention belongs to the technical field of testing or analyzing materials by means of measuring their chemical or physical properties, and in particular relates to a dual-mode Raman-optical projection tomography system. Background technique [0002] At present, the existing technology commonly used in the industry is as follows: 3D volumetric imaging enables quantitative and global measurement of complex systems, which is crucial in the study of cell metabolism, brain function, and developmental biology. The easiest way to achieve 3D volumetric imaging is to use optical slice scanning. The laser is scanned on a 2D plane to collect 2D images, and the laser focus is moved along the axial direction to obtain 3D image information. In this method, a strong axial sectioning capability of the focused laser beam is required. Both confocal fluorescence microscopy and coherent Raman scattering microscopy have this capability. However, this sectioning metho...

AI Technical Summary

Problems solved by technology

However, this method cannot achieve a good three-dimensional imaging effect on large-scale samples, and it cannot provide structural image information of the samples.

Although there are many methods to achieve three-dimensional volume imaging of samples, these methods are either limited by the problem of fluorescent markers or limited by imaging performance, and can only provide a single information of structure or chemical composition, and cannot simultaneously acquire multiple Modal Image Information

[0003] To sum up, the problems existing in the existing technology are: the three-dimensional volume imaging of the sample by the existing technology is limited by the fluorescent markers and imaging performance, and can only provide a single information

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