Dual-wavelength enhanced Raman endoscopic non-invasive pathological detection device and detection method

Abstract

The invention discloses a dual-wavelength enhanced Raman endoscopic non-invasive pathological detection device and detection method. Combining endoscopic detection, Raman detection and pathological analysis, the Raman spectrum of the tissue in the living body is directly detected, and the spectral information is based on The artificial intelligence method performs non-invasive pathological analysis instead of traditional invasive pathological examination. By constructing a signal enhancement device, the measured Raman spectrum signal is enhanced to effectively realize non-destructive pathological analysis of in vivo tissues. Two lasers with different wavelengths are used to detect tissue signals at the same part, and the difference between the two sets of signals is used to eliminate the influence of fluorescence and improve the measurement signal-to-noise ratio of the Raman endoscope. Design the self-focusing structure endoscopic lens, through the built-in support feet, realize the self-focusing and zooming of the endoscope without increasing the diameter of the endoscopic lens, and realize the three-dimensional scanning pathology of the sample on the basis of obtaining more stable and clear spectral results detection. Through the artificial intelligence pathological analysis method, non-invasive pathological detection is effectively realized.

Description

technical field [0001] The invention relates to the technical field of Raman measurement, in particular to a dual-wavelength enhanced Raman endoscopic non-invasive pathological detection device and detection method. Background technique [0002] Cancer has become one of the major public health problems that seriously threaten the life and health of the Chinese population. In recent years, the incidence and mortality of cancer in my country have continued to rise, while the cancer survival rate has a large gap compared with developed countries. One of the main reasons for the above situation is the low diagnosis rate of early stage cancer. At present, for gastric cancer, esophageal cancer, nasopharyngeal cancer and other cancers, the most important diagnostic methods are endoscopic diagnosis and pathological biopsy of lesion tissue taken out of the body, but it has many limitations, especially in early cancer diagnosis. obvious. The endoscopic detection system is mainly a t...

AI Technical Summary

Problems solved by technology

[0004] In the existing research, the existing research on the combination of Raman spectroscopy and endoscopy is to achieve in-situ real-time Raman spectroscopy measurement through the combination of fiber optic Raman and endoscopy, without considering the impact of the internal environment on Raman spectroscopy. Due to the complex influence of spectral signals, the lack of reliable and high-precision Raman scattering signal measurement methods, and the lack of feasible pathological analysis methods based on Raman spectral signals, it is not yet possible to truly achieve non-invasive pathological detection

Some studies have further improved the Raman endoscope, but in the actual measurement of biological tissues, there are very obvious fluorescent signals, which seriously affect the measurement signal-to-noise ratio, peak position, and peak intensity fitting accuracy of Raman spectroscopy.

At the same time, the Raman signal intensity of the sample itself is weak, and increasing the integration time can increase the intensity of the measured signal to a certain extent, but if the Raman integration time is blindly increased, the detection time will become longer, which will undoubtedly increase the pain of the patient

In the field of Raman measurement, the surface-enhanced Raman method and the tip-enhanced Raman method can effectively increase the Raman signal intensity of the sample to be measured, but this technology has not been applied to the field of Raman endoscopy

[0005] On the other hand, the existing research does not consider the focusing problem in living tissue, and the focusing effect will directly affect the measurement accuracy of Raman

Existing endoscopes often use an auxiliary focus ring to help focus, but on the one hand, applying the focus ring will increase the diameter of the endoscope lens and increase the patient’s discomfort during use; on the other hand, the focus ring may fall during operation, increasing the In order to avoid the risk of use, it is urgent to design an integrated self-focusing device

At the same time, the endoscope structure designed by some methods cannot be coupled with the existing clinical endoscope, and may even increase the size of the endoscope, which may increase the suffering of patients in practical applications, and it is difficult to obtain Raman spectra that can be used effectively , difficult to achieve pathological diagnosis

In addition, the Raman method for three-dimensional scanning pathological analysis has not been proposed, and it is difficult to determine the scope and depth of the lesion

[0006] In summary, the existing Raman endoscopic measurement methods are still unable to measure Raman spectra that eliminate the influence of fluorescence and have better signal strength

At the same time, the existing Raman endoscope device is still unable to realize the three-dimensional scanning Raman measurement of the integrated self-focusing and zooming of the lens.

In addition, after obtaining high-quality Raman spectra, there is still a lack of reliable pathological analysis criteria extraction methods and spectral information comparison methods, so as to truly realize the pathological detection of tissues.

Images