A Handheld Visible Resonance Raman Analyzer Used in Intraoperative Detection of Human Glioma

Overview

Journal Cancers (Basel)

Publisher MDPI

Specialty Oncology

Date 2023 Mar 29

PMID 36980638

Authors

Liang Zhang

Yan Zhou

Binlin Wu

Shengjia Zhang

Ke Zhu

Cheng-Hui Liu

Xinguang Yu

Robert R Alfano

Affiliations

Soon will be listed here.

Abstract

There is still a lack of reliable intraoperative tools for glioma diagnosis and to guide the maximal safe resection of glioma. We report continuing work on the optical biopsy method to detect glioma grades and assess glioma boundaries intraoperatively using the VRR-LRR Raman analyzer, which is based on the visible resonance Raman spectroscopy (VRR) technique. A total of 2220 VRR spectra were collected during surgeries from 63 unprocessed fresh glioma tissues using the VRR-LRR Raman analyzer. After the VRR spectral analysis, we found differences in the native molecules in the fingerprint region and in the high-wavenumber region, and differences between normal (control) and different grades of glioma tissues. A principal component analysis-support vector machine (PCA-SVM) machine learning method was used to distinguish glioma tissues from normal tissues and different glioma grades. The accuracy in identifying glioma from normal tissue was over 80%, compared with the gold standard of histopathology reports of glioma. The VRR-LRR Raman analyzer may be a new label-free, real-time optical molecular pathology tool aiding in the intraoperative detection of glioma and identification of tumor boundaries, thus helping to guide maximal safe glioma removal and adjacent healthy tissue preservation.

Citing Articles

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