GenAI synthesis of histopathological images from Raman imaging for intraoperative tongue squamous cell carcinoma assessment

Raman spectroscopy is an optical technique based on inelastic scattering of light by vibrating molecules and can provide chemical fingerprints of cells, tissues or biofluids. The high chemical specificity, minimal or lack of sample preparation and the ability to use advanced optical technologies in the visible or near-infrared spectral range (lasers, microscopes, fibre-optics) have recently led to an increase in medical diagnostic applications of Raman spectroscopy. The key hypothesis underpinning this field is that molecular changes in cells, tissues or biofluids, that are either the cause or the effect of diseases, can be detected and quantified by Raman spectroscopy. Furthermore, multivariate calibration and classification models based on Raman spectra can be developed on large "training" datasets and used subsequently on samples from new patients to obtain quantitative and objective diagnosis. Historically, spontaneous Raman spectroscopy has been known as a low signal technique requiring relatively long acquisition times. Nevertheless, new strategies have been developed recently to overcome these issues: non-linear optical effects and metallic nanoparticles can be used to enhance the Raman signals, optimised fibre-optic Raman probes can be used for real-time in-vivo single-point measurements, while multimodal integration with other optical techniques can guide the Raman measurements to increase the acquisition speed and spatial accuracy of diagnosis. These recent efforts have advanced Raman spectroscopy to the point where the diagnostic accuracy and speed are compatible with clinical use. This paper reviews the main Raman spectroscopy techniques used in medical diagnostics and provides an overview of various applications.

This perspective presents recent developments in the application of surface-enhanced Raman spectroscopy (SERS) to biosensing, with a focus on in vivo diagnostics. We describe the concepts and methodologies developed to date and the target analytes that can be detected. We also discuss how SERS has evolved from a "point-and-shoot" stand-alone technique in an analytical chemistry laboratory to an integrated quantitative analytical tool for multimodal imaging diagnostics. Finally, we offer a guide to the future of SERS in the context of clinical diagnostics.

In our study, 3461 cases of salivary gland tumor treated between 1955 and 2002 at West China Stomatology Hospital of Sichuan University were retrospectively analyzed, and compared with the previous reports. Measures such as age, tumor location, tumor histological type, and the nature of the growth (benign or malignant) were recorded at the same time. The findings are as follows: the average ages of salivary gland tumor patients were 41.38 years for the benign cases and 45.20 for the malignant ones; the male:female ratio was 0. 99:1 in the benign cases and 1.34:1 in the malignant ones; primary tumors were mostly in the parotid gland, palate and submandibular gland in sequence. Pleomorphic adenoma was the most frequent benign tumor followed by Warthin's tumor and basal cell adenoma, whereas mucoepidermoid carcinoma, adenoid cystic carcinoma and adenocarcinoma not otherwise specified were the most frequent malignant tumors. The incidence of salivary gland tumors increased with age. The male:female ratio of malignant tumors was higher than that of benign ones. The parotid gland and palate were the most common locations of salivary gland tumors. Pleomorphic adenoma and mucoepidermoid carcinoma were the most frequent benign and malignant tumors, respectively.