Assessment of the Sensitivity and Specificity of Tissue-specific-based and Anatomical-based Optical Biomarkers for Rapid Detection of Human Head and Neck Squamous Cell Carcinoma

Overview

Journal Oral Oncol

Publisher Elsevier

Specialty Dentistry

Date 2014 Jul 20

PMID 25037162

Citations 5

Authors

Fangyao Hu

Karthik Vishwanath

H Wolfgang Beumer

Liana Puscas

Hamid R Afshari

Ramon M Esclamado

Richard Scher

Samuel Fisher

Justin Lo

Christine Mulvey

Nirmala Ramanujam

Walter T Lee

Affiliations

Soon will be listed here.

Abstract

Objectives: We propose the use of morphological optical biomarkers for rapid detection of human head and neck squamous cell carcinoma (HNSCC) by leveraging the underlying tissue characteristics in aerodigestive tracts.

Materials And Methods: Diffuse reflectance spectra were obtained from malignant and contra-lateral normal tissues of 57 patients undergoing panendoscopy and biopsy. Oxygen saturation, total hemoglobin concentration, and the reduced scattering coefficient were extracted. Differences in malignant and normal tissues were examined based on two different groupings: anatomical site and morphological tissue type.

Results And Conclusions: Measurements were acquired from 252 sites, of which 51 were pathologically classified as SCC. Optical biomarkers exhibited statistical differences between malignant and normal samples. Contrast was enhanced when parsing tissues by morphological classification rather than anatomical subtype for unpaired comparisons. Corresponding linear discriminant models using multiple optical biomarkers showed improved predictive ability when accounting for morphological classification, particularly in node-positive lesions. The false-positive rate was retrospectively found to decrease by 34.2% in morphologically- vs. anatomically-derived predictive models. In glottic tissue, the surgeon exhibited a false-positive rate of 45.7% while the device showed a lower false-positive rate of 12.4%. Additionally, comparisons of optical parameters were made to further understand the physiology of tumor staging and potential causes of high surgeon false-positive rates. Optical spectroscopy is a user-friendly, non-invasive tool capable of providing quantitative information to discriminate malignant from normal head and neck tissues. Predictive models demonstrated promising results for real-time diagnostics. Furthermore, the strategy described appears to be well suited to reduce the clinical false-positive rate.

Citing Articles

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