Model-based spectroscopic analysis of the oral cavity: impact of anatomy

McGee, Sasha; Mirković, Jelena; Mardirossian, Vartan; Elackattu, Alphi; Yu, Chung-Chieh; Kabani, Sadru; Gallagher, George; Pistey, Robert; Galindo, Luis H.; Badizadegan, Kamran; Wang, Zhi; Dasari, Ramachandra R.; Feld, Michael S.; Grillone, Gregory A.

doi:10.1117/1.2992139

Cited by 39 publications

(51 citation statements)

References 35 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…On the other hand, our finding is consistent with previous study carried out by McGee et al [17]. They examined the total hemoglobin variations in all possible anatomical parts of the oral cavity.…”

Section: Discussionsupporting

confidence: 95%

Mapping of healthy oral mucosal tissue using diffuse reflectance spectroscopy: ratiometric-based total hemoglobin comparative study

2015

View full text Add to dashboard Cite

The objective of this study is to clinically evaluate the diffuse reflectance spectroscopy (DRS) ratiometric method for differentiation of normal oral mucosal tissues with different histological natures and vascularizations in the oral cavity. Twenty-one healthy patients aged 20-44 years were diagnosed as healthy and probed with a portable DRS system. Diffuse reflectance spectra were recorded in vivo in the range (450-650 nm). In this study, the following three oral mucosal tissues were considered: masticatory mucosa, lining mucosa, and specialized mucosa. Spectral features based on spectral intensity ratios were determined at five specific wavelengths (512, 540, 558, 575, and 620 nm). Total hemoglobin based on spectral ratios for the three anatomical regions have also been evaluated. The three studied groups representing different anatomical regions in the oral cavity were compared using analysis of variance and post hoc least significant difference tests. Statistical analysis showed a significant difference in the mean of diffuse spectral ratios between the groups (P < 0.05). Post hoc test detected significant difference between masticatory mucosa group and lining mucosa group (P < 0.05) and between masticatory mucosa group and specialized mucosa group (P = 0.000, at ratio 558/620 and P = 0.000, at ratio 575/620). Significant difference was also found between the lining mucosa group and specialized mucosa group (P = 0.000, at ratio 512/558 and P = 0.000, at ratio 512/575). It has also been shown that spectral ratios at wavelengths 558, 575, and 620 nm reveal the greatest difference among the main oral sites in terms of total hemoglobin content. Diffuse reflectance spectroscopy might be used for creating a DRS databank of normal oral mucosal tissue with specific spectral ratios featuring the total hemoglobin concentrations. That would further enhance the discrimination of oral tissue for examining the histological nature of oral mucosa and diagnosis of early precancerous changes in the oral cavity based on non-invasive monitoring of neovascularization.

show abstract

Section: Discussionsupporting

confidence: 95%

Mapping of healthy oral mucosal tissue using diffuse reflectance spectroscopy: ratiometric-based total hemoglobin comparative study

2015

View full text Add to dashboard Cite

show abstract

“…It is known that subsites in the oral cavity have distinct origins, and consequently distinct anatomical and molecular features. 29,30 Previous°uorescence 31 and re°ectance spectroscopy 32,33 studies have demonstrated de¯-nite spectral contrasts between di®erent subsites in healthy populations. Three major RS studies in thē nger-print and high wavenumber region have also demonstrated di®erences arising due to epithelial and sub-epithelial structures, submucosa and degree of keratinization in subsites of healthy subjects and suggested clustering of sites based on anatomical and spectral similarities.…”

Section: Introductionmentioning

confidence: 99%

In vivosubsite classification and diagnosis of oral cancers using Raman spectroscopy

Sahu

Deshmukh

Hole

et al. 2016

J. Innov. Opt. Health Sci.

View full text Add to dashboard Cite

Oral cancers su®er from poor disease-free survival rates due to delayed diagnosis. Noninvasive, rapid, objective approaches as adjuncts to visual inspection can help in better management of oral cancers. Raman spectroscopy (RS) has shown potential in identi¯cation of oral premalignant and malignant conditions and also in the detection of early cancer changes like cancer-¯eld-e®ects (CFE) at buccal mucosa subsite. Anatomic di®erences between di®erent oral subsites have also been reported using RS. In this study, anatomical di®erences between subsites and their possible in°uence on healthy vs pathological classi¯cation were evaluated on 85 oral cancer and 72 healthy subjects. Spectra were acquired from buccal mucosa, lip and tongue in healthy, contralateral (internal healthy control), premalignant and cancer conditions using¯ber-optic Raman spectrometer. Mean spectra indicate predominance of lipids in healthy buccal mucosa, contribution of both lipids and proteins in lip while major dominance of protein in tongue spectra. From healthy to tumor, changes in protein secondary-structure, DNA and heme-related features were observed. Principal component linear discriminant analysis (PC-LDA) followed by leave-one-out-crossvalidation (LOOCV) was used for data analysis. Findings indicate buccal mucosa and tongue are distinct entities, while lip misclassi¯es with both these subsites. Additionally, the diagnostic algorithm for individual subsites gave improved classi¯cation e±ciencies with respect to the pooled subsites model. However, as the pooled subsites model yielded 98% speci¯city and 100% sensitivity, this model may be more useful for preliminary screening applications. Large-scale validation studies are a pre-requisite before envisaging future clinical applications.

show abstract

“…5. The μ s ' of the lamina propria were similar to the values of buccal mucosa reported in [3], while the μ s ' of the epithelium could not be compared because a single-layer tissue model was used in [3]. The best-fit results of μ a of the epithelium and lamina propria were shown in Fig.…”

Section: Discussionmentioning

confidence: 57%

Development of a movable diffuse reflectance spectroscopy system for clinical study of esophageal precancer

et al. 2015

View full text Add to dashboard Cite

We constructed a movable imaging spectrograph-based system and a contact probe consisting of fibers with several source-to-detection separations (SDS) to measure spatially-resolved diffuse reflectance spectra from superficial tissue. The goal is to estimate optical properties of the mucosa in the oral cavity and investigate correlations between the estimated properties and precancerous changes in the mucosa. A previously developed GPU-based iterative curve-fitting inverse Monte Carlo model was used to extract optical properties from measured spectra. We validated the system with two-layer tissue phantoms, took in-vivo measurements on the buccal mucosa of three normal volunteers, and extracted optical parameters.

show abstract

Model-based spectroscopic analysis of the oral cavity: impact of anatomy

Cited by 39 publications

References 35 publications

Mapping of healthy oral mucosal tissue using diffuse reflectance spectroscopy: ratiometric-based total hemoglobin comparative study

Mapping of healthy oral mucosal tissue using diffuse reflectance spectroscopy: ratiometric-based total hemoglobin comparative study

In vivosubsite classification and diagnosis of oral cancers using Raman spectroscopy

Development of a movable diffuse reflectance spectroscopy system for clinical study of esophageal precancer

Contact Info

Product

Resources

About