Vol 30 No 3

Asian

Journal of Physics

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Volume 30 No 3 March 2021

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A Special Issue Dedicated
to
Prof V B Kartha, FNA

Guest Edited By : V V Tuchin and Santosh Chidangil

Anita Publications
FF-43, 1st Floor, Mangal Bazar, Laxmi Nagar, Delhi-110 092, India

Asian Journal of Physics

(A Publication Not for Profit)

Volume 30, Nos 3(2021)

CONTENTS

Guest Editorial

About the Guest Editor

About Prof V B Kartha

Raman spectroscopy in the bio-medical field: Practical guidelines from calibration to data processing for

an unbiased interpretation of biospectroscopic information

V Untereiner, O Piot, F Alsamad, N Mainreck, C Gobinet, G D Sockalingum

Recent progress in tissue enhanced spectroscopy for cancer detection

Valery V Tuchin and Luís M Oliveira

Investigation of metabolism in cancer specimens using Fluorescence Lifetime Imaging Microscopy

Shagufta Rehman Alam, Horst Wallrabe and Ammasi Periasamy

Multi-modal Tissue Sensing in the Detection of Malignant Tumors-A Mini Review

B S Suresh Anand, Jonath Sujan, and Narayanan Subhash

Fiberoptic Raman Theranostics in Cancer Management: Challenges and Perspectives

C Murali Krishna

Recent Advances in Multimodal Optical Coherence Tomography for Tissue Imaging

B Karthik Goud and K Divakar Rao

Adenocarcinoma and Squamous cell carcinoma probed by laser induced fluorescence

Sanoop Pavithran M, Ajaya Kumar Barik, Arun Chawla, Muralidhar V Pai, Rekha Upadhya, Jijo Lukose, Santhosh Chidangil

LIBS: Potential and possibilities for advanced biophotonics applications

Unnikrishnan V K

I am happy to pen down my appreciation on the occasion of the Special Issue of Asian Journal of Physics in honor of Prof V B Kartha. When I joined Bhabha Atomic Research Centre, Bombay in 1972 , Prof Kartha was already a very well recognized scientist in the Spectroscopy Division .He contributed significantly to many programs of the Department of Atomic Energy such as development of many spectroscopic techniques for critical applications in laser isotope enrichment. environmental monitoring and ultra-trace analysis.His contributions to the development of beam lines at synchrotron source INDUS-1 at RRCAT, Indore will always be remembered. Later on , he moved to MAHE and established a world class group in Biomedical applications of Spectroscopy. His contributions to the advancement of science and technology in our country will always be a source of inspiration to young scientists .On this occasion, it is my privilege and honor to offer my respects and best wishes to Prof Kartha.

Ajay Sood
Tue, 13 Apr 2021 18:18:06

Asian Journal of Physics Vol. 30 No 3, (2021), 427-444

Recent progress in tissue enhanced spectroscopy for cancer detection

Valery V Tuchin^1,2,3 and Luís M Oliveira^4,5

¹Research-Educational Institute of Optics and Biophotonics, Saratov State University, Saratov, Russian Federation.

²Interdisciplinary Laboratory of Biophotonics, National Research Tomsk State University, Tomsk, Russian Federation.

³Laboratory of Laser Diagnostics of Technical and Living Systems,
Institute of Precision Mechanics and Control of the Russian Academy of Sciences, Saratov, Russian Federation.

⁴Department of Physics, Polytechnic Institute of Porto – School of Engineering, Porto, Portugal.

⁵Centre of Innovation in Engineering and Industrial Technology, Polytechnic of Porto – School of Engineering, Porto, Portugal.

Dedicated to Professor Prof V B Kartha,FNA

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Spectroscopy methods can be used for pathology identification and monitoring, but their applications are limited by light scattering if the disease is located in deeper tissue layers. The first study presented in this paper shows that the simple application of spectroscopy measurements allows colorectal cancer discrimination through the identification of different pigment content in normal and diseased tissues. The other two studies demonstrate that by combining sensitive spectroscopy measurements in a wide spectral range with optical clearing (OC) treatments is also useful for cancer discrimination. In the second study, by using spectral collimated transmittance (T_c) measurements during OC treatments, it was possible to estimate the diffusion coefficient of glucose in normal and pathological colorectal mucosa as: D_glucose = 5.8×10^-7 cm²/s and D_glucose = 4.4×10^-7 cm²/s, respectively. An additional result of this study shows that the mobile water content is about 5% higher in pathological mucosa. In the third study, by analyzing the OC efficiency in the deep UV range, it was possible to obtain different protein dissociation rates in normal (27.4) and pathological (79.1) mucosa tissues at 93%-glycerol treatment. Such methods can be applied to study other types of cancer or other diseases, and their conversion into noninvasive procedures, based on diffuse reflectance spectroscopy, is to be expected. © Anita Publications. All rights reserved.

Keywords: Enhanced Tissue Spectroscopy, Colorectal Cancer, Tissue Optical Clearing, Optical Clearing Mechanisms, Optical Clearing Agents.

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