Source: http://jbpe.ssau.ru/index.php/JBPE/article/view/3284
Timestamp: 2019-04-24 17:01:58+00:00

Document:
Paper #3284 received 14 Mar 2018; revised manuscript received 16 May 2018; accepted for publication 11 Jun 2018; published online 29 Jun 2018.
Diabetes mellitus is a serious social and economic problem of modern society because it is widespread and fraught with numerous complications. Therefore, it is necessary to search for new methods of diabetes mellitus diagnostics and treatment and to improve the existing ones, which, in turn, requires thorough investigation of the disease development mechanisms, as well as elaboration of simple and reliable methods and criteria for detecting the complication precursors. In connection with the solution of these problems, in the paper we present an analytical review of recent publications devoted to the study of the changes of structural and optical properties of biological tissues under the conditions of diabetes mellitus development using in vitro models of glycated tissues, in vivo experimental models of diabetes in laboratory animals, and clinical studies.
2. Diabetes Fact Sheet, World Health Organization (2017).
4. D. LeRoith, S. I. Taylor, and J. M. Olefsky (Eds.), Diabetes Mellitus: A Fundamental and Clinical Text, 3rd edition, Lippincott Williams & Wilkins (2004).
5. K. T. Patton, G. A. Thibodeau, The Human Body in Health & Disease, 6th Edition, Elsevier Inc. (2014).
6. D. G. Gardner, D. M. Shoback, Greenspan's Basic & Clinical Endocrinology, 9th Edition, McGraw-Hill Medical, NY (2011).
7. B. B. Tripathy, RSSDI Textbook of Diabetes Mellitus, 2nd Edition, Jaypee Brothers Medical Publishers, New Delhi (2012).
8. Diabetes Care, Volume 40, Supplement 1, American Diabetes Association Inc. (2017).
10. T. Szkudelski, “The mechanism of alloxan and streptozotocin action in B cells of the rat pancreas,” Physiological Research 50(6), 537–546 (2001).
19. D. McGuire, N. Marx, Diabetes in Cardiovascular Disease: A Companion to Braunwald’s Heart Disease, Elsevier Health Sciences (2014).
20. V. V. Tuchin (Ed.), Handbook of Optical Sensing of Glucose in Biological Fluids and Tissues, Taylor & Francis Group LLC, CRC Press (2009).
37. U. Kanska, J. Boratynski, “Thermal glycation of proteins by D-glucose and D-fructose,” Archivum Immunologiae et Therapiae Experimentalis 50(1), 61–66 (2002).
48. V. V. Tuchin, Optical Clearing of Tissues and Blood, PM 154, SPIE Press, Bellingham, WA (2006).
60. M. Marre, “Genetics and the prediction of complications in type 1 diabetes,” Diabetes Care 22(2), B53–B58 (1999).
68. T. T. Berezov, B. F. Korovkin, Biological Chemistry, Meditsina, Moscow (1998) [in Russian].
89. A. Rohilla, S. Ali, “Alloxan Induced Diabetes: Mechanisms and Effects,” International journal of research in pharmaceutical and biomedical sciences 3(2), 819–823 (2012).
92. J. R. Garrett, J. Ekström, and L. C. Anderson (Eds.), Frontiers of Oral Biology: Glandular Mechanisms of Salivary Secretion, 10 (1998).
93. N. Rakieten, M. L. Rakieten, and M. V. Nadkarni, “Studies on the diabetogenic action of streptozotocin,” Cancer Chemotherapy Reports 29, 91–98 (1963).
94. K. Srinivasan, P. Ramarao, “Animal models in type 2 diabetes research: an overview,” Indian Journal of Medical Research 125, 451–472 (2007).
99. T. Hanafusa, J. Miyagawa, H. Nakajima, K. Tomita, M. Kuwajima, Y. Matsuzawa, and S. Tarui, “The NOD mouse,” Diabetes Research and Clinical Practice 24, S307–S311 (1994).
114. R. D. G. Leslie, D. C. Robbins (Eds.), Diabetes: Clinical Science in Practice, Cambridge University Press (1995).
128. J. D. Maynard, M. N. Ediger, R. D Johnson, and M. R. Robinson, Determination of a measure of a glycation end-product or disease state using a flexible probe to determine tissue fluorescence of various sites, Patent US11677498 USA, MPK А61В 6/00, Assignee: VeraLight, Inc., Albuquerque, NM (US), Appl. No.: 11/677,498 (2012).
130. K. Sangkyu, L. Joonhyung, Noninvasive apparatus and method for testing glycated hemoglobin, Patent 9841415, Assignee: Samsung Electronics Co., Ltd. (Suwon-si, KR), United States (2017).
138. P. J. Higgins, H. F. Bunn, “Kinetic analysis of the nonenzymatic glycosylation of hemoglobin,” The Journal of Biological Chemistry 256(10), 05204–5208 (1981).
143. V. L. Emanuel, I. Yu. Karyagina, and Yu. V. Emanuel, “Comparison of method for determining glycosylated hemoglobin,” Laboratornaya meditsina 5, 98–104 (2002) [in Russian].
144. V. V. Tuchin, Lasers and Fibre Optics in Biomedical Science, Fizmatlit, Moscow (2010) [in Russian].
145. V. V. Tuchin, Optics of Biological Tissues. Methods of Light Scattering in Medical Diagnostics, Fizmatlit, Moscow (2012) [in Russian].
148. F. S. Pavone, P. J. Campagnola (Eds.), “SHG and Optical Clearing,” Chap. 8 in Second Harmonic Generation Imaging, CRC Press, Taylor & Francis Group, Boca Raton, London, NY, 169−189 (2014).
149. E. A. Genina, A. N. Bashkatov, K. V. Larin, and V. V. Tuchin, “Light–Tissue Interaction at Optical Clearing,” Chap. 7 in Laser Imaging and Manipulation in Cell Biology, F.S. Pavone (Ed.), Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim, 113–164 (2010).
159. D. K. Tuchina, A. N. Bashkatov, E. A. Genina, and V. V. Tuchin, Biosensor for noninvasive optical monitoring of the pathology of biological tissues, Patent RF No. 2633494, MPK A61B 5/05, G01N 21/01, Patent holder: N.G. Chernyshevsky Saratov State University, Application No. 2016102046, 22.01.2016, Bul. No. 29 (2017).
167. C.-M. Cheng, Y.-F. Chang, H.-C. Chiang, and C.-W. Chang, “Optical coherence tomography for the structural changes detection in aging skin,” Proceedings of SPIE 10456, 104565B (2018).
180. L. V. Wang (Ed.), Photoacoustic Imaging and Spectroscopy, CRC Press (2009).

References: V. 
 V. 
 V. 
 V. 
 V. 
 V. 
 V. 
 V. 
 V. 
 V. 
 Application No. 2016102046
 V.