Today: Dec 22, 2024
RU / EN
Last update: Oct 30, 2024
Сomplex Phototherapy for Compensation of Damages Induced  by High-Intensity Laser Radiation in Experiment

Сomplex Phototherapy for Compensation of Damages Induced by High-Intensity Laser Radiation in Experiment

Bavrina А.P., Malinovskaya S.L., Alakaev R.R., Monich V.А.
Key words: red light; protein oxidative modification; high-intensity laser radiation.
2015, volume 7, issue 4, page 78.

Full text

html pdf
1996
1777

The aim of the investigation was to develop a new technology of complex phototherapy based on consecutive biological tissue exposure to high-intensity laser radiation and low-intensity broadband red light and to evaluate its possibilities in experiment.

Materials and Methods. There were studied the effects of consecutive exposure of white rat tissues to high-intensity red and infrared radiation and low-intensity broadband red light on spontaneous and metal-catalyzed oxidative modification of proteins. The study was performed on white outbred rats with a body mass of 180 to 250 g, which were divided into 5 groups. Control group 1 included animals whose inner surface of the thigh was exposed locally to laser light radiation with a wavelength of 671 nm (red laser) and the power of 50 mW. Test group 2 underwent locally red laser radiation of the inner femoral surface and three consecutive sessions of low-intensity broadband red light exposure (a wavelength of 630 nm, light spot intensity of 5 mW/cm2). Control group 3 was exposed locally to 980 nm laser radiation of the inner femoral surface (infrared laser with the power of 50 mW). Test group 4 was exposed locally to infrared laser radiation of the inner femoral surface and three consecutive sessions of low-intensity broadband red light. Group 5 (intact) was not exposed to radiation. Samples of femoral tissue and blood serum were taken on day 3 in all groups of animals.

Results. The content of neutral and basic aliphatic dinitrophenylhydrazons in the tissues exposed to red and infrared laser radiation was found to be increasing. In subsequent sessions of low-intensity red light phototherapy there occurred sharp decrease in the levels of protein oxidative modification products to normal values.

Conclusion. The developed technology of complex phototherapy including sessions of consecutive exposure of biological tissues to laser and broadband red light provides radiation safety of procedures.

  1. Buravlev E.A., Zhidkova T.V., Vladimirov Y.A., Osipov A.N. Effects of laser and LED radiation on mitochondrial respiration in experimental endotoxic shock. Lasers Med Sci 2013; 28(3): 785–790, http://dx.doi.org/10.1007/s10103-012-1155-7.
  2. Kondratyev A.S., Mikhailova I.A., Petrishchev N.N. Modeling of different degrees of microvessel laser-induced endothelium damage. Rossiyskiy fiziologicheskiy zhurnal im. I.M. Sechenova 2013; 99(6): 745–750.
  3. Petrischev N.N., Yantareva L.I., Fokin S.I. Dependence of infra-red laser emission (IrLE) photo-effect on the power flux density (PFD) and functional state of biological objects (infusoria Spirostomum ambiguum). Lazernaya meditsina 2005; 9(3): 43–48.
  4. Bavrina A.P., Monich V.A., Malinovskaya S.L., Yakovleva E.I., Bugrova M.L., Lazukin V.F., Bavrina A.P., Monich V.A., Malinovskaya S.L., Yakovleva E.I., Bugrova M.L., Lazukin V.F. Correction method for radiation-induced heart disease consequences by low-intensity electromagnetic radiation in experiment. Bulleten’ eksperimental’noj biologii i mediciny 2015; 159(1): 115–119.
  5. Karu T., Pyatibrat L. Gene expression under laser and light-emitting diodes radiation for modulation of cell adhesion: possible applications for biotechnology. IUBMB Life 2011; 63(9): 747–753, http://dx.doi.org/10.1002/iub.514.
  6. Monich V.A., Drugova O.V., Lazukin V.F., Bavrina A.P. Low-power light and isolated rat hearts after ischemia of myocardium. J Photochem Photobiol B 2011; 105(1): 21–24, http://dx.doi.org/10.1016/j.jphotobiol.2011.06.006.
  7. Dubinina E.I., Burmistrov S.O., Khodov D.A., Porotov I.G. Oxidative modification of human blood serum proteins, and the method of its determination. Voprosy meditsinskoy khimii 1995; 41(1): 24–26.
  8. Bavrina A.P., Monich V.A., Malinovskaya S.L., Ermolaev V.S., Druzhinin E.A., Kuznetsov S.S. Correction of ionizing irradiation consequences with low-intensity light. Bulleten’ eksperimental’noj biologii i mediciny 2013; 156(11): 608–610.
  9. Malinovskaya S.L., Ermolayev V.S., Bavrina А.P., Monich V.А. Normalization of free-radical oxidation processes in muscular tissue in radiation disease by low-intensity red light exposure in experiment. Sovremennye tehnologii v medicine 2014; 6(2): 32–37.
  10. Mason M.G., Nicholls P., Wilson M.T., Cooper C.E. Nitric oxide inhibition of respiration involves both competitive (heme) and noncompetitive (copper) binding to cytochrome c oxidase. Proc Natl Acad Sci USA 2006; 103(3): 708–713, http://dx.doi.org/10.1073/pnas.0506562103.
  11. Iaffaldano N., Meluzzi A., Manchisi A., Passarella S. Improvement of stored turkey semen quality as a result of He–Ne laser irradiation. Anim Reprod Sci 2005; 85(3–4): 317–325, http://dx.doi.org/10.1016/j.anireprosci.2004.04.043.
  12. Moriyama Y., Nguyen J., Akens M., Moriyama E.H., Lilge L. In vivo effects of low level laser therapy on inducible nitric oxide synthase. Lasers Surg Med 2009; 41(3): 227–231, http://dx.doi.org/10.1002/lsm.20745.
  13. Udut V.V., Prokop’ev V.A. Biophisical effects of 632.8 nm HeNe laser radiation on human blood and organism. Al’manakh klinicheskoy meditsiny 2006; 12: 41.
Bavrina А.P., Malinovskaya S.L., Alakaev R.R., Monich V.А. Сomplex Phototherapy for Compensation of Damages Induced by High-Intensity Laser Radiation in Experiment. Sovremennye tehnologii v medicine 2015; 7(4): 78, https://doi.org/10.17691/stm2015.7.4.10


Journal in Databases

pubmed_logo.jpg

web_of_science.jpg

scopus.jpg

crossref.jpg

ebsco.jpg

embase.jpg

ulrich.jpg

cyberleninka.jpg

e-library.jpg

lan.jpg

ajd.jpg

SCImago Journal & Country Rank