ORIGINAL RESEARCH

Dynamics of functional activity of thyrocytes in the setting of changing morphofunctional activity of mast cells of the thyroid gland upon infrared laser therapy

About authors

1 Multi-specialty Center of Laser Medicine, Chelyabinsk

2 South Ural State Medical University, Chelyabinsk

Correspondence should be addressed: Irina V. Smelova
ul. Potemkina, d. 14, kv. 65, Chelyabinsk, Russia, 454081; ur.liam@vis.larips

Received: 2016-11-28 Accepted: 2016-12-12 Published online: 2017-01-19
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  1. Moskvin SV. Effektivnost' lazernoy terapii. Seriya «Effektivnaya lazernaya terapiya». Vol. 2. Moscow: Izd-vo “Tver”; 2015. 896 p. Russian.
  2. Kravchenko TG, Zarezina AS, Golovneva ES. Otsenka glubiny proniknoveniya lazernogo izlucheniya pri terapevticheskom vozdeystvii metodom komp'yuternogo modelirovaniya. Vestnik novykh meditsinskikh tekhnologiy. 2007; 14 (2): 202–4. Russian.
  3. Golovneva ES, Kravchenco TG, Kudrina MG, Gughyna AO, Popov GK. [Local effects of systemic high intensive laser radiation]. Journal of Ural Medical Academic Science. 2012; 2 (39): 126–7.
  4. Hоfling DB, Chavantes MC, Juliano AG, Cerri GG, Knobel M, Yoshimura EM, et al. As sessment of the effects of low-level laser therapy on the thyroid vascularization of patients with autoimmune hypothyroidism by color Doppler ultrasound. ISRN Endocrinol. 2012: 126720. DOI: 10.5402/2012/126720.
  5. Hofling DB, Chavantes MC, Acencio MM, Cerry GG, Marui S, Yoshimura EM, et al. Effects of low-level laser therapy on the serum TGF-β concentrations in individuals with autoimmune thyroiditis. Photomed LaserSurg. 2014 Aug; 32 (8): 444–9.DOI: 10.1089/pho.2014.3716.
  6. Morcos N, Omran M, Ghanem H, Elahdal M, Kamel N, Attia E. Phototherapeutic Effect of Low-Level Laser on Thyroid Gland of Gamma-Irradiated Rats. Photochem Photobiol. 2015 Jul–Aug; 91 (4): 942–51. DOI: 10.1111/php.12465.
  7. Weber JBB, Mayer L, Cenci RA, et al. Effect of three different protocols of low-level laser therapy on thyroid hormone production after dental implant placement in an experimental rabbit model. Laser Surg. 2014; 32 (11): 612–7.
  8. Aristarkhov VG. Rekomendatsii po primeneniyu infrakrasnogo lazernogo izlucheniya u bol'nykh s patologiey shchitovidnoy zhelezy. In: Materialy nauchno-prakticheskoy konferentsii GBOU VPO RyazGMU Minzdrava Rossii; 2014; Ryazan, Russia. Ryazan: RIO RyazGMU; 2014. Russian.
  9. Yushkov BG, Chereshnev VA, Klimin VG, Artashyan OS. Tuchnye kletki. Fiziologiya i patofiziologiya. Moscow: Izd-vo “Meditsina”; 2011. 240 p. Russian.
  10. Artashyan OS, Khramtsova YuS, Yushkov BG. [Participation of mast cells in process of reparative regeneration of the thyroid]. Journal of Ural Medical Academic Science. 2013; 44 (2): 36–8. Russian.
  11. Kozel AI, Soloveva LI, Popov GK. K mekhanizmu deystviya nizkointensivnogo lazernogo izlucheniya na kletku. Byulleten' eksperimental'noy biologii i meditsiny. 1999; 128 (10): 397–9. Russian.
  12. Golovneva ES, Kozel AI, Popov GK. [Pathophysiological mechanism of tissue revascularization by using an impact of a high-intensity laser irradiation]. Annals of the Russian academy of medical sciences. 2003; (6): 23–6. Russian.
  13. Isman CA, Yegen ВС, Alican I. Methimazole-induced hypothyroidism in rats ameliorates oxidative injury in experimental colitis. J Endocrinol. 2003; 177 (3): 471–6.
  14. Pinheiro AL, Browne RM, Frame JW, Matthews JB. Mast cells in laser and surgical wounds. Braz Dent J. 1995; 6 (1): 11–5.
  15. Chaves ME, Araujo AR, Piancastelli AC, Pinotty M. Effects of low- power light therapy on wound healing: LASER x LED. An Bras Dermatol. 2014 Jul–Aug; 89 (4): 616–23.
  16. Zalesskiy VN. K 50-letiyu lazernoy meditsiny: molekulyarnye mekhanizmy lazernoy biostimulyatsii. Ukrainskiy meditsinskiy zhurnal. 2010; 5 (79): 52–8. Russian.