Advanced Diode Laser with Specialized Beam-delivery Instrument in Mini Invasive Laser Treatment of Anorectal Vascular Pathology
( Pp. 139-144)
Kuznetsov Evgeny V.
Zhizhin Nikita K.
Golyaev Yuri D.
Kolbas Yuri Yu.
Soloveva Tatyana I.
Dmitry N. Ermakov
More about authors
Kuznetsov Evgeny V.
Dr. Sci. (Eng.), Professor; General Director; Head at the Center
Research Institute “Polyus” named after M.F. Stelmakh; Engineering Academy of the Peoples’ Friendship University of Russia
Moscow, Russian Federation Zhizhin Nikita K. Cand. Sci. (Med.), Associate Professor; senior researcher
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Golyaev Yuri D. Dr. Sci. (Eng.); Head at the NPK-470
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Kolbas Yuri Yu. Dr. Sci. (Eng.); Deputy Head at the NPK-470
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Soloveva Tatyana I. Cand. Sci. (Eng.), Associate Professor; leading researcher
Research Institute “Polyus” named after M.F. Stelmakh; Engineering Academy of the Peoples’ Friendship University of Russia
Moscow, Russian Federation Dmitry N. Ermakov Dr. Sc. (Polit.), Dr. Sc. (Econ.), Cand. Sci. (Hist.), Professor, Principal Researcher; Institute of China and Modern Asia, Russian Academy of Sciences Researcher; Russian Federation; Professor of the Department of Management
Center for World Politics and Strategic Analysis; International Academy of Business and New Technologies
Institute of China and Modern Asia, Russian Academy of Sciences Researcher, Russian Federation; Yaroslavl, Russian Federation
Research Institute “Polyus” named after M.F. Stelmakh; Engineering Academy of the Peoples’ Friendship University of Russia
Moscow, Russian Federation Zhizhin Nikita K. Cand. Sci. (Med.), Associate Professor; senior researcher
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Golyaev Yuri D. Dr. Sci. (Eng.); Head at the NPK-470
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Kolbas Yuri Yu. Dr. Sci. (Eng.); Deputy Head at the NPK-470
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Soloveva Tatyana I. Cand. Sci. (Eng.), Associate Professor; leading researcher
Research Institute “Polyus” named after M.F. Stelmakh; Engineering Academy of the Peoples’ Friendship University of Russia
Moscow, Russian Federation Dmitry N. Ermakov Dr. Sc. (Polit.), Dr. Sc. (Econ.), Cand. Sci. (Hist.), Professor, Principal Researcher; Institute of China and Modern Asia, Russian Academy of Sciences Researcher; Russian Federation; Professor of the Department of Management
Center for World Politics and Strategic Analysis; International Academy of Business and New Technologies
Institute of China and Modern Asia, Russian Academy of Sciences Researcher, Russian Federation; Yaroslavl, Russian Federation
Abstract:
As the wavelength range of diode lasers expands, they become increasingly attractive for laser medicine because they are compact, allow the use of convenient fiber delivery systems, and are relatively inexpensive and long-lived. Russian diode lasers are based on world-level achievements in nanotechnologies used in their production. The paper presents the results of clinical application of an improved diode laser apparatus ACT model of a domestic company “Uricon Group” equipped with unique multifunctional instruments which enable to minimize mucous lesion in treating vascular pathology of the anorectal zone. A dual-frequency apparatus generating at wavelengths of 980 and 1470 nm permitted the development of a combined technique, which was verified by practical clinical application. The study was aimed at improving the mini-invasive method of surgical treatment of vascular anorectal pathology to ensure maximum efficiency of surgery at any stage of the disease, reducing the duration of surgery, minimizing pain during and after surgery. The technique of laser mini-invasive transdermal and subdermal-submucosal destruction, applied in treatment of 362 patients using the diode laser of ACT model and the developed specialized instrument, has shown its effectiveness. All patients returned to daily activities 2-3 days after surgery. Economic effect of the developed treatment technology is provided by low price of the equipment and absence of necessity of the patient’s stay in the clinic in the postoperative period.
How to Cite:
Kuznetsov E.V., Zhizhin N.K., Golyaev Y.D., Kolbas Y.Y., Soloveva T.I., Dmitry N.E., (2022), ADVANCED DIODE LASER WITH SPECIALIZED BEAM-DELIVERY INSTRUMENT IN MINI INVASIVE LASER TREATMENT OF ANORECTAL VASCULAR PATHOLOGY. Computational Nanotechnology, 1 => 139-144.
Reference list:
De A., Roy P. Hybrid digitally guided hemorrhoidal artery ligation with laser hemorrhoidoplasty: Our experience with a new approach to hemorrhoidal disease.International Surgery Journal. 2021. No. 8 (10). Pp. 2968-2673.
Karahaliloglu A.F. First results after laser obliteration of first- and second-degree hemorrhoids. Coloproctology. 2007. No. 29 (6). Pp. 327-335.
Kasagawa O., Marumo M., Asako O. et al. Clinical availability of contact laser probe for hemorrhidectomy. Nippon Laser Igakkaishi (Japan Society for Laser Surgery and Medicine). 2008. No. 29 (2). Pp. 112-118. (In Jap.)
Lakmal K., Basnayake O., Jayarajah U., Samarasekera D.N. Clinical outcomes and effectiveness of laser treatment for hemorrhoids: A systematic review. World J. Surg. 2021. No. 45. Pp. 1222-1236.
Leff E. Hemorrhoidectomy - laser vs. nonlaser: Outpatient surgical experience. Dis. Colon Rectum. 1992. No. 35 (8). Pp. 743-746.
Loder P.B., Kamm M.A., Nicholls R.J., Phillips R.K.S. Haemorrhoids: Pathology, pathophysiology and aetiology. Br. J. Surg. 1994. No. 8. Pp. 1946-1954.
Longchamp G., Liot E., Meyer J. et al. Non-excisional laser therapies for hemorrhoidal disease: A systematic review of the literature. Lasers in Medical Science. 2021. No. 36. Pp. 485-496.
Maloku H., Gashi Z., Lazovic R. et al. Laser hemorrhoidoplasty procedure vs open surgical hemorrhoidectomy: A trial comparing 2 treatments for hemorrhoids of third and fourth degree. A. Acta Inform Med. 2014. No. 22 (6). Pp. 365-367.
Minayev V.P. The dawn of use of laser radiation in domestic medicine. Photonics. 2017. No. 62 (2). Pp. 104-110.
Plapler H., Netto F., Pedro A.J. 350 ambulatory hemorrhoidectomies using a scanner coupled to a CO2 laser. J. Clin. Laser Med. Surg. 2000. No. 18. Pp. 259-262.
Plapler H., Hage R., Duarte J. et al. A new method for hemorrhoid surgery: Intrahemorrhoidal diode laser, does it work Photomedicine and Laser Surgery. 2009. No. 27 (5). Pp. 819-823.
Salfi R. A new technique for ambulatory hemorroidal treatment. Coloproctol. 2009. No. 31. Pp. 99-103.
Shimojima Y., Miyajima N. Matsushima M. Surgical Treatment for hemorrhoids, mainly performed in hospital. Nippon Daicho Komonbyo Gakkai Zasshi (Journal of the Japan Society of Coloproctology). 2021. No. 74 (10). Pp. 531-539.
Skobelkin O.K., Brekhov E.I., Korepanov V.I. Lasers in surgery and medicine a review of laser surgery in the U.S.S.R. Lasers in Surgery and Medicine. 1985. No. 5. Pp. 451-452.
Skobelkin O.K. Lasers in surgery. Moscow: Medicina, 1989.
Solovieva T. Low-level laser therapy. Proceedings of SPIE 4422, 2001.
Trigui A., Rejab H., Akrout A. et al. Laser utility in the treatment of hemorrhoidal pathology: A review of literature. Lasers in Medical Science. 2021, July 31.
Sokolov V.V., Chissov V.I., Yakubovskaya R.I. et al. Photodynamic therapy and laser-induced thermotherapy combination: New apparatus and first clinical experience in Russia. Proceedings of IPA 9th World Congress of the International Photodynamic Association (Miyzaki, Japan). 2003. No. 35.
Tsui C., Klein R., Garabrant M. Minimally invasive surgery: National trends in adoption and future directions for hospital strategy. Surg Endosc. 2013. No. 27. Pp. 2253-2257. Published online.
Usui Y. A new procedure of ICG enhanced diode laser therapy for hemorrhoids. Nippon Daicho Komonbyo Gakkai Zasshi (Journal of the Japan Society of Coloproctology). 2003. No. 56 (10). Pp. 815-818. (In Jap.)
Wang X., Yin X., Guo X.T. et al. Effects of the pestle needle therapy, a type of acupoint stimulation, on post-hemorrhoidectomy pain: A randomized controlled trial. J. of Integrative Med. 2020. No. 18 (6). Pp. 492-498.
Yamana T. Japanese practice guidelines for anal disorders: I. Hemorrhoids. Journal of the Anus, Rectum and Colon. 2017. No. 1 (3). Pp. 89-99.
Zhizhin N.K., Kolbas Yu.Yu., Nikitin S.A. et al. Innovative method of using diode laser in the treatment of hemorroidal disease. Quality. Innovations. Education. 2020. No. 6 (170). Pp. 99-104.
Zhizhin N.K., Kolbas Yu.Yu., Kuznetsov E.V. Application of lasers in surgery. Photonics. 2020. No. 14 (3). Pp. 282-291.
http://www.kremlin.ru/events/president/news/67740 (data obrashcheniya: 12.02.2022).
Karahaliloglu A.F. First results after laser obliteration of first- and second-degree hemorrhoids. Coloproctology. 2007. No. 29 (6). Pp. 327-335.
Kasagawa O., Marumo M., Asako O. et al. Clinical availability of contact laser probe for hemorrhidectomy. Nippon Laser Igakkaishi (Japan Society for Laser Surgery and Medicine). 2008. No. 29 (2). Pp. 112-118. (In Jap.)
Lakmal K., Basnayake O., Jayarajah U., Samarasekera D.N. Clinical outcomes and effectiveness of laser treatment for hemorrhoids: A systematic review. World J. Surg. 2021. No. 45. Pp. 1222-1236.
Leff E. Hemorrhoidectomy - laser vs. nonlaser: Outpatient surgical experience. Dis. Colon Rectum. 1992. No. 35 (8). Pp. 743-746.
Loder P.B., Kamm M.A., Nicholls R.J., Phillips R.K.S. Haemorrhoids: Pathology, pathophysiology and aetiology. Br. J. Surg. 1994. No. 8. Pp. 1946-1954.
Longchamp G., Liot E., Meyer J. et al. Non-excisional laser therapies for hemorrhoidal disease: A systematic review of the literature. Lasers in Medical Science. 2021. No. 36. Pp. 485-496.
Maloku H., Gashi Z., Lazovic R. et al. Laser hemorrhoidoplasty procedure vs open surgical hemorrhoidectomy: A trial comparing 2 treatments for hemorrhoids of third and fourth degree. A. Acta Inform Med. 2014. No. 22 (6). Pp. 365-367.
Minayev V.P. The dawn of use of laser radiation in domestic medicine. Photonics. 2017. No. 62 (2). Pp. 104-110.
Plapler H., Netto F., Pedro A.J. 350 ambulatory hemorrhoidectomies using a scanner coupled to a CO2 laser. J. Clin. Laser Med. Surg. 2000. No. 18. Pp. 259-262.
Plapler H., Hage R., Duarte J. et al. A new method for hemorrhoid surgery: Intrahemorrhoidal diode laser, does it work Photomedicine and Laser Surgery. 2009. No. 27 (5). Pp. 819-823.
Salfi R. A new technique for ambulatory hemorroidal treatment. Coloproctol. 2009. No. 31. Pp. 99-103.
Shimojima Y., Miyajima N. Matsushima M. Surgical Treatment for hemorrhoids, mainly performed in hospital. Nippon Daicho Komonbyo Gakkai Zasshi (Journal of the Japan Society of Coloproctology). 2021. No. 74 (10). Pp. 531-539.
Skobelkin O.K., Brekhov E.I., Korepanov V.I. Lasers in surgery and medicine a review of laser surgery in the U.S.S.R. Lasers in Surgery and Medicine. 1985. No. 5. Pp. 451-452.
Skobelkin O.K. Lasers in surgery. Moscow: Medicina, 1989.
Solovieva T. Low-level laser therapy. Proceedings of SPIE 4422, 2001.
Trigui A., Rejab H., Akrout A. et al. Laser utility in the treatment of hemorrhoidal pathology: A review of literature. Lasers in Medical Science. 2021, July 31.
Sokolov V.V., Chissov V.I., Yakubovskaya R.I. et al. Photodynamic therapy and laser-induced thermotherapy combination: New apparatus and first clinical experience in Russia. Proceedings of IPA 9th World Congress of the International Photodynamic Association (Miyzaki, Japan). 2003. No. 35.
Tsui C., Klein R., Garabrant M. Minimally invasive surgery: National trends in adoption and future directions for hospital strategy. Surg Endosc. 2013. No. 27. Pp. 2253-2257. Published online.
Usui Y. A new procedure of ICG enhanced diode laser therapy for hemorrhoids. Nippon Daicho Komonbyo Gakkai Zasshi (Journal of the Japan Society of Coloproctology). 2003. No. 56 (10). Pp. 815-818. (In Jap.)
Wang X., Yin X., Guo X.T. et al. Effects of the pestle needle therapy, a type of acupoint stimulation, on post-hemorrhoidectomy pain: A randomized controlled trial. J. of Integrative Med. 2020. No. 18 (6). Pp. 492-498.
Yamana T. Japanese practice guidelines for anal disorders: I. Hemorrhoids. Journal of the Anus, Rectum and Colon. 2017. No. 1 (3). Pp. 89-99.
Zhizhin N.K., Kolbas Yu.Yu., Nikitin S.A. et al. Innovative method of using diode laser in the treatment of hemorroidal disease. Quality. Innovations. Education. 2020. No. 6 (170). Pp. 99-104.
Zhizhin N.K., Kolbas Yu.Yu., Kuznetsov E.V. Application of lasers in surgery. Photonics. 2020. No. 14 (3). Pp. 282-291.
http://www.kremlin.ru/events/president/news/67740 (data obrashcheniya: 12.02.2022).
Keywords:
diode laser, optical fiber, laser medical technology, laser coagulation.
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