Red Light Therapy LED Bed - Whole Body Infrared Wellness Center Gym M6N Ultimate

Description: Please reach out with any questions you have about red light therapy and/or our innovative LED red light therapy bed. When you place your order, please message us with your choice of color for the bed: white or charcoal gray. Depending on when you order, there may be a difference in shipping/delivery time based on your color choice. If time is of the essence, just let us know you want the quickest available color. Advantages of M6NThe Merican LED Light Whole-body Therapy Bed-M6N is a kind of high-energy-density professional Photobiomodulation device for the human body. The M6N makes the light irradiation range stronger and more uniform stimulates the entire body in one treatment utilizing Stimu-LED diode technology and superposition effect of light.Patented independent separate fresh air duct system, the fresh air exchange volume inside the machine reaches 1300CFM, greatly improves the durability of LED lights and user comfort.With the patented technology wide-lamp-board heat dissipation scheme, combined with the constant current source scheme, the output power is increased by more than 4 times, and the comprehensive power saving is more than 50% at the same time.Beloved by patients and professionals, the Capsule targets more problem areas, faster and more effective than ever before. Features· Luxury front panel with brand shield and ambient flow light· Unique extra side cabin design· UK Lucite® Acrylic Sheet, up to 99% light transmittance· China Taiwan EPISTAR® LED chips· Patented technology wide-lamp-board heat dissipation scheme· Self-developed Constant current source scheme· Patented independent separate fresh air duct system.· Self-developed Wireless Smart Control System· Independent wavelengths control available· 0-100% duty cycle adjustable system· 0-50000Hz pulse adjustable system· Efficient 3 groups of standard light source combination solutions optional The Red Light Therapy Treatment Protocols eBook is included with your purchase (you can choose PDF or Kindle version). This eBook is full of valuable red light therapy information and research along with providing a couple dozen specific treatment procotols. You can search and view this eBook on Amazon under its title. Advantages of High Power Device Absorption into certain kinds of tissue (most notably, the tissue where a lot of water is present) can interfere with light photons passing through, and result in shallower tissue penetration. This means ample light photons are required to ensure that the maximum amount of light reaches the targeted tissue — and that requires a light therapy device with more power. Advantages of 660+850 As the two lights move through the tissue, both wavelengths will work together up to about 4 mm. After that, the 660 nm wavelengths are extinguished while the 850 nm wavelengths continue into slightly greater absorption depth more than 5 mm before extinguishing. This two-wavelength combination will help reduce the loss of energy that occurs as light photons pass through the body — and when you add longer wavelengths to the mix, you exponentially increase the number of light photons interacting with your cells. Advantages of 633+660+810+850+940 As the light photons enter the skin, all five wavelengths interact with the tissues they pass through. It’s very “bright” in the irradiated area, and this five-wavelength combination has a significant impact on the cells in the treatment area. Some of the light photons scatter and change direction, creating a “net” effect in the treatment area in which all wavelengths are active. This net effect receives the light energy of five different wavelengths.The net will also be bigger when you use a larger light therapy device; but for now, we’ll stay focused on how the individual light photons behave in the body. While the light energy does indeed dissipate as the light photons pass through the body, these distinct wavelengths work together to “saturate” the cells with more light energy.This spectral output results in an unprecedented synergy that ensures each layer of tissue — within the skin and below the skin — receives the maximum light energy possible. 633nm· Reduced fine lines and wrinkles · Improvement in chronic skin disorders · Hair regrowth · Reduce fatigue and muscle damage 850nm· Enhanced muscle recovery · Accelerate healing of post-surgical conditions 660nm 810nm· Reduced inflammation · Reduced neuropathic pain · Accelerated wound healing 940nm· Improved recovery from stroke in certain patients · Improved recovery from traumatic brain injury · Improvement in psychiatric disorders · Neuroprotective effect· Accelerated wound healing· Improves the nervedamage regeneration process · Decreased inflammation · Suppress Herpes Simplex Virus · Improved bone formation Theoretical supporting literature for the above role1. Alexander Wunschcorresponding, and Karsten Matuschka. (2014). A Controlled Trial to Determine the Efficacy of Red and Near-Infrared Light Treatment in Patient Satisfaction, Reduction of Fine Lines, Wrinkles, Skin Roughness, and Intradermal Collagen Density Increase. Photomed Laser Surg. 2014 Feb 1; 32(2): 93–100.2. Dr. Michael W. Berns PhD, Joan Coffey RN,Alan Wile MD, Mark Rettenmaier MD, Michael Berman MD, Philip Disaia MD, Gerald Weinstein MD, and Jerry McCullough PhD (1984). Response of psoriasis to red laser light (630 nm) following systemic injection of hematoporphyrin derivative. Lasers in Surgery and Medicine. Volume 4, Issue 1 p. 73-77.3. Hyojin Kim MD, Jee Woong Choi MD, Jun Young Kim MD, Jung Won Shin MD, Seok-jong Lee MD,PhD, and Chang-Hun Huh MD, PhD. (2013) Low-Level Light Therapy for Androgenetic Alopecia: A 24-Week, Randomized, Double-Blind, Sham Device–Controlled Multicenter Trial. Dermatologic Surgery. Volume 39, Issue 8 p. 1177- 1183.4. Cleber Ferraresi, Ricardo Vinicius Dos Santos, Guilherme Marques, Marcelo Zangrande, Roberley Leonaldo, Michael R Hamblin, Vanderlei Salvador Bagnato, and Nivaldo Antonio Parizotto. (2015). Light-emitting diode therapy (LEDT) before matches prevents increase in creatine kinase with a light dose response in volleyball players. Lasers Med Sci. 2015 May; 30(4):1281-7.5. Emerson S. Boschi MS, Carlos E. Leite MS,Vasyl C. Saciura MS, Eduardo Caberlon MS, Adroaldo Lunardelli MS,Shanna Bitencourt MS, Denizar A.S. Melo PhD, and Jarbas R. Oliveira PhD. (2008). Anti-Inflammatory effects of low-level laser therapy (660 nm) in the early phase in carrageenan-induced pleurisy in rat. Lasers in Surgery and Medicine. Volume 40, Issue 7 p. 500- 508.6. M. Masoumipoor, S. B. Jameie, A. Janzadeh, F. Nasirinezhad, M. Soleimani, and M. Kerdary. (2014). Effects of 660- and 980-nm low- level laser therapy on neuropathic pain relief following chronic constriction injury in rat sciatic nerve. Lasers in Medical Science. volume 29, p1593–1598.7. Fábio Colombo, Alberto de Aguiar Pires Valença Neto, Ana Paula Cavalcanti de Sousa, Antônio Márcio Teixeira Marchionni, Antônio Luiz Barbosa Pinheiro, and Silvia Regina de Almeida Reis. (2013). Effect of Low-Level Laser Therapy (λ660 nm) on Angiogenesis in Wound Healing: A Immunohistochemical Study in a Rodent Model. Braz. Dent. J. 24 (4).8. Yair Lampl 1, Justin A Zivin, Marc Fisher, Robert Lew, Lennart Welin, Bjorn Dahlof, Peter Borenstein, Bjorn Andersson, Julio Perez, Cesar Caparo, Sanja Ilic, and Uri Oron. (2007). Infrared laser therapy for ischemic stroke: a new treatment strategy: results of the NeuroThera Effectiveness and Safety Trial-1 (NEST-1). Randomized Controlled Trial. Stroke. 2007 Jun; 38(6):1843-9.9. Amir Oron, Uri Oron, Jackson Streeter, and Luis De Taboada. (2007). Low-Level Laser Therapy Applied Transcranially to Mice following Traumatic Brain Injury Significantly Reduces Long-term Neurological Deficits. Journal of Neurotrauma 24(4):651-6.10. Fredric Schiffer, Andrea L Johnston, Caitlin Ravichandran, Ann Polcari, Martin H Teicher, Robert H Webb, and Michael R Hamblin. (2009). Psychological benefits 2 and 4 weeks after a single treatment with near infrared light to the forehead: a pilot study of 10 patients with major depression and anxiety. Behav Brain Funct. 2009; 5: 46.11. Farzad Salehpour, Javad Mahmoudi, Farzin Kamari, Saeed Sadigh-Eteghad, Seyed Hossein Rast, and Michael R Hambline. (2018). Brain Photobiomodulation Therapy: A Narrative Review. Mol Neurobiol. 2018 Aug; 55(8): 6601–6636.12. Ludmila Dancáková, MSc, Tomáš Vasilenko, MD, Ivan Kováč, MD, Katarína Jakubčová, MSc, Martin Hollý, MSc, Viera Revajová, DVM, PhD, František Sabol, MD, PhD, Zoltán Tomori, PhD, Marjolein Iversen, RN, PhD, Peter Gál, PhD, and Jan M. Bjordal, PT, PhD. (2014). Low-Level Laser Therapy with 810 nm Wavelength Improves Skin Wound Healing in Rats with Streptozotocin- Induced Diabetes. Photomed Laser Surg. 2014 Apr 1; 32(4): 198–204.13. Cleber Ferraresi, Ying-Ying Huang, and Michael R. Hamblin. (2016). Photobiomodulation in human muscle tissue: an advantage in sports performance?. J Biophotonics. 2016 Dec; 9(11-12): 1273–1299.14. Gary Lask, Nathalie Fournier, Mario Trelles, Monica Elman, Michael Scheflan, Michael Slatkine, Jenny Naimark, and Yoram Harth. (2005). The utilization of nonthermal blue (405-425 nm) and near infrared (850-890 nm) light in aesthetic dermatology and surgery-a multicenter study. Controlled Clinical Trial > J Cosmet Laser Ther. 2005 Dec;7(3-4):163-70.15. Karla Guivernau Gaudens Serafim, Solange De Paula Ramos, Franciele Mendes de Lima, and Marcelo Carandina. (2011) Effects of 940 nm light- emitting diode (led) on sciatic nerve regeneration in rats. Lasers in Medical Science. May 2011 27(1):113-9.16. Priscila D'Andrea Fonseca, Franciele Mendes de Lima, Dayla Thyemi Higashi, Débora Fernanda Volttani Koyama, Dari de Oliveira Toginho Filho, Ivan Frederico Lupiano Dias, and Solange de Paula Ramos. (2013). Effects of light emitting diode (LED) therapy at 940 nm on inflammatory root resorption in rats. Lasers Med Sci. 2013 Jan; 28(1):49-55.17. Mahsa Alavi Namvar, Mohammad Vahedi, Hamid-Reza Abdolsamadi, Alireza Mirzaei, Younes Mohammadi, and Farid Azizi Jalilian. (2019). Effect of photodynamic therapy by 810 and 940 nm diode laser on Herpes Simplex Virus 1: An in vitro study. Photodiagnosis Photodyn Ther. 2019 Mar;25:87-91.18. Mohammed Mahmood Jawad, Adam Husein, Ahmad Azlina, Mohammad Khursheed Alam, Rozita Hassan, and Rumaizi Shaari. (2013). Effect of 940 nm low-level laser therapy on osteogenesis in vitro. J Biomed Opt. 2013 Dec;18(12):128001.19. Emily Tierney, and C William Hanke. (2009). Randomized controlled trial: Comparative efficacy for the treatment of facial telangiectasias with 532 nm versus 940 nm diode laser. Randomized Controlled Trial > Lasers Surg Med. 2009 Oct;41(8):555-62.

Price: 29900 USD

Location: Missoula, Montana

End Time: 2024-09-29T15:45:32.000Z

Shipping Cost: 0 USD