Recherches Scientifiques myLEDmask | Études Scientifiques
Découvrez les études scientifiques et références cliniques qui prouvent l'efficacité de myLEDmask2. Transparence totale sur notre approche beauty-tech.

Chez myBlend, chaque innovation repose sur des années de recherche clinique. Voici les 28 études qui ont guidé le développement de notre masque LED nouvelle génération.

  1. Karu, T., Primary and secondary mechanisms of action of visible to near-IR radiation on cells. J Photochem Photobiol B, 1999. 49(1): p. 1-17.
  2. Karu, T. and S.F. Kolyakov, Exact action spectra for cellular responses relevant to phototherapy. Photomed Laser Surg, 2005. 23(4): p. 355-61.
  3. Avci, P., et al., Low-level laser (light) therapy (LLLT) in skin: stimulating, healing, restoring. Semin Cutan Med Surg, 2013. 32(1): p. 41-52.
  4. Barolet, D., Light-emitting diodes (LEDs) in dermatology. Semin Cutan Med Surg, 2008. 27(4): p. 227-38.
  5. Barolet, D., Photobiomodulation in dermatology: harnessing light from visible to near infrared. Medical Research Archives, 2018. 6(1).
  6. Barolet, D., et al., Regulation of skin collagen metabolism in vitro using a pulsed 660 nm LED light source: clinical correlation with a single blinded study. Journal of investigative dermatology, 2009. 129(12): p. 2751-2759.
  7. Zein, R., W. Selting, and M.R. Hamblin, Review of light parameters and photobiomodulation efficacy: dive into complexity. Journal of biomedical
    optics, 2018. 23(12): p. 120901.
  8. Barolet, D., et al., Importance of pulsing illumination parameters in low-level-light therapy. Journal of biomedical optics, 2010. 15(4): p. 048005.
  9. Hashmi, J.T., et al., Effect of pulsing in low-level light therapy. Lasers in surgery and medicine, 2010. 42(6): p. 450-466.
  10. Lima, A.M.C.T., L.P. da Silva Sergio, and A.d.S. da Fonseca, Photobiomodulation via multiple-wavelength radiations. Lasers in medical science, 2020. 35(2): p. 307-316.
  11. McDaniel, D., et al., Varying ratios of wavelengths in dual wavelength LED photobiomodulation alters gene expression profiles in human skin
    fibroblasts. Lasers in surgery and medicine, 2010. 42(6): p. 540-545.
  12. Hamblin, M.R., Mechanisms and applications of the anti-inflammatory effects of photobiomodulation. AIMS biophysics, 2017. 4(3): p. 337.
  13. Noé, C., Photobiomodulation en dermatologie: Comprendre et utiliser les LED. 2014: Doin.
  14. Tseng, S.-H., et al., Chromophore concentrations, absorption and scattering properties of human skin in-vivo. Optics express, 2009. 17(17): p. 14599-14617.
  15. Linares, S.N., et al., Photobiomodulation effect on local hemoglobin concentration assessed by near-infrared spectroscopy in humans. Lasers in medical science, 2020. 35(3): p. 641-649.
  16. Karu, T., How the absorption of monochromatic visible-to-near IR radiation by cells leads to their biological responses?, in Energy And
    Information Transfer In Biological Systems: How Physics Could Enrich Biological Understanding. 2003, World Scientific. p. 148-156.
  17. Nkengne, A., et al., Visible characteristics and structural modifications relating to enlarged facial pores. Skin Research and Technology, 2020.
  18. Ma, H., et al., Effect of low-level laser therapy on proliferation and collagen synthesis of human fibroblasts in vitro. Journal of wound
    management and research, 2018. 14(1): p. 1-6.
  19. Houreld, N.N., P.R. Sekhejane, and H. Abrahamse, Irradiation at 830 nm stimulates nitric oxide production and inhibits pro-inflammatory
    cytokines in diabetic wounded fibroblast cells. Lasers in surgery and medicine, 2010. 42(6): p. 494-502.
  20. Lee, S.Y., et al., A prospective, randomized, placebo-controlled, double-blinded, and split-face clinical study on LED phototherapy for skin
    rejuvenation: clinical, profilometric, histologic, ultrastructural, and biochemical evaluations and comparison of three different treatment settings. Journal of Photochemistry and Photobiology B: Biology, 2007. 88(1): p. 51-67.
  21. Sommer, A.P., et al., Biostimulatory windows in low-intensity laser activation: lasers, scanners, and NASA's light-emitting diode array system. Journal of clinical laser medicine & surgery, 2001. 19(1): p. 29-33.
  22. Smith, K.C., The photobiological basis of low level laser radiation therapy. Laser Therapy, 1991. 3(1): p. 19-24
  23. Ryabykh, T. and T. Karu. Action of pulsed visible and near-IR laser radiation on oxidative metabolism of cells evaluated by chemiluminescence measurement. in Effects of Low-Power Light on Biological Systems. 1996. International Society for Optics and Photonics.
  24. Al-Watban, F.A. and X. Zhang, The comparison of effects between pulsed and CW lasers on wound healing. Journal of clinical laser medicine & surgery, 2004. 22(1): p. 15-18.
  25. Karsten, A.E. and J.E. Smit, Modeling and verification of melanin concentration on human skin type. Photochemistry and photobiology, 2012. 88(2): p. 469-474.
  26. Montagna, W. and K. Carlisle, The architecture of black and white facial skin. Journal of the American Academy of Dermatology, 1991. 24(6): p. 929-937.
  27. Souza-Barros, L., et al., Skin color and tissue thickness effects on transmittance, reflectance, and skin temperature when using 635 and 808 nm lasers in low intensity therapeutics. Lasers in surgery and medicine, 2018. 50(4): p. 291-301.
  28. Barolet, A.C., I.V. Litvinov, and D. Barolet, Beneficial Effects of Near-Infrared Light Photobiomodulation in Linear Morphea: A Case Report.
    Photobiomodul Photomed Laser Surg, 2020. 38(11): p. 679-682.