Page 231 - Veterinary Laser Therapy in Small Animal Practice

P. 231

References 217

procedural assessments and meta-analysis of low level irradiation stimulates wound healing in diabetic wounded
laser therapy in lateral elbow tendinopathy (tennis elbow). fibroblast cells (WS1). Diabetes Technol Ther, 2010.
BMC Musculoskelet Disord, 2008. 9: p. 75. 12(12): pp. 971–8.
102. Bjordal, J.M., et al. A systematic review of low level 116. Jere, S.W., N.N. Houreld, and H. Abrahamse.
laser therapy with location-specific doses for pain from Photobiomodulation at 660nm stimulates proliferation
chronic joint disorders. Aust J Physiother, 2003. 49(2): pp. and migration of diabetic wounded cells via the expression
107–16. of epidermal growth factor and the JAK/STAT pathway. J
103. Fulop, A.M., et al. A meta-analysis of the efficacy of Photochem Photobiol B, 2018. 179: pp. 74–83.
laser phototherapy on pain relief. Clin J Pain, 2010. 26(8): 117. Hawkins, D.H. and H. Abrahamse. The role of laser
pp. 729–36. fluence in cell viability, proliferation, and membrane
104. Kreisler, M.B., et al. Efficacy of low level laser therapy integrity of wounded human skin fibroblasts following
in reducing postoperative pain after endodontic surgery–a helium-neon laser irradiation. Lasers Surg Med, 2006.
randomized double blind clinical study. Int J Oral 38(1): pp. 74–83.
Maxillofac Surg, 2004. 33(1): pp. 38–41. 118. Goncalves, W.L., et al. Influence of He-Ne laser
105. Moore, K.C., et al. The effect of infra-red diode laser therapy on the dynamics of wound healing in mice treated
irradiation on the duration and severity of postoperative with anti-inflammatory drugs. Braz J Med Biol Res, 2007.
pain: a double blind trial. Laser Ther, 1992. 4(4): pp. 40(6): pp. 877–84.
145–9. 119. Meireles, G.C., et al. Effectiveness of laser
106. Ojea, A.R., et al. Beneficial effects of applying low- photobiomodulation at 660 or 780 nanometers on the
level laser therapy to surgical wounds after bariatric repair of third-degree burns in diabetic rats. Photomed
surgery. Photomed Laser Surg, 2016. 34(11): pp. 580–4. Laser Surg, 2008. 26(1): pp. 47–54.
107. Nesioonpour, S., et al. Does low-level laser therapy 120. Kayak, B.S., A. Maiya, and P. Kumar. Influence
enhance the efficacy of intravenous regional anesthesia? of helium-neon laser photostimulation on excision
Pain Res Manag, 2014. 19(6): pp. e154–8. wound healing in Wistar rats. OnLine J Biol Sci, 7(2): pp.
108. Ribas, E.S., et al. Use of low intensity laser 89–92.
treatment in neuropathic pain refractory to clinical 121. Novaes, R.D., et al. The energy density of laser
treatment in amputation stumps. Int J Gen Med, 2012. 5: light differentially modulates the skin morphological
pp. 739–42. reorganization in a murine model of healing by secondary
109. Falaki, F., A.H. Nejat, and Z. Dalirsani. The effect of intention. Int J Exp Pathol, 2014. 95(2): pp. 138–46.
low-level laser therapy on trigeminal neuralgia: A review 122. Demidova-Rice, T.N., et al. Low-level light stimulates
of literature. J Dent Res Dent Clin Dent Prospects, 2014. excisional wound healing in mice. Lasers Surg Med, 2007.
8(1): pp. 1–5. 39(9): pp. 706–15.
110. de Andrade, A.L., P.S. Bossini, and N.A. Parizotto. 123. Gonzaga Ribeiro, M.A., et al. Morphological analysis
Use of low level laser therapy to control neuropathic pain: of second-intention wound healing in rats submitted to 16
A systematic review. J Photochem Photobiol B, 2016. 164: J/cm2 lambda 660-nm laser irradiation. Indian J Dent Res,
pp. 36–42. 2009. 20(3): p. 390.
111. Roberts, D.B., R.J. Kruse, and S.F. Stoll. The 124. Sperandio, F.F., et al. Low-level laser irradiation
effectiveness of therapeutic class IV (10 W) laser promotes the proliferation and maturation of
treatment for epicondylitis. Lasers Surg Med, 2013. 45(5): keratinocytes during epithelial wound repair. J
pp. 311–7. Biophotonics, 2015. 8(10): pp. 795–803.
112. Basso, F.G., et al. Biostimulatory effect of low-level 125. Gagnon, D., et al. An in vitro method to test the
laser therapy on keratinocytes in vitro. Lasers Med Sci, safety and efficacy of low-level laser therapy (LLLT) in the
2013. 28(2): pp. 367–74. healing of a canine skin model. BMC Vet Res, 2016. 12: p.
113. Arany, P.R., et al. Activation of latent TGF-beta1 by 73.
low-power laser in vitro correlates with increased TGF- 126. Liao, X., et al. Helium-neon laser irradiation promotes
beta1 levels in laser-enhanced oral wound healing. Wound the proliferation and migration of human epidermal stem
Repair Regen, 2007. 15(6): pp. 866–74. cells in vitro: proposed mechanism for enhanced wound
114. Saygun, I., et al. Effects of laser irradiation on the re-epithelialization. Photomed Laser Surg, 2014. 32(4): pp.
release of basic fibroblast growth factor (bFGF), insulin 219–25.
like growth factor-1 (IGF-1), and receptor of IGF-1 127. Stadler, I., et al. 830-nm irradiation increases the
(IGFBP3) from gingival fibroblasts. Lasers Med Sci, 2008. wound tensile strength in a diabetic murine model. Lasers
23(2): pp. 211–5. Surg Med, 2001. 28(3): pp. 220–6.
115. Houreld, N. and H. Abrahamse. Low-intensity laser 128. Peplow, P.V., T.Y. Chung, and G.D. Baxter. Laser

REDONDO PRINT (4-COL BLEED).indd 217 08/08/2019 09:51

226 227 228 229 230 231 232 233 234 235 236