Effect of the transdermal low-level laser therapy on endothelial function.

The effect of low-level laser therapy (LLLT) on the cardiovascular system is not fully established. Since the endothelium is an important endocrine element, establishing the mechanisms of LLLT action is an important issue.The aim of the study was to evaluate the effect of transdermal LLLT on endothelial function.In this study, healthy volunteers (n = 40, age = 20-40 years) were enrolled. N = 30 (14 female, 16 male, mean age 30 ± 5 years) constituted the laser-irradiated group (LG). The remaining 10 subjects (6 women, 4 men, mean age 28 ± 5 years) constituted the control group (CG). Participants were subjected to LLLT once a day for three consecutive days. Blood for biochemical assessments was drawn before the first irradiation and 24 h after the last session. In the LG, transdermal illumination of radial artery was conducted (a semiconductor laser λ = 808 nm, irradiation 50 mW, energy density 1.6 W/cm(2) and a dose 20 J/day, a total dose of 60 J). Biochemical parameters (reflecting angiogenesis: vascular endothelial growth factor (VEGF), fibroblast growth factor (FGF), angiostatin; antioxidative status: glutathione (GSH) and the nitric oxide metabolic pathway: symmetric dimethylarginine (SDMA), asymmetric dimethylarginine (ADMA) and L-arginine) were assessed. In the LG, a significant increase in GSH levels and considerable decrease in angiostatin concentration following the LLLT were observed. No significant differences in levels of the VEGF, FGF, SDMA, ADMA were observed.LLLT modifies vascular endothelial function by increasing its antioxidant and angiogenic potential. We found no significant differences in levels of the nitric oxide pathway metabolites within 24 h following the LLLT irradiation.

Both in vitro and in vivo irradiation are associated with induction of macrophage-derived fibroblast growth factors.

Fibrosis in the lung directly underlying the field of irradiation is an almost universal long term sequelae of thoracic irradiation. It is assumed to represent the consequence of direct damage to local tissues and/or vascular endothelium by ionizing radiation. This view, however, is not in keeping with our current understanding of fibrotic processes, which suggest that growth factors for fibroblasts (including platelet-derived growth factor (PDGF), insulin-like growth factor I (IGF-I)) and cytokines stimulating collagen synthesis (notably transforming growth factor-beta) are largely responsible for this process. Since a major source of these factors is the macrophage, present in large numbers within the lung, it appeared possible that radiation-induced fibrosis might be mediated by similar mechanisms. Therefore, a study was designed to determine, first, whether in vitro irradiation of mononuclear phagocytes could induce the release of growth factors for fibroblasts. Second, we wished to ascertain whether these same growth factors might also be secreted by bronchoalveolar cells from humans who had undergone in vivo thoracic irradiation. The results of this study indicate that irradiation of a number of different types of mononuclear phagocytes resulted in the dose-dependent synthesis and release of several growth factors for fibroblasts, including PDGF, tumour factor-alpha (TNF-alpha) and IGF-I. Further, cells obtained by bronchoalveolar lavage from patients undergoing thoracic radiation spontaneously released PDGF following irradiation. These findings strongly support the contention that synthesis and release of macrophage-derived growth factors for fibroblasts (particularly PDGF and IGF-I) occur after thoracic irradiation and play a significant role in the pathogenesis of irradiation-induced pulmonary fibrosis in humans.