Low Level Laser Therapy Reduces the Development of Lung Inflammation Induced by Formaldehyde Exposure.

Lung diseases constitute an important public health problem and its growing level of concern has led to efforts for the development of new therapies, particularly for the control of lung inflammation. Low Level Laser Therapy (LLLT) has been highlighted as a non-invasive therapy with few side effects, but its mechanisms need to be better understood and explored. Considering that pollution causes several harmful effects on human health, including lung inflammation, in this study, we have used formaldehyde (FA), an environmental and occupational pollutant, for the induction of neutrophilic lung inflammation. Our objective was to investigate the local and systemic effects of LLLT after FA exposure. Male Wistar rats were exposed to FA (1%) or vehicle (distillated water) during 3 consecutive days and treated or not with LLLT (1 and 5 hours after each FA exposure). Non-manipulated rats were used as control. 24 h after the last FA exposure, we analyzed the local and systemic effects of LLLT. The treatment with LLLT reduced the development of neutrophilic lung inflammation induced by FA, as observed by the reduced number of leukocytes, mast cells degranulated, and a decreased myeloperoxidase activity in the lung. Moreover, LLLT also reduced the microvascular lung permeability in the parenchyma and the intrapulmonary bronchi. Alterations on the profile of inflammatory cytokines were evidenced by the reduced levels of IL-6 and TNF-α and the elevated levels of IL-10 in the lung. Together, our results showed that LLLT abolishes FA-induced neutrophilic lung inflammation by a reduction of the inflammatory cytokines and mast cell degranulation. This study may provide important information about the mechanisms of LLLT in lung inflammation induced by a pollutant.

Formaldehyde inhalation during pregnancy abolishes the development of acute innate inflammation in offspring.

Formaldehyde (FA) is an environmental and occupational pollutant that induces programming mechanisms on the acquired immune host defense in offspring when exposed during the prenatal period. Hence, here we investigated whether the exposure of FA on pregnant rats could affect the development of an innate acute lung injury in offspring induced by lipopolissacaride (LPS) injection. Pregnant Wistar rats were exposed to FA (0.92 mg/m(3)) or vehicle (distillated water), both 1 h/day, 5 days/week, from 1 to 21 days of pregnancy. Non-manipulated rats were used as control. After 30 days of birth, the offspring was submitted to injection of LPS (Salmonella abortus equi, 5 mg/kg, i.p.). Systemic and lung inflammatory parameters were evaluated 24 h later. Exposure to FA during gestation abolished the development of acute lung injury in offspring, as observed by reduced number of leukocytes in the bronchoalveolar fluid (BAL), in the blood and in the bone marrow, and decreased myeloperoxidase activity in the lung. Moreover, phagocytes from BAL presented normal phagocytosis, but reduced oxidative burst. Alterations on the profile of inflammatory cytokines were evidenced by reduced mRNA levels of IL-6 and elevated levels of IL-10 and IFN gamma in the lung tissue. Indeed, mRNA levels of toll-likereceptor-4 and nuclear factor-kappa B translocation into the nucleus were also reduced. Additionally, hyperresponsiveness to methacholine was blunted in the trachea of offspring of FA exposed mothers. Together, our data clearly show that FA exposure in the prenatal period modifies the programming mechanisms of the innate defense in the offspring leading to impaired defense against infections.