Beta-amyloid is a major constituent of senile plaques that occur in the brains of Alzheimer's disease (AD) patients. Cell culture studies have shown that high concentrations of beta-amyloid are toxic and damage biological macromolecules. A number of experiments have shown that melatonin is a potent antioxidant. Melatonin not only neutralizes oxygen-derived free radicals but can also scavenge species of other types such as carbon-centered free radicals. The present study was designed to determine whether beta-amyloid toxicity would cause lipid peroxidation of human platelet membranes. Since aluminum has been implicated in the etiology of AD, we investigated the effects of aluminum on lipid peroxidation and whether the harmful effects of beta-amyloid are aggravated by aluminum. We also investigated whether melatonin had the ability to protect against beta-amyloid toxicity. Our results indicate that both beta-amyloid and aluminum dose-dependently increased lipid peroxidation in platelet membranes. Aluminum was more potent than beta-amyloid. Incubation of platelet membranes with increasing concentrations of aluminum in the presence of 100 microM beta-amyloid (fragment 25-35) resulted in lipid peroxidation levels of similar magnitude as the two substances, respectively. Prior administration of melatonin dose-dependently inhibited this effect. These results confirm the toxic effects of beta-amyloid to biological membranes. While aluminum itself damages membranes, its presence did not exacerbate the toxic effects of beta-amyloid. Melatonin effectively reduced the lipid peroxidation induced by beta-amyloid and aluminum, suggesting that its supplementation to AD patients may be beneficial.
BackgroundIn a recent study utilizing a saline-lavaged adult rabbit model, we described a significant improvement in systemic oxygenation and pulmonary shunt after the instillation of a novel synthetic peptide-containing surfactant, Synsurf. Respiratory distress syndrome in the preterm lamb more closely resembles that of the human infant, as their blood gas, pH values, and lung mechanics deteriorate dramatically from birth despite ventilator support. Moreover, premature lambs have lungs which are mechanically unstable, with the advantage of being able to measure multiple variables over extended periods. Our objective in this study was to investigate if Synsurf leads to improved systemic oxygenation, lung mechanics, and histology in comparison to the commercially available porcine-derived lung surfactant Curosurf® when administered before first breath in a preterm lamb model.Materials and methodsA Cesarean section was performed under general anesthesia on 18 time-dated pregnant Dohne Merino ewes at 129–130 days gestation. The premature lambs were delivered and ventilated with an expiratory tidal volume of 6–8 mL/kg for the first 30 minutes and thereafter at 8–10 mL/kg. In a randomized controlled trial, the two surfactants tested were Synsurf and Curosurf®, both at a dose of 100 mg/kg phospholipids (1,2-dipalmitoyl-L-α-phosphatidylcholine; 90% in Synsurf, 40% in Curosurf®). A control group of animals was treated with normal saline. Measurements of physiological variables, blood gases, and lung mechanics were made before and after surfactant and saline replacement and at 15, 30, 45, 60, 90, 120, 180, 240 and 300 minutes after treatment. The study continued for 5 hours.ResultsSurfactant treatment led to a significant improvement in oxygenation within 30 minutes, with the Synsurf group and the Curosurf® group having significantly higher ratios between arterial partial pressure of oxygen/fraction of inspired oxygen (PaO2/FiO2; P = 0.021) compared to that of the control (saline-treated) animals. Dynamic compliance improved in the three groups over time, with no intergroup differences. All of the surfactant-treated animals survived, and one in the saline group died before the study ended. Histology between groups was not different, showing mild–moderate injury patterns.Discussion: Treatment with surfactants before first breath clearly resulted in improved systemic oxygenation within 30 minutes of instillation. Both Synsurf- and Curosurf®-treated animals experienced similar and more sustained improvement in oxygenation and decreased calculated shunt compared to saline-treated animals.
The free radical scavenging abilities of the structurally related steroids beta-sitosterol, beta-sitosterol glucoside (plant sterols and sterolins), cholesterol, and dehydroepiandrosterone sulphate (DHEAS) were compared with melatonin (an efficient free radical scavenger) in an in vitro system which measures lipid peroxidation of platelet membranes in the presence of iron (Fe2+). Lipid peroxidation is a process whereby cellular membranes are damaged due to the oxidative deterioration of polyunsaturated lipids, which may lead to cell death and disease in living organisms. Substances such as vitamin E protect cellular membranes against oxidative damage due to their chemical structures. The steroids cholesterol, beta-sitosterol, beta-sitosterol glucoside and dehydroepiandrosterone (DHEA) are structurally related to each other. During aging, serum concentrations of DHEA, DHEAS and melatonin decrease, while the concentration of cholesterol tends to increase. The aim of the present study was to compare the role these substances play in lipid peroxidation over a wide concentration range. At concentrations lower than the free iron in the reaction mixture, all the steroids investigated decreased lipid peroxidation. At higher concentrations, cholesterol and beta-sitosterol increased lipid peroxidation, while DHEAS and melatonin continued to decrease lipid peroxidation.
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