Pediatric research
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The aim of this study was to produce a neonatal piglet model which, avoiding vessel ligation, exposed the whole animal to hypoxia and produced dose-dependent clinical encephalopathy and neuropathologic damage similar to that seen after birth asphyxia. Twenty-three piglets were halothane-anesthetized. Hypoxia was induced in 19 piglets by reducing the fractional concentration of inspired oxygen (FiO2) to the maximum concentration at which the EEG amplitude was below 7 microV (low amplitude) for 17-55 min. ⋯ We conclude that EEG-controlled hypoxia and subsequent intensive care enabled the animals to survive with an encephalopathy which correlated with the cerebral hypoxic insult. The encephalopathy was clinically, electrophysiologically, and neuropathologically similar to that in the asphyxiated term infant. This model is suitable for examining mechanisms of damage and evaluation of potential protective therapies after birth asphyxia.
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Because the antiprotease defense in cystic fibrosis (CF) airways is overwhelmed by neutrophil elastase (NE), substitution of antiproteases such as secretory leukoprotease inhibitor (SLPI) seems to be a reasonable therapeutic approach. Knowing, however, that native antiproteases may be liable to rapid inactivation by the locally abundant oxidants, we comparatively investigated the interactions of CF sputum with recombinant native SLPI (rSLPI) and its partially oxidation-resistant variant (rSLPI-242), respectively, to estimate their therapeutic potentials. NE activity in supernatants from diluted CF sputum samples was dose-dependently inhibited by both rSLPI and rSLPI-242, with comparable potency. ⋯ Furthermore, secretion of radiolabeled macromolecules from porcine tracheal glands induced by purified NE or by CF sputum was inhibited dose-dependently by rSLPI and even better by rSLPI-242. We conclude that both rSLPI and rSLPI-242 effectively inhibit NE activity and NE-induced gland hypersecretion in vitro. In vivo effects of CF remain to be analyzed; an advantage of the partially oxidation-resistant rSLPI-242 can be expected.