Articles: respiratory-distress-syndrome.
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The intravascular oxygenator and carbon dioxide removal device (IVOX; CardioPulmonics, Salt Lake City, UT) has been shown to perform 30% of the gas exchange in animals and patients with acute respiratory failure. Among the factors that limit gas exchange is the mass transfer resistance in the blood phase. To determine if a reduction in mass transfer resistance by mixing venous blood can enhance the O2 transfer and CO2 removal by IVOX, a right atrium-pulmonary artery venovenous bypass circuit was used in sheep to model the adult vena cava. ⋯ It is concluded that reduction in the mass transfer resistance by blood mixing improves gas exchange. Because O2 is more diffusion limited, it is more dependent upon mixing of blood for gas exchange than CO2. More design improvements to incorporate active mixing may further enhance the gas exchange performance of IVOX.
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Multicenter Study Clinical Trial
Respiratory distress syndrome in New Zealand: evidence from the OSIRIS trial of exogenous surfactant (Exosurf).
To assess the impact, mortality, morbidity and economic costs, of respiratory distress syndrome severe enough to warrant ventilation in one year in New Zealand. ⋯ In a full year (total births 60,000) approximately 350 New Zealand infants may require ventilation for respiratory distress syndrome. Increasing the percentage of infants who receive antenatal steroids is likely to be extremely cost effective. In the era of antenatal steroids and exogenous surfactant, 85% of infants with respiratory distress syndrome requiring ventilation survive to discharge home and over 90% of survivors are likely to be healthy normal adults.
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To assess the clinical consequences of duration of adult respiratory distress syndrome (ARDS) on lung structure and function. ⋯ The lung structure and function changes markedly with ARDS duration, and the late stages may be described as restrictive lung disease with superimposed emphysemalike lesions. Presence of pneumothorax affects survival and appears to be related to the lung structural changes occurring with time.
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Critical care medicine · Jun 1994
Comparative StudyInduction of the heat shock response reduces mortality rate and organ damage in a sepsis-induced acute lung injury model.
To test the hypothesis that induction of heat shock proteins before the onset of sepsis could prevent or reduce organ injury and death in a rat model of intra-abdominal sepsis and sepsis-induced acute lung injury produced by cecal ligation and perforation. ⋯ These data suggest that thermal pretreatment, associated with the synthesis of heat shock proteins, reduces organ damage and enhances animal survival in experimental sepsis-induced acute lung injury. Although the mechanisms by which heat shock proteins exert a protective effect are not well understood, these data raise interesting questions regarding the importance of fever in the protection of the whole organism during bacterial infection.
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The Journal of pediatrics · Jun 1994
Acute effects of inhaled nitric oxide in children with severe hypoxemic respiratory failure.
To determine the physiologic effects of inhaled nitric oxide (NO) on oxygenation and hemodynamics in children with severe hypoxemic respiratory failure, we studied the acute response to inhaled NO during mechanical ventilation in 17 pediatric patients. Diagnoses included adult respiratory distress syndrome (ARDS) (10 patients), bronchopulmonary dysplasia with viral pneumonitis (6 patients), and acute pneumonitis, caused by respiratory syncytial virus, without chronic lung disease (1 patient). Gas exchange and hemodynamic measurements were compared before and during exposure to inhaled NO (20 ppm) without changing ventilator settings for 30 minutes. ⋯ Fifteen patients were subsequently treated with low-dose inhaled NO (3 to 10 ppm) for 1 to 24 days; 5 (50%) of 10 patients with ARDS and 7 (100%) of the 7 non-ARDS patients survived. We conclude that inhaled NO acutely improves oxygenation and lowers pulmonary vascular resistance without causing adverse hemodynamic effects in severe hypoxemic respiratory failure in pediatric patients. Inhaled NO may be a useful adjuvant therapy in children with acute hypoxemic respiratory failure, including infants with bronchopulmonary dysplasia, but whether prolonged low-dose inhalational NO therapy can reduce morbidity or improve survival rates remains unknown.