Gas chromatography/negative ion chemical ionization triple quadrupole mass spectrometric determination and pharmacokinetics of 11 alpha-hydroxy-9,15-dioxo-2,3,4,5,20-pentanor-19-carboxyprostan oic acid in plasma

Systemic levels following PGE1 inhalation in neonatal hypoxemic respiratory failure

AIM

To measure plasma prostaglandin E1 (PGE1) levels in newborns with hypoxemic respiratory failure (NHRF) following inhaled PGE1 (IPGE1), normal term newborns, and newborns with congenital heart disease (CHD) following intravenous PGE1.

METHODS

Twenty newborns with NHRF received IPGE1 by jet nebulizer in doses of 25, 50, 150, and 300 ng/kg/min followed by weaning. Blood for PGE1 assay using enzyme immunoassay was available in eight neonates with NHRF, 10 normal newborns, and three neonates with CHD.

RESULTS

There were no differences in PGE1 levels between cord arterial blood in normal newborns and baseline samples from newborns with NHRF. Oxygenation improved significantly following IPGE1 (p=0.024) in newborns with NHRF. No adverse events were identified. Although a reversible increase in PGE1 levels was detected following a dose of 50 ng/kg/min (p<0.05), there was no association between PGE1 levels and IPGE1 duration, PaO2, temperature, heart rate, and blood pressure.

CONCLUSION

A reversible increase in mean PGE1 levels was demonstrable at low doses of IPGE1 in babies with NHRF using a sensitive assay, suggesting effective drug delivery. Levels did not increase further with increasing dose or duration of administration, suggesting local action in the lungs and a lack of systemic spillover due to extensive pulmonary metabolism offering pulmonary selectivity.

Plasma prostaglandin E1 concentrations and hemodynamics during intravenous infusions of prostaglandin E1 in humans and swine

Prostaglandin (PG) E1 administered intravenously has been used for the treatment of primary nonfunction of hepatic allografts and fulminant hepatic failure. It has been proposed that this therapy may improve hepatic blood flow via the vasodilating properties of PGE1. However, PGE1 undergoes extensive metabolic inactivation by the lung and the concentration of PGE1 reaching the liver during intravenous administration has not been determined. Thus, we measured plasma PGE1 concentrations in patients with hepatic dysfunction being treated with PGE1 and in a swine model of PGE1 infusion. We also determined the hemodynamic effects of PGE1 infusion in swine. Blood was sampled from the pulmonary artery, carotid artery, portal vein, and hepatic vein in swine infused with PGE1 (range, 0.67-4.9 microg/kg/hr) demonstrating: (1) a pulmonary extraction ratio of PGE1 of 0.78 +/- 0.12, (2) a splanchnic extraction ratio of PGE1 of 0.54 +/- 0.23, and (3) levels of PGE1 in the systemic circulation of </= 78 pg/ml, even at the highest infusion rates. Despite significant increases in body temperature and pulse rate, hepatic hemodynamics were not affected by the PGE1 infusions in healthy swine. Seven patients receiving intravenous PGE1 for hepatic dysfunction (0.11-1.30 microg/kg/hr) had a pulmonary extraction ratio of 0.69 +/- 0.17. Systemic arterial concentrations of PGE1 were </= 62 pg/ml. These results suggest that due to clearance of PGE2 in the pulmonary and splanchnic circulations, current clinical protocols for intravenous administration of PGE1 are not likely to affect perihepatic hemodynamics.