Raymond F. Johnson

Comparative placental transport of oral hypoglycemic agents in humans: A model of human placental drug transfer

OBJECTIVEnThis study compares the human placental transport of glyburide, glipizide, chlorpropamide, and tolbutamide.nnnSTUDY DESIGNnThe recirculating single cotyledon human placenta model tested maternal-to-fetal transport in term placentas perfused immediately after delivery. Drug levels were measured by high-performance liquid chromatography and liquid scintillation spectrometry, and transport rates were calculated by comparing maternal and fetal concentrations.nnnRESULTSnThe transport of these substances differed significantly over a tenfold range (analysis of variance, p < 0.0008). A significant association exists by multiple linear regression between drug transfer and molecular weight, dissociation constant, and the octanol-water partition coefficient (R2 = 0.91, p < 0.0001).nnnCONCLUSIONSnThere is significant variability in human placental transfer rates of the oral hypoglycemics, which strongly correlates with molecular properties. These data suggest that less fetal exposure may occur with second-generation sulfonylureas and anticipate that regression models may be useful in selecting agents that minimize placental transport to the fetus.

Insignificant transfer of glyburide occurs across the human placenta

No data exist concerning human placental transfer of oral hypoglycemic agents during pregnancy. This study characterizes the transport of glyburide in 10 term human placentas with the single-cotyledon placental model. Serial samples were taken from both the maternal and fetal reservoirs during each 3-hour perfusion, and the percent transport and metabolism of tritiated glyburide was calculated with liquid scintillation spectrometry and high-performance liquid chromatography. Antipyrine labeled with carbon 14 was added to the perfusate solution during these experiments as a control. Virtually no transfer of glyburide occurred, and no appreciable metabolism of the drug was detected. Neither variation in the albumin concentration nor increase in the maternal glyburide levels to 100 times therapeutic concentration materially altered the rate of transport. These data show that insignificant transport of glyburide occurs across the human placenta in vitro and suggest that fetal exposure to maternally administered glyburide likewise may be insignificant.

A Comparative Evaluation of the Transport of H2-Receptor Antagonists by the Human and Baboon Placenta

Using a single cotyledon perfusion model, the placental transport of four H2-receptor antagonists, cimetidine, famotidine, nizatidine, and ranitidine, was determined and compared using normal term human and normal preterm baboon placentas. In both the human and baboon placentas, the transport of each agent was similar whether administered singly or in combination with the other drugs. Drug transport was the same in both directions, maternal-to-fetal and vice versa, indicating a lack of preferential transfer. The H2-receptor antagonists were transported at about 40% the rate of the freely diffusable reference compound, antipyrine. There were no significant differences between the human and baboon in any of the parameters of placental function evaluated. Placental glucose and oxygen consumptions, and lactate production were comparable in the human and baboon preparations. The transport and clearance of each of the H2-antagonists were similar in each species.

Effects of Liver Disease on the Disposition of Ciramadol in Humans

To determine the effects of liver disease on the disposition of ciramadol, an analgesic that undergoes ether glucuronidation, we studied its plasma pharmacokinetics in 10 patients with stable cirrhosis, 8 with acute viral hepatitis, and 16 age‐matched healthy controls. Renal excretion of the glucuronides was also determined. In healthy controls given a single intravenous dose of the drug the t1/2 was 3.4 ± 0.3 hrs and the systemic clearance was 668 ± 109 ml/min of which renal clearance was 320 ± 73 ml/min and non‐renal clearance 349 ± 74 ml/min. The corresponding values after an oral dose were similar. Renal clearance was related directly to the estimated creatinine clearance. Moreover, the renal clearance of ciramadol exceeded creatinine clearance, suggesting that the drug was excreted not only by glomerular filtration but also by tubular secretion. The systemic clearance of intravenous ciramadol was diminished by 40% in cirrhosis, P < 0.05, due to a reduction in renal clearance, while non‐renal clearance remained normal. Renal clearance of the inactive glucuronides, on the other hand, was not affected. In patients with acute viral hepatitis, systemic clearance was unchanged, but renal clearance of ciramadol tended to increase during the acute phase of the disease and to return toward normal after recovery. Renal excretion of the inactive glucuronides was decreased by 48% (P < .05). These findings suggest that the non‐renal ether glucuronidation of ciramadol remains intact in patients with stable cirrhosis or acute viral hepatitis. However, the renal clearance of the drug may be impaired in cirrhosis, but tends to be enhanced in acute hepatitis. Finally, the renal excretion of the parent compound may differ from that of its metabolites. Thus, ciramadol may be a suitable analgesic in patients with stable liver disease provided the kidneys are functioning normally.