Metabolism and disposition of the HIV-1 protease inhibitor lopinavir (ABT-378) given in combination with ritonavir in rats, dogs, and humans

Gondi N Kumar; Venkata K Jayanti; Marianne K Johnson; John Uchic; Samuel Thomas; Ronald D Lee; Brian A Grabowski; Hing L Sham; Dale J Kempf; Jon F Denissen; Kennan C Marsh; Eugene Sun; Stanley A Roberts

doi:10.1023/b:pham.0000041457.64638.8d

Metabolism and disposition of the HIV-1 protease inhibitor lopinavir (ABT-378) given in combination with ritonavir in rats, dogs, and humans

Pharm Res. 2004 Sep;21(9):1622-30. doi: 10.1023/b:pham.0000041457.64638.8d.

Authors

Gondi N Kumar¹, Venkata K Jayanti, Marianne K Johnson, John Uchic, Samuel Thomas, Ronald D Lee, Brian A Grabowski, Hing L Sham, Dale J Kempf, Jon F Denissen, Kennan C Marsh, Eugene Sun, Stanley A Roberts

Affiliation

¹ Pharmaceutical Products Division, Abbott Laboratories, Abbott Park, Illinois 60064, USA.

PMID: 15497688
DOI: 10.1023/b:pham.0000041457.64638.8d

Abstract

Purpose: The objective of this study was to examine the metabolism and disposition of the HIV protease inhibitor lopinavir in humans and animal models.

Methods: The plasma protein binding of [14C]lopinavir was examined in vitro via equilibrium dialysis technique. The tissue distribution of radioactivity was examined in rats dosed with [14C]lopinavir in combination with ritonavir. The metabolism and disposition of [14C]lopinavir was examined in rats, dogs, and humans given alone (in rats only) or in combination with ritonavir.

Results: The plasma protein binding of lopinavir was high in all species (97.4-99.7% in human plasma), with a concentration-dependent decrease in binding. Radioactivity was extensively distributed into tissues, except brain, in rats. On oral dosing to rats, ritonavir was found to increase the exposure of lopinavir-derived radioactivity 13-fold. Radioactivity was primarily cleared via the hepato-biliary route in all species (>82% of radioactive dose excreted via fecal route), with urinary route of elimination being significant only in humans (10.4% of radioactive dose). Oxidative metabolites were the predominant components of excreted radioactivity. The predominant site of metabolism was found to be the carbon-4 of the cyclic urea moiety, with subsequent secondary metabolism occurring on the diphenyl core moiety. In all the three species examined, the primary component of plasma radioactivity was unchanged lopinavir (>88%) with small amounts of oxidative metabolites.

Conclusions: Lopinavir was subject to extensive metabolism in vivo. Co-administered ritonavir markedly enhanced the pharmacokinetics of lopinavir-derived radioactivity in rats, probably due to inhibition of presystemic and systemic metabolism, leading to an increased exposure to this potent HIV protease inhibitor.

Publication types

Comparative Study

MeSH terms

Administration, Oral
Adult
Animals
Bile / metabolism
Blood Proteins / metabolism
Dogs
Drug Combinations
Feces / chemistry
Female
HIV Protease Inhibitors / administration & dosage
HIV Protease Inhibitors / pharmacokinetics*
Humans
Injections, Intravenous
Lopinavir
Macaca fascicularis
Male
Models, Chemical
Molecular Structure
Protein Binding
Pyrimidinones / administration & dosage
Pyrimidinones / chemistry
Pyrimidinones / pharmacokinetics*
Rats
Rats, Sprague-Dawley
Ritonavir / administration & dosage
Ritonavir / pharmacokinetics*
Tissue Distribution

Substances

Blood Proteins
Drug Combinations
HIV Protease Inhibitors
Pyrimidinones
Lopinavir
Ritonavir