The valine at position 82 (Val 82) in the active site of the human immunodeficiency virus (HIV) protease mutates in response to therapy with the protease inhibitor ritonavir. By using the X-ray crystal structure of the complex of HIV protease and ritonavir, the potent protease inhibitor ABT-378, which has a diminished interaction with Val 82, was designed. ABT-378 potently inhibited wild-type and mutant HIV protease (Ki = 1.3 to 3.6 pM), blocked the replication of laboratory and clinical strains of HIV type 1 (50% effective concentration [EC50], 0.006 to 0.017 μM), and maintained high potency against mutant HIV selected by ritonavir in vivo (EC50, ≤0.06 μM). The metabolism of ABT-378 was strongly inhibited by ritonavir in vitro. Consequently, following concomitant oral administration of ABT-378 and ritonavir, the concentrations of ABT-378 in rat, dog, and monkey plasma exceeded the in vitro antiviral EC50 in the presence of human serum by >50-fold after 8 h. In healthy human volunteers, coadministration of a single 400-mg dose of ABT-378 with 50 mg of ritonavir enhanced the area under the concentration curve of ABT-378 in plasma by 77-fold over that observed after dosing with ABT-378 alone, and mean concentrations of ABT-378 exceeded the EC50 for >24 h. These results demonstrate the potential utility of ABT-378 as a therapeutic intervention against AIDS.
Baclofen is a racemic GABA B receptor agonist that has a number of significant pharmacokinetic limitations, including a narrow window of absorption in the upper small intestine and rapid clearance from the blood. Arbaclofen placarbil is a novel transported prodrug of the pharmacologically active R-isomer of baclofen designed to be absorbed throughout the intestine by both passive and active mechanisms via the monocarboxylate type 1 transporter. Arbaclofen placarbil is rapidly converted to R-baclofen in human and animal tissues in vitro. This conversion seems to be primarily catalyzed in human tissues by human carboxylesterase-2, a major carboxylesterase expressed at high levels in various tissues including human intestinal cells. Arbaclofen placarbil was efficiently absorbed and rapidly converted to R-baclofen after oral dosing in rats, dogs, and monkeys. Exposure to R-baclofen was proportional to arbaclofen placarbil dose, whereas exposure to intact prodrug was low. Arbaclofen placarbil demonstrated enhanced colonic absorption, i.e., 5-fold higher R-baclofen exposure in rats and 12-fold higher in monkeys compared with intracolonic administration of R-baclofen. Sustained release formulations of arbaclofen placarbil demonstrated sustained R-baclofen exposure in dogs with bioavailability up to 68%. In clinical use, arbaclofen placarbil may improve the treatment of patients with gastroesophageal reflux disease, spasticity, and numerous other conditions by prolonging exposure and decreasing the fluctuations in plasma levels of R-baclofen.
WHAT IS ALREADY KNOWN ABOUT THIS SUBJECT • Gabapentin enacarbil is a transported prodrug of gabapentin that provides sustained, dose‐proportional exposure to gabapentin by taking advantage of high‐capacity transport pathways expressed throughout the intestinal tract. This prodrug has shown efficacy in multiple clinical trials for the treatment of moderate‐to‐severe primary restless legs syndrome and could potentially represent the first non‐dopaminergic treatment for this important disease. WHAT THIS STUDY ADDS • Unlike gabapentin, gabapentin enacarbil is actively absorbed from the intestine by multiple pathways, including the monocarboxylate transporter type‐1 transporter (MCT‐1). Although drug interactions of gabapentin have been reported in the literature, the distinctly different absorption pathway of gabapentin enacarbil requires a separate evaluation of the potential for interaction with other substrates of MCT‐1. To achieve this, the pharmacokinetics of gabapentin enacarbil were examined in healthy adults when administered alone or in combination with naproxen, a known MCT‐1 substrate. • After absorption, gabapentin enacarbil is completely hydrolyzed to gabapentin, and the released gabapentin is excreted by renal elimination. Gabapentin is a substrate for the organic cation transporter type‐2 (OCT2) present in the kidney. To examine the potential for an elimination‐site drug interaction resulting from administration of the prodrug, the pharmacokinetics of gabapentin enacarbil were examined in healthy adults when administered alone or in combination with cimetidine, a known substrate of OCT2. AIM Gabapentin enacarbil, a transported prodrug of gabapentin, provides sustained, dose‐proportional exposure to gabapentin. Unlike gabapentin, the prodrug is absorbed throughout the intestinal tract by high‐capacity nutrient transporters, including mono‐carboxylate transporter‐1 (MCT‐1). Once absorbed, gabapentin enacarbil is rapidly hydrolyzed to gabapentin, which is subsequently excreted by renal elimination via organic cation transporters (OCT2). To examine the potential for drug–drug interactions at these two transporters, the pharmacokinetics of gabapentin enacarbil were evaluated in healthy adults after administration alone or in combination with either naproxen (an MCT‐1 substrate) or cimetidine (an OCT2 substrate). METHODS Subjects (n= 12 in each study) received doses of study drug until steady state was achieved; 1200 mg gabapentin enacarbil each day, followed by either naproxen (500 mg twice daily) or cimetidine (400 mg four times daily) followed by the combination. RESULTS When gabapentin enacarbil was co‐administered with naproxen, gabapentin Css,max increased by, on average, 8% and AUC by, on average, 13%. When gabapentin enacarbil was co‐administered with cimetidine, gabapentin AUCss increased by 24% and renal clearance of gabapentin decreased. Co‐administration with gabapentin enacarbil did not affect naproxen or cimetidine exposure. Gabapentin enacarbil was generally well tolerated. CONCLUSIONS No ...
AP decreased reflux and associated symptoms with good tolerability in patients with GERD.
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