Aripiprazole Lauroxil: Pharmacokinetic Profile of This Long-Acting Injectable Antipsychotic in Persons With Schizophrenia.

BACKGROUND: Aripiprazole lauroxil is an extended-release prodrug of aripiprazole for intramuscular injection, approved for schizophrenia treatment. We developed a population pharmacokinetic (PopPK) model to characterize aripiprazole lauroxil PK and evaluate dosing scenarios likely to be encountered in clinical practice. METHODS: Data from 616 patients with schizophrenia, collected from 5 clinical studies, were used to construct the PopPK model. The model was subsequently used to evaluate various dose levels and frequency and the impact of dosing delay on aripiprazole concentrations. FINDINGS: The results of the model indicate that aripiprazole is released into the systemic circulation after 5 to 6 days, and release continues for an additional 36 days. The slow increase in aripiprazole concentration after injection necessitates the coadministration of oral aripiprazole for 21 days with the first injection. Based on the PopPK model simulations, a dosing interval of 882 mg every 6 weeks results in aripiprazole concentrations that fall within the concentration range associated with the efficacious aripiprazole lauroxil dose range (441-882 mg dosed monthly). A 662-mg monthly dose also resulted in aripiprazole concentrations within the efficacious dose range. Aripiprazole lauroxil administration results in prolonged exposure, such that dose delays of 2 to 4 weeks, depending on the dose regimen, do not require oral aripiprazole supplementation upon resumption of dosing. CONCLUSIONS: This PopPK model and model-based simulations were effective means for evaluating aripiprazole lauroxil dosing regimens and management of missed doses. Such analyses play an important role in determining the use of this long-acting antipsychotic in clinical practice.

Effects of oral loperamide on efficacy of naltrexone, baclofen and AM-251 in blocking ethanol self-administration in rats.

Naltrexone is a µ-opioid receptor antagonist that has been extensively studied for its ability to block the rewarding effects of ethanol. Opioid receptors are widely distributed within the gastrointestinal tract (GIT). Typically, naltrexone is administered by parenteral routes in nonclinical studies. We initially tested if opioid receptors within the GIT would influence the ability of oral naltrexone to inhibit ethanol oral self-administration in rats using the co-administration of oral loperamide, a peripherally restricted opioid agonist. As expected, oral naltrexone only had modest effects on ethanol intake, and the response was not dose-dependent. However in rats, treatment with loperamide prior to the administration of naltrexone resulted in a suppression of ethanol intake which approached that observed with naltrexone given by the subcutaneous (SC) route. Importantly, administration of loperamide prior to administration of naltrexone did not alter blood concentrations of naltrexone. We then evaluated if oral loperamide would enhance effects of baclofen (a GABA(B) receptor agonist) and AM-251 (a CB-1 receptor antagonist) and found that pre-treatment with loperamide did potentiate the action of both drugs to reduce ethanol self-administration. Finally, the specific opioid receptor type involved was investigated using selective µ- and κ-receptor antagonists to determine if these would affect the ability of the AM-251 and loperamide combination to block ethanol drinking behavior. The effect of loperamide was blocked by ALKS 37, a peripherally restricted µ-receptor antagonist. These data suggest an important role for opioid receptors within the GIT in modulating central reward pathways and may provide new insights into strategies for treating reward disorders, including drug dependency.

Route of administration affects the ability of naltrexone to reduce amphetamine-potentiated brain stimulation reward in rats.

Opioid receptor antagonism has been shown to attenuate behavioral and neurochemical effects of amphetamine in humans and rodents. The effects of acute (oral or subcutaneous) or extended-release naltrexone (XR-NTX) were tested on the reward-enhancing effects of amphetamine using the intracranial self-stimulation (ICSS) paradigm. Acute exposure to drugs of abuse reduces the locus of rise (LOR) in the ICSS procedure, reflecting enhanced brain stimulation reward (BSR). Rats were treated once a day with naltrexone orally (PO; 5.0 mg/kg) or subcutaneously (SC; 0.5 mg/kg) for four consecutive days and tested with D-amphetamine (0.5 mg/kg, intraperitoneal) in the ICSS paradigm 30 minutes later on days 1 and 4. Separate groups of rats received XR-NTX (50 mg/kg, SC) or placebo microspheres (similar mass to XR-NTX, SC) on day 0 and tested with D-amphetamine in the ICSS paradigm on days 4, 14, 21, 28 and 41 after administration. Naltrexone plasma concentrations were determined for each amphetamine testing session using liquid chromatography-mass spectrometry/mass spectrometry (LC-MS/MS). In rats pretreated with naltrexone acutely, amphetamine-potentiated BSR did not differ from vehicle-pretreated rats on either day 1 or day 4 (25-30% decrease in LOR). In XR-NTX-pretreated rats, amphetamine-potentiated BSR was reduced by 64 and 70% on days 4 and 14, respectively, compared to placebo microsphere-treated controls. This effect dissipated by day 21. Naltrexone plasma concentrations were comparable across all treatment groups (14-30 ng/ml) on days 1, 4 and 14. In summary, an extended-release formulation of naltrexone results in significant attenuation of psychostimulant-enhanced BSR that is not observed with acute naltrexone.

Population pharmacokinetics of extended-release injectable naltrexone (XR-NTX) in patients with alcohol dependence.

OBJECTIVE: Injectable extended-release naltrexone (XR-NTX; Vivitrol) has recently been approved for the treatment of alcohol dependence. A population pharmacokinetic (PPK) analysis examined the possibility of altered pharmacokinetics for naltrexone and its primary metabolite, 6beta-naltrexol, in subpopulations with a potential for alcohol-dependence treatment. METHOD: Data from four clinical studies of XR-NTX were pooled. Absorption was modeled as a sequential release in three phases. The pharmacokinetics of naltrexone and 6beta-naltrexol were modeled as one-compartment disposition submodels, parameterized in terms of clearance (CL) and volume of distribution (V). The impact of age, weight, gender, race, hepatic function, renal function, smoking, and alcohol/opioid dependence on PPK parameter estimates was analyzed. RESULTS: Plasma concentrations were available from 453 subjects. More than half of the subjects (59%) were alcohol dependent, and 27% were dependent on both alcohol and opioids. Naltrexone CL (140 L/h) and V (38,300 L) were dependent on weight (changes of 0.548 L/h/kg and 0.655 L/kg, respectively) and were 23% and 35% higher, respectively, in subjects with alcohol and/or opioid dependence than in healthy subjects. Naltrexone CL also was dependent on age (-0.108 L/h/year); 6beta-naltrexol CL (65.1 L/h) was dependent on creatinine CL (0.229 L/h/ml/minute) and alkaline phosphatase (-0.130 L/h/IU/L), and was increased by 18% in smokers and in alcohol- and/or opioid-dependent subjects. CONCLUSIONS: Although statistically significant covariate-parameter relationships were identified, they were not considered clinically meaningful, suggesting that dosing adjustments of XR-NTX based on weight, age, gender, health status, smoking status, creatinine CL, and hepatic function differences should not be necessary.

Hepatobiliary disposition of a drug/metabolite pair: Comprehensive pharmacokinetic modeling in sandwich-cultured rat hepatocytes.

The hepatobiliary disposition of xenobiotics may involve passive and/or active uptake, metabolism by cytochromes P450, and excretion of the parent compound and/or metabolite(s) into bile. Although in vitro systems have been used to evaluate these individual processes discretely, mechanistic in vitro studies of the sequential processes of uptake, metabolism, and biliary or basolateral excretion are limited. The current studies used sandwich-cultured (SC) rat hepatocytes combined with a comprehensive pharmacokinetic modeling approach to investigate the hepatobiliary disposition of terfenadine and fexofenadine, a model drug/metabolite pair. The metabolism of terfenadine and the biliary excretion of terfenadine and fexofenadine were determined in control and dexamethasone-treated SC rat hepatocytes. Dexamethasone (DEX) treatment increased the formation rates of the terfenadine metabolites azacyclonol and fexofenadine approximately 20- and 2-fold, respectively. The biliary excretion index (BEI) of fexofenadine, when generated by terfenadine metabolism, was not significantly different from the BEI of preformed fexofenadine (15 +/- 2% versus 19 +/- 2%, respectively). Pharmacokinetic modeling revealed that the rate constant for hepatocyte uptake was faster for terfenadine compared with preformed fexofenadine (2.5 versus 0.08 h(-1), respectively), whereas the biliary excretion rate constant for preformed fexofenadine exceeded that of terfenadine (0.44 versus 0.039 h(-1), respectively). Interestingly, the rate constants for basolateral excretion of terfenadine and fexofenadine were comparable (3.2 versus 1.9 h(-1), respectively) and increased only slightly with DEX treatment. These studies demonstrate the utility of the SC hepatocyte model, coupled with pharmacokinetic modeling, to evaluate the hepatobiliary disposition of generated metabolites.

Effect of culture conditions on the expression and function of Bsep, Mrp2, and Mdr1a/b in sandwich-cultured rat hepatocytes.

Rat hepatocytes cultured in a sandwich configuration form functional canalicular networks. The influence of extracellular matrix configuration, medium composition, and confluency on the expression and function of Bsep, Mrp2, and Mdr1a/b in sandwich-cultured (SC) rat hepatocytes was examined. Primary rat hepatocytes were: (1) maintained in various extracellular matrix sandwich configurations, (2) cultured in Dulbecco's modified Eagle's medium (DMEM), Modified Chee's medium (MCM) or Williams' E medium (WME), and/or (3) plated at decreasing cell density. Bsep, Mrp2, and Mrdr1a/b expression in day 4 SC rat hepatocytes was assessed by Western blot; function was measured by accumulation of taurocholate, 5(and 6)-carboxy-2',7'-dichlorofluorescein, and rhodamine 123, respectively, in canalicular networks. In general, the extracellular matrix conditions examined resulted in similar protein expression and function. Function of Bsep, Mrp2, and Mdr1a/b was higher in SC rat hepatocytes maintained in DMEM or WME. Mrp2 and Mdr1a/b expression, representative of total cellular content, did not always correlate directly with function, which should be reflective of canalicular membrane expression. Mrp2 expression decreased significantly as cell density decreased in SC hepatocytes. Low plating density in Biocoat plates resulted in poor canalicular network formation and reduced function of Mrp2 and Mdr1a/b. Expression and/or function of Mrp2 and Mdr1a/b in rat hepatocytes cultured in a sandwich configuration may be influenced by plating density and media type.

Single- and multiple-dose pharmacokinetics of long-acting injectable naltrexone.

BACKGROUND: Oral naltrexone is effective in the treatment of alcohol dependence; however, a major limitation of its clinical utility is poor patient adherence to the daily dosing schedule. A biodegradable, long-acting naltrexone microsphere formulation was developed to achieve continuous naltrexone exposure for 1 month in the treatment of alcohol dependence. METHODS: The single- and multiple-dose safety and pharmacokinetics of a long-acting naltrexone microsphere preparation were evaluated in healthy subjects. One group of subjects (n = 28) received a single dose of oral naltrexone 50 mg followed by a single gluteal intramuscular (IM) injection of long-acting naltrexone 190 or 380 mg or placebo. A different group of subjects (n = 14) received oral naltrexone 50 mg daily for 5 days, followed by IM long-acting naltrexone 380 mg or placebo every 28 days for a total of 4 doses. A 7-day washout period separated oral and IM administrations. Blood samples were collected to determine plasma concentrations of naltrexone and the primary metabolite, 6beta-naltrexol. RESULTS: After a single IM injection of long-acting naltrexone 380 mg, naltrexone plasma concentrations were measurable in all subjects for at least 31 days postdose. The pharmacokinetics were proportional to the dose and multiple dose observations were consistent with single dose observations. Mean apparent elimination half-lives for naltrexone and 6beta-naltrexol ranged from 5 to 7 days. Exposure to 6beta-naltrexol was reduced with IM injection compared with that oral administration. No serious adverse events occurred. CONCLUSIONS: This study demonstrated that the long-acting naltrexone formulation was well tolerated, displayed predictable pharmacokinetics, and resulted in no meaningful drug accumulation upon multiple dosing. Intramuscular administration avoids first-pass metabolism and changes the exposure ratio of 6beta-naltrexol to naltrexone compared with oral administration. By providing continuous exposure to naltrexone for several weeks following IM injection, this long-acting naltrexone formulation may offer therapeutic benefit to those patients who experience difficulty adhering to the daily administration schedule necessitated by oral naltrexone therapy.

Pharmacokinetics of long-acting naltrexone in subjects with mild to moderate hepatic impairment.

Long-acting naltrexone is an extended-release formulation developed with the goal of continuous naltrexone exposure for 1 month for the treatment of alcohol dependence. The influence of mild and moderate hepatic impairment on naltrexone pharmacokinetics following long-acting naltrexone 190-mg administration was assessed. Subjects with mild (Child-Pugh grade A) and moderate (Child-Pugh grade B) hepatic impairment (n = 6 per group) and matched control subjects (n = 13) were enrolled. Naltrexone and 6beta-naltrexol concentrations were determined over a period of 63 days following a single intramuscular dose. Naltrexone and 6beta-naltrexol concentrations were detected in all subjects through 28 days. Total exposure (AUC(0-infinity)) of naltrexone and 6beta-naltrexol was similar across all groups. The long apparent half-lives of naltrexone and 6beta-naltrexol (5-8 days) were attributed to the slow release of naltrexone (long-acting naltrexone exhibits absorption rate-limited elimination or "flip-flop" kinetics); elimination was not altered in subjects with hepatic impairment. Based on pharmacokinetic considerations, the dose of long-acting naltrexone does not need to be adjusted in patients with mild or moderate hepatic impairment.

P-glycoprotein expression, localization, and function in sandwich-cultured primary rat and human hepatocytes: relevance to the hepatobiliary disposition of a model opioid peptide.

PURPOSE: The isolation of hepatocytes from intact liver involves collagenase digestion of the tissue, resulting in loss of cell polarization and functional vectorial excretion. These studies examined repolarization, localization of P-glycoprotein (P-gp) to the canalicular domain of the hepatocyte, and re-establishment of vectorial transport in sandwich-cultured (SC) rat and human primary hepatocytes. METHODS: Protein localization and expression were determined in SC hepatocytes by confocal microscopy and Western blotting, respectively. Transporter function was evaluated by measuring [D-penicillamine2,5]enkephalin (3H-DPDPE) and 5 (and 6)-carboxy-2',7'-dichlorofluorescein (CDF) biliary excretion in SC hepatocytes. RESULTS: P-gp and the canalicular marker protein dipeptidyl peptidase IV (DPPIV) co-localized by Day 3 and Day 6 in SC rat hepatocytes and SC human hepatocytes, respectively, consistent with canalicular network formation visualized by light microscopy. Co-localization of multidrug resistance associated protein 2 (MRP2) and P-gp in SC human hepatocytes was observed on Day 6 in culture. Expression levels of P-gp increased slightly in both species over days in culture; similar expression was observed for MRP2 in SC human hepatocytes. Oatp1a1 expression in SC rat hepatocytes was maintained over days in culture, whereas Oatp1a4 expression decreased. OATP1B1 expression decreased slightly on Day 3 in SC human hepatocytes. OATP1B3 expression was constant in SC human hepatocytes. In vitro biliary excretion of the opioid peptide 3H-DPDPE correlated with the proper localization of canalicular proteins in both species. Excretion of CDF in SC human hepatocytes confirmed network formation and MRP2 function. CONCLUSIONS: These studies indicate that SC hepatocytes repolarize and traffic functional canalicular transport proteins to the appropriate cellular domain.

Effect of dexamethasone treatment on the expression and function of transport proteins in sandwich-cultured rat hepatocytes.

Dexamethasone (DEX) is a well established inducer of CYP3A. These studies examined the influence of DEX treatment on transport protein expression and function in sandwich-cultured (SC) rat hepatocytes. Freshly isolated hepatocytes were cultured between two layers of gelled collagen and maintained in Dulbecco's modified Eagle's medium supplemented with DEX (0.1 microM, 0-48 h and 0.1-100 microM, 48-96 h). The expression of sinusoidal [(organic anion transporting polypeptide 1a1 (Oatp1a1), Oatp1a4, multidrug resistance-associated protein 3 (Mrp3), and Na(+)-dependent taurocholate cotransporting polypeptide (Ntcp)] and canalicular [bile salt export pump (Bsep), multidrug resistance protein 1a/b (Mdr1a/b), and Mrp2] transport proteins was determined by Western blot analysis. The accumulation and biliary excretion index (BEI; percentage of accumulated substrate in canalicular networks) of the probe substrates taurocholate (TC; 1 microM, 10 min), rhodamine 123 (Rh123; 10 microM, 30 min), and carboxy-2',7'-dichlorofluorescein (CDF; 10 microM, 10 min) were employed as measures of canalicular transport protein function in SC rat hepatocytes. DEX treatment increased CYP3A1/2, Oatp1a4, and Mrp2 expression, decreased the expression of Ntcp, and did not seem to alter the expression of Oatp1a1, Mrp3, Mdr1a/b, or Bsep. The BEI of CDF, an Mrp2 substrate, increased from 18 to 37% after DEX treatment (100 microM). The accumulation of TC, an Ntcp substrate, was reduced (<50% of control), whereas the BEI of TC, also a Bsep substrate, was unchanged. Treatment of SC rat hepatocytes with DEX resulted in alterations in the expression of CYP3A1/2 and some hepatic transport proteins. Modest alterations in hepatic transport protein function were consistent with changes in protein expression.

Pharmacokinetics of 5 (and 6)-carboxy-2',7'-dichlorofluorescein and its diacetate promoiety in the liver.

Hepatic disposition of 5 (and 6)-carboxy-2',7'-dichlorofluorescein (CDF) and its diacetate promoiety (CDFDA) was studied in isolated perfused rat livers. Livers from Wistar wild-type and multidrug resistance-associated protein (Mrp)2-deficient (TR(-)) rats were perfused with CDF in the presence or absence of probenecid. Probenecid decreased the recovery of CDF in bile approximately 4-fold in wild-type livers (65 +/- 8% versus 15 +/- 2% of dose over 2 h). In livers from TR(-) rats, CDF was not excreted into bile and probenecid decreased perfusate CDF concentrations in a concentration-dependent manner, in part due to inhibition of Mrp3. Plasma membrane vesicles from rat Mrp2- or Mrp3-transfected Sf9 cells were used to confirm that CDF is a substrate for Mrp2 and Mrp3; probenecid inhibited the transport of CDF by Mrp2 and Mrp3 in a concentration-dependent manner. CDF uptake in collagen sandwich-cultured rat hepatocytes was temperature-dependent and saturable (K(m) = 22 +/- 10 microM; V(max) = 97 +/- 9 pmol/min/mg protein). Uptake of CDF in sandwich-cultured rat hepatocytes was impaired significantly by bromosulfophthalein, a substrate for organic anion-transporting polypeptides (Oatps), but was not modulated by specific Oatp2 or organic anion transporter (Oat) substrates. CDFDA uptake was not saturable, temperature-dependent, or impaired by inhibitors. The hydrolysis of CDFDA to CDF is mediated by basic pH and esterases in biological media. CDFDA passively diffuses into hepatocytes where it is hydrolyzed to CDF. In contrast, CDF appears to be taken up by Oatp-mediated transport into rat hepatocytes and effluxed via Mrp2 into bile and via Mrp3 into sinusoidal blood.