Elucidation of Metabolic and Disposition Pathways for Maribavir in Nonhuman Primates through Mass Balance and Semi-Physiologically Based Modeling Approaches.

Maribavir is in phase 3 clinical development for treatment of cytomegalovirus infection/disease in transplant recipients. Previous research conducted using only intact cynomolgus monkeys indicated biliary secretion as the primary elimination pathway for maribavir and that maribavir undergoes enterohepatic recirculation (EHR). To clarify the exact mechanisms of maribavir's EHR behavior, we studied its clearance pathways using intravenously administered 14C-labeled maribavir in intact and bile duct-cannulated (BDC) monkeys and constructed a semi-physiologically based pharmacokinetic (PBPK) model. Total radioactivity metabolite profiles in plasma and excreta were quantitatively determined along with plasma maribavir concentrations. Intact animals showed significantly lower clearance and longer half-lives in both total radioactivity and parent concentration in plasma than BDC monkeys. The primary in vitro and in vivo metabolic pathway for maribavir in monkey is direct glucuronidation; N-dealkylation and renal clearance are minor pathways. In BDC monkeys, 73% of dose was recovered as maribavir glucuronides in bile, and 3% of dose was recovered as parent in bile and feces; in intact animals' feces, 58% of dose was recovered as parent, and no glucuronides were detected. Therefore, EHR of maribavir occurs through biliary secretion of maribavir glucuronides, and this is followed by hydrolysis of glucuronides in the gut lumen and subsequent reabsorption of parent. A semi-PBPK model constructed from physiologic, in vitro, and in vivo BDC monkey data is capable of projecting maribavir's pharmacokinetic and EHR behavior in intact animals after intravenous or oral dosing and could be applied to modeling other xenobiotics that are subject to similar EHR processes. SIGNIFICANCE STATEMENT: Through both mass balance and semi-physiologically based pharmacokinetic (semi-PBPK) modeling approaches, this study mechanistically and quantitatively elucidates maribavir's enterohepatic recirculation (EHR) behavior in monkeys, which occurs via extensive direct glucuronidation, biliary secretion of these glucuronides, luminal hydrolysis of glucuronides to parent, and subsequent reabsorption of the parent. The study also identifies important drug- and animal-specific parameters that determine the EHR kinetics, and the semi-PBPK model is readily applicable to other drugs that undergo similar metabolic and recirculation mechanisms.

Leveraging Quantitative Systems Pharmacology Approach into Development of Human Recombinant Follistatin Fusion Protein for Duchenne Muscular Dystrophy.

Quantitative understanding about the dynamics of drug-target interactions in biological systems is essential, especially in rare disease programs with small patient populations. Follistatin, by antagonism of myostatin and activin, which are negative regulators of skeletal muscle and inflammatory response, is a promising therapeutic target for Duchenne Muscular Dystrophy. In this study, we constructed a quantitative systems pharmacology model for FS-EEE-Fc, a follistatin recombinant protein to investigate its efficacy from dual target binding, and, subsequently, to project its human efficacious dose. Based on model simulations, with an assumed efficacy threshold of 7-10% muscle volume increase, 3-5 mg/kg weekly dosing of FS-EEE-Fc is predicted to achieve meaningful clinical outcome. In conclusion, the study demonstrated an application of mechanism driven approach at early stage of a rare disease drug development to support lead compound optimization, enable human dose, pharmacokinetics, and efficacy predictions.

Correction to: Development of Guanfacine Extended-Release Dosing Strategies in Children and Adolescents with ADHD Using a Physiologically Based Pharmacokinetic Model to Predict Drug-Drug Interactions with Moderate CYP3A4 Inhibitors or Inducers.

The article "Development of Guanfacine Extended-Release Dosing Strategies in Children and Adolescents with ADHD Using a PhysiologicallyBased Pharmacokinetic Model to Predict Drug-Drug Interactions with Moderate CYP3A4 Inhibitors or Inducers", written by Aiqun Li, Karen Yeo, Devin Welty, Haojing Rong, was originally published electronically on the publisher's internet portal (currently SpringerLink) on 02nd November, 2017 without open access.

Ocular Distribution and Pharmacokinetics of Lifitegrast in Pigmented Rabbits and Mass Balance in Beagle Dogs.

PURPOSE: Lifitegrast is approved in the United States for the treatment of dry eye disease (DED). We assessed lifitegrast's ocular distribution/pharmacokinetic profile in rabbits, and 14C-lifitegrast mass balance/excretion in dogs. METHODS: Female pigmented rabbits received a single topical ocular dose of lifitegrast (Formulation No. 1, n = 25; No. 2, n = 25) per eye twice daily (target, 1.75 mg/eye/dose). Blood/ocular tissues were collected on day 5. Beagle dogs received single intravenous (n = 10; target, 3 mg, 262 µCi/animal) and ocular (n = 8, target, 3 mg, 30 µCi/eye) doses of 14C-lifitegrast (∼8 weeks between doses). Blood, excreta, and cage rinse/wipes were collected. Concentrations were measured by mass spectrometry/liquid scintillation counting. Pharmacokinetic analyses (noncompartmental) included maximum concentration (Cmax), time to Cmax (tmax), and area under the concentration-time curve from 0 to 8 h (AUC0-8). RESULTS: In rabbits, lifitegrast Cmax and AUC0-8 were similar between formulations. Cmax was highest in ocular anterior segment tissues: 5,190-14,200 ng/g [conjunctiva (palpebral/bulbar), cornea, anterior sclera]. Posterior segment tissues had lower concentrations (0-826 ng/g). AUC0-8 followed a similar trend. Plasma concentrations were low (Cmax <18 ng/mL). Tissue/plasma tmax was ∼0.25-1 h. In dogs, after intravenous/ocular doses, 14C-lifitegrast was eliminated primarily through feces. Excreted radioactivity was mainly unchanged lifitegrast. CONCLUSIONS: High exposure of lifitegrast in rabbit ocular anterior segment tissues and low exposure in posterior segment tissues/plasma suggests that lifitegrast reaches target tissues for DED treatment, with low potential for off-target systemic/ocular effects. Excretion of unchanged 14C-lifitegrast suggests minimal drug metabolism in vivo. This is consistent with lifitegrast clinical trial efficacy/safety data.

Development of Guanfacine Extended-Release Dosing Strategies in Children and Adolescents with ADHD Using a Physiologically Based Pharmacokinetic Model to Predict Drug-Drug Interactions with Moderate CYP3A4 Inhibitors or Inducers.

BACKGROUND: Guanfacine extended-release (GXR) is an orally administered, non-stimulant treatment for children and adolescents with attention-deficit/hyperactivity disorder (ADHD) and is primarily metabolized by the 3A4 isozyme of cytochrome P450 (CYP3A4). The results of clinical pharmacokinetic (PK) studies indicate that guanfacine is sensitive to drug-drug interactions (DDIs) perpetrated by strong inhibitors and inducers of CYP3A4. OBJECTIVE: The aim was to provide guidance on the possible requirement for GXR dose adjustment in children and adolescents with ADHD by predicting DDIs following co-administration with moderate CYP3A4 inhibitors and inducers. METHODS: A physiologically based PK model for GXR orally administered to healthy adults was developed based on physicochemical, in vitro and clinical PK data. The model was validated using clinical PK data for co-administration of GXR with ketoconazole (strong CYP3A4 inhibitor) or rifampicin (strong CYP3A4 inducer). RESULTS: Model predictions indicated that co-administration of GXR with the moderate CYP3A4 inhibitors erythromycin 500 mg three times a day or fluconazole 200 mg daily (q.d.) increased the guanfacine area under the plasma concentration-time curve (AUC) by 2.31-fold or 1.98-fold, respectively, compared with GXR monotherapy. The moderate CYP3A4 inducer efavirenz 400 mg or 600 mg q.d. was predicted to reduce guanfacine AUC to 58 or 33% of its value for GXR monotherapy, respectively. CONCLUSION: Without the requirement for additional clinical studies, the following GXR dose recommendations were developed and approved for US labeling for use in children and adolescents with ADHD: (1) decrease GXR to 50% of the usual target dose when it is co-administered with strong or moderate CYP3A4 inhibitors; (2) consider titrating GXR up to double the usual target dose over 1-2 weeks when it is co-administered with strong or moderate CYP3A4 inducers.

In vitro drug-drug interactions of budesonide: inhibition and induction of transporters and cytochrome P450 enzymes.

1. Budesonide is a glucocorticoid used in the treatment of several respiratory and gastrointestinal inflammatory diseases. Glucocorticoids have been demonstrated to induce cytochrome P450 (CYP) 3A and the efflux transporter P-glycoprotein (P-gp). This study aimed to evaluate the potential of budesonide to act as a perpetrator or a victim of transporter- or CYP-mediated drug-drug interactions (DDIs). 2. In vitro studies were conducted for P-gp, breast cancer resistance protein and organic anion and cation transporters (OATP1B1, OATP1B3, OAT1, OAT3, OCT2) in transporter-transfected cells. Changes in mRNA expression in human hepatocytes and enzyme activity in human liver microsomes by budesonide were determined for CYP1A2, CYP2B6, CYP2C8, CYP2C9, CYP2C19, CYP2D6 and CYP3A. 3. The data indicated that budesonide is a substrate of P-gp but is not a substrate or an inhibitor of the other transporters investigated. Budesonide is neither an inducer nor an inhibitor of major CYP enzymes. The effect of P-gp on budesonide disposition is anticipated to be low owing to CYP3A-mediated clearance. 4. Collectively, our data indicate there is a low risk of budesonide perpetrating clinical DDIs mediated by the transporters or CYPs studied.

Continuous infusion of the α7 nicotinic acetylcholine receptor agonist EVP-6124 produces no signs of tolerance at memory-enhancing doses in rats: a pharmacokinetic and behavioral study.

We investigated whether the effects of acutely administered EVP-6124, an α7 nicotinic acetylcholine receptor (α7 nAChR) agonist, on cognition were maintained after 6-day continuous minipump administration. Performance in a delay-dependent forgetting test was measured in the object recognition task after single-oral doses of 0.3 or 1 mg/kg, or at plasma steady-state concentrations (Css) of 0.6 or 2 ng/ml, which were similar to the efficacious plasma concentrations after single-oral dosing. The 0.3 mg/kg acute dose enhanced memory at a total plasma concentration of ∼0.3 ng/ml at 1-4 h after dosing. Continuous treatment produced total plasma Css values of 0.48 and 1.93 ng/ml on day 6 and enhanced memory. At EVP-6124 plasma concentrations that optimally enhance memory in the object recognition task, tolerance did not develop after 6 days of continuous treatment.

Neuropharmacokinetics of two investigational compounds in rats: divergent temporal profiles in the brain and cerebrospinal fluid.

Two investigational compounds (FRM-1, (R)-7-fluoro-N-(quinuclidin-3-yl)benzo[b]thiophene-2-carboxamide and FRM-2, (R)-7-cyano-N-(quinuclidin-3-yl)benzo[b]thiophene-2-carboxamide) resided in rat brain longer than in systemic circulation. In Caco-2 directional transport studies, they both showed good intrinsic passive permeability but differed significantly in efflux susceptibility (efflux ratio of <2 and ∼7, respectively), largely attributed to P-glycoprotein (P-gp). Capitalizing on these interesting properties, we investigated how cerebrospinal fluid (CSF) concentration (CCSF) would be shaped by unbound plasma concentration (Cu,p) and unbound brain concentration (Cu,b) in disequilibrium conditions and at steady state. Following subcutaneous administration, FRM-1CCSF largely followed Cu,p initially and leveled between Cu,p and Cu,b. However, it gradually approached Cu,b and became lower than, but parallel to Cu,b at the terminal phase. In contrast, FRM-2CCSF temporal profile mostly paralleled the Cu,p but was at a much lower level. Upon intravenous infusion to steady state, FRM-1CCSF and Cu,b were similar, accounting for 61% and 69% of the Cu,p, indicating a case of largely passive diffusion-governed brain penetration where CCSF served as a good surrogate for Cu,b. On the contrary, FRM-2CCSF and Cu,b were remarkably lower than Cu,p (17% and 8% of Cu,p, respectively), suggesting that FRM-2 brain penetration was severely impaired by P-gp-mediated efflux and CCSF underestimated this impact. A semi-physiologically based pharmacokinetic (PBPK) model was constructed that adequately described the temporal profiles of the compounds in the plasma, brain and CSF. Our work provided some insight into the relative importance of blood-brain barrier (BBB) and blood-CSF barrier (BCSFB) in modulating CCSF.

A dynamic view to the modulation of phosphorylation and O-GlcNAcylation by inhibition of O-GlcNAcase.

Protein phosphorylation and O-GlcNAcylation are reciprocally regulated. As hyperphosphorylation is implicated in tau pathology, approaches have been exploited to reduce the magnitude of tau phosphorylation by increasing the level of tau O-GlcNAcylation. With mathematic models constructed to describe different kinetic scenarios, we analyzed the temporal change of an O-GlcNAcylated protein in contrast to that of the phosphorylated form upon inhibition of O-GlcNAcase (OGA). The analyses indicate that when degradation of the modified protein is negligible relative to the naked one, the magnitude of O-GlcNAcylated protein increase is proportional to the level of inhibition, while the extent of phosphorylated protein decline varies due to other factors. Furthermore, the increase of O-GlcNAcylated protein parallels with the decrease of phosphorylated form upon acute or short-term inhibition of OGA, as observed in many in vitro and short term in vivo studies. However, phosphorylated protein is predicted to return to its initial level while O-GlcNAcylated protein to achieve a higher steady level under sustained inhibition. This simulated result is in line with a recent report on long-term inhibition of OGA in transgenic mice. Noticeably, inhibition withdrawal is anticipated to cause a transient rise of phosphorylated protein. If degradation of modified proteins proceeds in addition to the naked one, the characteristic temporal profiles of each form in response to OGA inhibition would depend on the relative importance of individual degradation pathways. The models described herein may serve as a useful investigational tool that will provide insight into pharmacological intervention for tauopathies in particular and for reciprocally modulated reactions in general.

Pharmacokinetics of a sustained-release dexamethasone intravitreal implant in vitrectomized and nonvitrectomized eyes.

PURPOSE: To evaluate dexamethasone pharmacokinetics after implantation of a sustained-release dexamethasone (DEX) intravitreal implant in nonvitrectomized and vitrectomized eyes. METHODS: The right eyes of 25 rabbits underwent vitrectomy; contralateral eyes served as nonvitrectomy controls. The 0.7-mg DEX implant was injected into both eyes, and drug concentrations were determined in the vitreous humor and retina for 31 days (on days 2, 8, 15, 22, and 31). RESULTS: DEX was present in nonvitrectomized and vitrectomized eyes for at least 31 days. There were no statistically significant differences in DEX concentration between nonvitrectomized and vitrectomized eyes at any time point (P > 0.05). The maximum concentration of DEX in nonvitrectomized versus vitrectomized eyes for vitreous humor was 791 ng/mL (day 22) versus 731 ng/mL (day 22), respectively, and for retina it was 4110 ng/mL (day 15) versus 3670 ng/mL (day 22), respectively. Mean absorption (AUC(0-tlast)) of dexamethasone in nonvitrectomized and vitrectomized eyes was not different for both the vitreous humor (13,600 vs. 15,000 ng/day/mL; P = 0.73) and retina (67,600 vs. 50,200 ng/day/mL; P = 0.47). CONCLUSIONS: The vitreoretinal pharmacokinetic profiles were similar between nonvitrectomized and vitrectomized eyes. These observations are consistent with clinical findings of the DEX implant in patients who have undergone vitrectomy and should reduce concerns about the use of the DEX implant in eyes that have undergone vitrectomy.

Pharmacokinetics and pharmacodynamics of a sustained-release dexamethasone intravitreal implant.

PURPOSE: To determine the pharmacokinetics and pharmacodynamics of a sustained-release dexamethasone (DEX) intravitreal implant (Ozurdex; Allergan, Inc.). METHODS: Thirty-four male monkeys (Macaca fascicularis) received bilateral 0.7-mg DEX implants. Blood, vitreous humor, and retina samples were collected at predetermined intervals up to 270 days after administration. DEX was quantified by liquid chromatography-tandem mass spectrometry, and cytochrome P450 3A8 (CYP3A8) gene expression was analyzed by real-time reverse transcription-polymerase chain reaction. RESULTS: DEX was detected in the retina and vitreous humor for 6 months, with peak concentrations during the first 2 months. After 6 months, DEX was below the limit of quantitation. The C(max) (T(max)) and AUC for the retina were 1110 ng/g (day 60) and 47,200 ng · d/g, and for the vitreous humor were 213 ng/mL (day 60) and 11,300 ng · d/mL, respectively. The C(max) (T(max)) of DEX in plasma was 1.11 ng/mL (day 60). Compared with the level in the control eyes (no DEX implant), CYP3A8 expression in the retina was upregulated threefold up to 6 months after injection of the implant (0.969 ± 0.0565 vs. 3.07 ± 0.438; P < 0.05 up to 2-month samples). CONCLUSIONS: The in vivo release profile of the DEX implant in an animal eye was similar to the pharmacokinetics achieved with pulse administration of corticosteroids (high initial drug concentration, followed by a prolonged period of low concentration). These results are consistent with those in clinical studies supporting the use of the DEX implant for the extended management of posterior segment diseases.

Ocular pharmacokinetics of 0.45% ketorolac tromethamine.

PURPOSE: A new carboxymethylcellulose (CMC)-containing ophthalmic formulation of 0.45% ketorolac, pH 6.8 (Acuvail(®)) was recently developed for treatment of inflammation and pain after cataract surgery. This study compared pharmacokinetics of the new formulation with that of a prior formulation, 0.4% ketorolac, pH 7.4 (Acular LS(®)). METHODS: Ketorolac formulations were administered bilaterally (35 µL) to female New Zealand White rabbits. Samples from aqueous humor and iris-ciliary body were collected at multiple time points, and ketorolac was quantified using liquid chromatography-tandem mass spectrometry. RESULTS: In aqueous humor, the peak concentration (C(max)) and area under the concentration-time curve (AUC(0-τ)) of ketorolac were, respectively, 389 ng/mL and 939 ng·h/mL following administration of the CMC-containing 0.45% ketorolac, pH 6.8, and 211 ng/mL and 465 ng·hr/mL following administration of the 0.4% ketorolac, pH 7.4. In iris-ciliary body, C(max) and AUC(0-τ) of ketorolac were, respectively 450 ng/g and 2040 ng·h/g after administration of the CMC-containing 0.45% ketorolac, pH 6.8, and 216 ng/g and 699 ng·h/g after administration of the 0.4% ketorolac, pH 7.4. PK simulations predicted an AUC(0-τ) of 2910 ng·h/g for twice daily, CMC-containing 0.45% ketorolac, pH 6.8, compared to 725 ng·h/g for 4 times daily, 0.4% ketorolac, pH 7.4. CONCLUSIONS: The CMC-containing formulation of 0.45% ketorolac, pH 6.8, increased ketorolac bioavailability by 2-fold in aqueous humor and by 3-fold in iris-ciliary body in comparison to the 0.4% ketorolac, pH 7.4, allowing a reduced dosing schedule from 4 times daily to twice daily.

Sensitivity and proportionality assessment of metabolites from microdose to high dose in rats using LC-MS/MS.

BACKGROUND: The objective of this study was to evaluate the sensitivity requirement for LC-MS/MS as an analytical tool to characterize metabolites in plasma and urine at microdoses in rats and to investigate proportionality of metabolite exposure from a microdose of 1.67 µg/kg to a high dose of 5000 µg/kg for atorvastatin, ofloxacin, omeprazole and tamoxifen. RESULTS: Only the glucuronide metabolite of ofloxacin, the hydroxylation metabolite of omeprazole and the hydration metabolite of tamoxifen were characterized in rat plasma at microdose by LC-MS/MS. The exposure of detected metabolites of omeprazole and tamoxifen appeared to increase in a nonproportional manner with increasing doses. Exposure of ortho- and para-hydroxyatorvastatin, but not atorvastatin and lactone, increased proportionally with increasing doses. CONCLUSION: LC-MS/MS has demonstrated its usefulness for detecting and characterizing the major metabolites in plasma and urine at microdosing levels in rats. The exposure of metabolites at microdose could not simply be used to predict their exposure at higher doses.

Microdosing assessment to evaluate pharmacokinetics and drug metabolism in rats using liquid chromatography-tandem mass spectrometry.

PURPOSE: To evaluate the sensitivity requirement for LC-MS/MS as an analytical tool to support human microdosing study with sub-pharmacological dose, investigate proportionality of pharmacokinetics from the microdose to therapeutic human equivalent doses in rats and characterize circulating metabolites in rats administered with the microdose. MATERIALS AND METHODS: Five drugs of antipyrine, metoprolol, carbamazepine, digoxin and atenolol were administered orally to male Sprague-Dawley rats at 0.167, 1.67, 16.7, 167 and 1,670 microg/kg doses. Plasma samples were extracted using either solid phase extraction or liquid-liquid extraction, and analyzed using LC-MS/MS. RESULTS: Using 100 microl of plasma sample, the lower limit of quantitation for antipyrine (10 pg/ml), carbamazepine (1 pg/ml), metoprolol (5 pg/ml), atenolol (20 pg/ml), and digoxin (5 pg/ml) were achieved using an API 5000. Proportional pharmacokinetics were observed from 0.167 microg/kg to 1,670 microg/kg for antipyrine and carbamazepine and from 1.67 to 1,670 microg/kg for atenolol and digoxin, while metoprolol exhibited a non-proportional pharmacokinetics relationship. Several metabolites of carbamazepine were characterized in plasma from rats dosed at 1.67 mug/kg using LC-MS/MS. CONCLUSIONS: This study has shown the promise of sensitive LC-MS/MS method to support microdose pharmacokinetics and drug metabolism studies in human.

AAPS-FDA workshop white paper: microdialysis principles, application and regulatory perspectives.

Many decisions in drug development and medical practice are based on measuring blood concentrations of endogenous and exogenous molecules. Yet most biochemical and pharmacological events take place in the tissues. Also, most drugs with few notable exceptions exert their effects not within the bloodstream, but in defined target tissues into which drugs have to distribute from the central compartment. Assessing tissue drug chemistry has, thus, for long been viewed as a more rational way to provide clinically meaningful data rather than gaining information from blood samples. More specifically, it is often the extracellular (interstitial) tissue space that is most closely related to the site of action (biophase) of the drug. Currently microdialysis (microD) is the only tool available that explicitly provides data on the extracellular space. Although microD as a preclinical and clinical tool has been available for two decades, there is still uncertainty about the use of microD in drug research and development, both from a methodological and a regulatory point of view. In an attempt to reduce this uncertainty and to provide an overview of the principles and applications of microD in preclinical and clinical settings, an AAPS-FDA workshop took place in November 2005 in Nashville, TN, USA. Stakeholders from academia, industry and regulatory agencies presented their views on microD as a tool in drug research and development.

Effects of the preservative purite on the bioavailability of brimonidine in the aqueous humor of rabbits.

PURPOSE: To determine aqueous humor concentrations of brimonidine given the following ophthalmic formulations in female New Zealand White Rabbits: (1) BAK-preserved brimonidine tartrate 0.20% at a pH of 6.4; (2) BAK-preserved brimonidine tartrate 0.15% at a pH of 6.4, and (3) Purite((R))-preserved brimonidine tartrate 0.15% at a pH of 7.3. METHODS: Eighteen (18) animals were given a 35-microL drop of formulation into each eye. Aqueous humor samples were collected at 9 time points over 8 hours. Brimonidine concentrations were quantified using LC-MS/MS. RESULTS: The C(max) was achieved between 0.33-0.67 hours postdosing for all 3 formulations. Mean C(max) after Purite-preserved brimonidine tartrate 0.15% was 88% higher than that after BAK-preserved brimonidine tartrate 0.15% (p = 0.040), and 44% higher than that after BAK-preserved brimonidine tartrate 0.20% (p = 0.0784). AUC(0-3 hr) values were comparable for all 3 formulations. CONCLUSIONS: Purite-preserved brimonidine tartrate 0.15% produced higher peak concentrations than BAK-preserved brimonidine tartrate 0.15%. It also had a concentration that was comparable to BAK-preserved brimonidine tartrate 0.20%. The differences in safety may result from the change in preservative.

Evaluation of an immortalized retinal endothelial cell line as an in vitro model for drug transport studies across the blood-retinal barrier.

PURPOSE: To evaluate the growth and barrier properties of an immortalized rat retinal endothelial cell line (TR-iBRB) maintained on permeable membrane for drug transport studies. METHODS: TR-iBRB cells were grown on permeable membrane filters. The effect of coating material on cell growth was investigated. Transport of [14C]-3-O-methyl-D-glucose (3-OMG), AGN 194716, AGN 195127, AGN 197075, acebutolol, alprenolol, atenolol, brimonidine, carbamazepine epoxide (CBZ-E), metoprolol, nadolol, rhodamine 123, and sotalol was measured across the cultured cell layer to determine the apparent permeability coefficients (Papp). Rhodamine 123 uptake into these cells in the presence of these test compounds was evaluated. Western blot was performed to detect the efflux transporter P-glycoprotein (P-gp). Bidirectional transport in MDR1-MDCK cell monolayers overexpressing the human P-gp was measured for AGN 197075. RESULTS: TR-iBRB cells form confluent cell layers when grown on fibronectin-coated membrane and exhibit characteristic spindle-shaped morphology. A good correlation between Papp and cLogD (pH 7.4) of the compounds tested was observed, except for 3-OMG, AGN 197075, and rhodamine 123, which are substrates of carrier-mediated transport systems such as P-gp and a glucose transporter (GLUT1). When grown on permeable membrane, TR-iBRB cells expressed functional P-gp and GLUT1. CONCLUSIONS: TR-iBRB cells, when grown on permeable membrane, provide a useful tool for predicting permeability across the BRB. The usefulness of this model for high-throughput screening and rank ordering of drug candidates intended for the back of the eye in treatment of ocular diseases needs further characterization upon correlation with in vivo data.

Formulation effects on ocular absorption of brimonidine in rabbit eyes.

Purite (stabilized oxychloro complex) and benzalkonium chloride (BAK) are preservatives. We investigated formulation effects on ocular absorption of brimonidine in rabbit eyes. The formulations compared were: Alphagan (0.2% brimonidine tartrate/0.005% BAK, pH 6.4), Brimonidine-Purite (0.2% brimonidine tartrate/0.005% Purite, pH 7.2), and Brimonidine-PF (0.2% brimonidine tartrate, preservative-free (PF), pH 6.4) solutions. The study was conducted in a cross-over fashion; albino rabbits (n = 18) were given a single 35 microl drop of each test formulation in each eye. Aqueous humor samples were collected at selected times post-dose from subgroups of 2 rabbits per timepoint and analyzed for brimonidine concentrations by LC-MS/MS. The AUC and Cmax were calculated. The results showed rapid ocular absorption of brimonidine, with peak concentrations at 0.33-1 hr. The AUC(0-5hr) values were 3.78 +/- 0.38, 2.77 +/- 0.22, and 2.49 +/- 0.22 microg-hr/ml (mean +/- SEM) for Brimonidine-Purite, Alphagan and Brimonidine-PF, respectively. The corresponding Cmax values were 2.69 +/- 0.72, 1.74 +/- 0.13, and 1.24 +/- 0.22 microg/ml (mean +/- SEM). Brimonidine-Purite provided significantly higher AUC(0-5hr) than Alphagan (p < 0.05). No statistical significant difference in AUC(0-5hr) was found between Alphagan and Brimonidine-PF. In conclusion, 0.2% Brimonidine-Purite was 1.4 and 1.5 times more ocularly bioavailable in rabbits than 0.2% Alphagan and 0.2% Brimonidine-PF, respectively.