Kelly M. Mahar Doan scite author profile

Membrane permeability and P-glycoprotein (Pgp) can be limiting factors for blood-brain barrier penetration. The objectives of this study were to determine whether there are differences in the in vitro permeability, Pgp substrate profiles, and physicochemical properties of drugs for central nervous system (CNS) and non-CNS indications, and whether these differences are useful criteria in selecting compounds for drug development. Apparent permeability (P app ) and Pgp substrate profiles for 93 CNS (n ϭ 48) and non-CNS (n ϭ 45) drugs were determined by monolayer efflux. Calcein-AM inhibition assays were used to supplement the efflux results. The CNS set (2 of 48, 4.2%) had a 7-fold lower incidence of passive permeability values Ͻ150 nm/s compared with the non-CNS set (13 of 45, 28.9%). The majority of drugs (72.0%, 67 of 93) were not Pgp substrates; however, 49.5% (46 of 93) were positive in the calcein-AM assay when tested at 100 M. The CNS drug set (n ϭ 7 of 48, 14.6%) had a 3-fold lower incidence of Pgp-mediated efflux than the non-CNS drug set (n ϭ 19 of 45, 42.2%). Analysis of 18 physicochemical properties revealed that the CNS drug set had fewer hydrogen bond donors, fewer positive charges, greater lipophilicity, lower polar surface area, and reduced flexibility compared with the non-CNS group (p Ͻ 0.05), properties that enhance membrane permeability. This study on a large, diverse set of marketed compounds clearly demonstrates that permeability, Pgp-mediated efflux, and certain physicochemical properties are factors that differentiate CNS and non-CNS drugs. For CNS delivery, a drug should ideally have an in vitro passive permeability Ͼ150 nm/s and not be a good (B 3 A/A 3 B ratio Ͻ2.5) Pgp substrate.The delivery of a new drug candidate to the central nervous system (CNS) can be a significant challenge during drug development. Often, the CNS distribution of a drug is poor because of exclusion at the blood-brain barrier (BBB) (Abbott and Romero, 1996;Pardridge, 1997). The BBB is composed of a single layer of endothelial cells connected by tight junctions. Brain microvascular endothelial cells lack fenestrations, have few pinocytotic vesicles, and express a variety of metabolic enzymes and membrane efflux transporters, such as P-glycoprotein (Pgp) (Rubin and Staddon, 1999; Kusuhara and Sugiyama, 2001a,b). These features make the BBB a formidable barrier that drugs must overcome to reach the brain parenchyma.Early assessment of the ability of a drug candidate to penetrate the CNS is critical during the drug discovery selection process, especially for therapeutic indications that require delivery to a CNS site of action. Equally important is the ability to design drugs for non-CNS indications that have minimal brain penetration to avoid undesirable CNS side effects. Over the past several years, academia and industry have invested significant effort in the development and implementation of lead optimization screens, including in vitro assays and computational models to evaluate CNS penetration.A number o...

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Gastric pH and Gastric Residence Time in Fasted and Fed Conscious Cynomolgus Monkeys Using the Bravo® pH System

Chen

Doan

Portelli

et al. 2007

Pharm Res

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Impact ofSLCO1B1(OATP1B1) andABCG2(BCRP) genetic polymorphisms and inhibition on LDL-C lowering and myopathy of statins

et al. 2011

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Statins are the preferred class of drugs for treating patients with atherosclerosis and related coronary heart disease. Treatment with statins leads to significant low-density lipoprotein cholesterol (LDL-C) lowering, resulting in reductions in major coronary and vascular events. Statins are generally well tolerated and safe; however, their use is complicated by infrequent, but often serious, muscular adverse events. For many statins, both efficacy and risk of adverse muscle events can be influenced by membrane transporters, which are important determinants of statin disposition. Genetic polymorphisms and drug-drug interactions (DDIs) involving organic anion-transporting polypeptide 1B1 and breast cancer resistance protein have shown the capacity to reduce the activity of these transporters, resulting in changes in LDL-C lowering by statins, as well as changes in the frequency of adverse muscle events associated with their use. This review presents evidence for how reduced transporter activity impacts the safety and pharmacology of statins. It expands on the scope of other recent statin reviews by providing recommendations on in vitro evaluation of statin interaction potential, discussing how reduced transporter activity impacts statin management during drug development, and proposing ideas on how to evaluate the impact of DDI on statin efficacy during clinical trials. Furthermore, the potential clinical consequences of perturbing statin efficacy via DDI are discussed.

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Steady-State Brain Concentrations of Antihistamines in Rats

et al. 2004

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The purpose of this study was to measure the in vivo brain distribution of antihistamines and assess the influence of in vitro permeability, P-glycoprotein (Pgp) efflux, and plasma protein binding. Six antihistamines (acrivastine, chlorpheniramine, diphenhydramine doxylamine, fexofenadine, terfenadine) were selected based on previously reported in vitro permeability and Pgp efflux properties and dosed intravenously to steady-state plasma concentrations of 2–10 µmol/l in rats. Plasma and brain concentrations were measured by LC/MS/MS, and protein binding determined by ultrafiltration. Doxylamine, diphenhydramine and chlorpheniramine had brain-to-plasma concentration ratios of 4.34 ± 1.26, 18.4 ± 2.35 and 34.0 ± 9.02, respectively. These drugs had high passive membrane permeability (>310 nm/s), moderate protein binding (71–84%) and were not Pgp substrates; features that yield high CNS penetration. In contrast, acrivastine and fexofenadine had low brain-to-plasma ratios of 0.072 ± 0.014 and 0.018 + 0.002, consistent with low passive membrane permeability for both compounds (16.2 and 66 nm/s, respectively) and Pgp efflux. Finally, terfenadine had a brain-to-plasma ratio of 2.21 ± 1.00 even though it underwent Pgp-mediated efflux (in vitro ratio = 2.88). Terfenadine’s high passive permeability (285 nm/s) overcame the Pgp-mediated efflux to yield brain-to-plasma ratio >1. The brain-to-unbound plasma ratio was 22-fold higher suggesting that protein binding (96.3% bound) limited terfenadine’s brain distribution. In conclusion, passive membrane permeability, Pgp-mediated efflux and/or high plasma protein binding influence the in vivo brain distribution of antihistamine drugs.

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