Interactions between the dopamine agonist, bromocriptine and the efflux protein, P-glycoprotein at the blood-brain barrier in the mouse.

Bromocriptin (BCT) is a dopaminergic receptor agonist, poorly transported through the blood-brain barrier (BBB) and responsible for central side effects. Interactions between BCT and the efflux protein, P-glycoprotein (Pgp), have been described in vitro but nothing is known in vivo nor at the BBB level. At the BBB, in vivo, we investigated BCT as (i) a Pgp substrate by comparing the brain uptake in CF1 mdr1a(-/-) and mdr1a(+/+) mice with or without inhibitors of Pgp (valspodar, elacridar); (ii) a Pgp inducer by looking at the effect of repeated doses of BCT on cerebral uptake of digoxin and comparing it to the effect of dexamethasone and rifampicin; (iii) a Pgp inhibitor by determining the effect of a single dose of BCT on cerebral uptake of digoxin and comparing it to the effect of valspodar. CF1 mdr1a(-/-) mice showed much higher brain uptake of BCT than CF1 mdr1a(+/+) mice and brain uptake of BCT was higher in CF1 mdr1a(+/+) mice pre-treated with valspodar or elacridar indicating that BCT is a Pgp substrate at the BBB level. Brain uptake of digoxin was not modified in CF1 mdr1a(+/+) mice pre-treated with a single dose or repeated doses of BCT, indicating that BCT is neither a Pgp inductor nor a Pgp inhibitor at the BBB in the chosen experimental setting. In vivo, at the mouse BBB level and in our experimental conditions, bromocriptin is a Pgp substrate but is not a Pgp modulator.     

Differences in the transport of the antiepileptic drugs phenytoin, levetiracetam and carbamazepine by human and mouse P-glycoprotein

In view of the important role of P-glycoprotein (Pgp) and other drug efflux transporters for drug distribution and resistance, the identification of compounds as substrates of Pgp-mediated transport is one of the key issues in drug discovery and development, particularly for compounds acting on the central nervous system. In vitro transport assays with Pgp-transfected kidney cell lines are widely used to evaluate the potential of compounds to act as Pgp substrates or inhibitors. Furthermore, such cell lines are also frequently utilized as a substitute for more labor-intensive in vitro or in vivo models of the blood-brain barrier (BBB). Overexpression of Pgp or members of the multidrug resistance protein (MRP) family at the BBB has been implicated in the mechanisms underlying resistance to antiepileptic drugs (AEDs) in patients with epilepsy. Therefore, it is important to know which AEDs are substrates for Pgp or MRPs. In the present study, we used monolayers of polarized MDCKII dog kidney or LLC-PK1 pig kidney cells transfected with cDNA containing either human MDR1, MRP2 or mouse mdr1a and mdr1b sequences to measure the directional transport of AEDs. Cyclosporin A (CsA) and vinblastine were used as reference standards for Pgp and MRP2, respectively. The AEDs phenytoin and levetiracetam were directionally transported by mouse but not human Pgp, whereas CsA was transported by both types of Pgp. Carbamazepine was not transported by any type of Pgp and did not inhibit the transport of CsA. In contrast to vinblastine, none of the AEDs was transported by MRP2 in transfected kidney cells. The data indicate that substrate recognition or transport efficacy by Pgp differs between human and mouse for certain AEDs. Such species differences, which are certainly not restricted to human and mouse, may explain, at least in part, the controversial data which have been previously reported for AED transport by Pgp in preparations from different species. However, because transport efficacy of efflux transporters such as Pgp or MRP2 may not only differ between species but also between tissues, the present data do not exclude that the AEDs examined are weak substrates of Pgp or MRP2 at the human BBB.     

Active efflux of the 5-HT(1A) receptor agonist flesinoxan via P-glycoprotein at the blood-brain barrier.

The role of P-glycoprotein on the efflux of the 5-HT(1A) receptor agonist flesinoxan across the blood-brain barrier in vivo and in vitro was investigated. In vitro, the transport ratios (representing polarized transport) of flesinoxan (10 microg/ml) were 4.2 in the MDR1-transfected LLC-PK1 cell line, which could be inhibited by the Pgp modulators SDZ-PSC 833 and LY 335979 and 1.1 in the wild-type LLC-PK1 cell line after 4 h. Flesinoxan concentrations lower than 33 microg/ml were actively transported by Pgp, while at higher concentrations Pgp became saturated and transport in the MDR1-transfected cell line was comparable with the wild-type cell line. In the in vitro BBB co-culture model the transport ratio was 2.0 and was decreased to 1.0 in the presence of Pgp modulators. In vivo, the accumulation of flesinoxan in the brain at 3 h was much higher in the mdr1a(-/-) mice compared to mdr1a(+/+) mice (ratio 12.6 and 27.0 at dose levels of 3 mg/kg and 10 mg/kg respectively). In conclusion, both in vivo as well as in vitro results have demonstrated that Pgp is a limiting factor for the transport of the 5-HT(1A) receptor agonist flesinoxan into the CNS. This should be considered when its application in therapy is combined with other Pgp substrates.     

BBB Transport and P-glycoprotein Functionality Using MDR1A (-/-) and Wild-Type Mice. Total Brain Versus Microdialysis Concentration Profiles of Rhodamine-123

Purpose. The effect of P-glycoprotein (Pgp) on brain distribution using mdrla (-/-) mice was investigated. Methods. Fluorescein (Flu) and FD-4 were used to check whether blood-brain barrier (BBB) integrity was maintained in mdrla (-/-) mice. The Pgp substrate rhodamine-123 (R123) was infused and total brain, blood and brain microdialysate concentrations in mdrla (-/-) mice and wild-type mice were compared. Results. Maintenance of BBB integrity was indicated by equal total brain/blood ratios of Flu and FD-4 in both mice types. R123 concentrations in brain after i.v. infusion were about 4-fold higher in mdrla (-/-) than in wild-type mice (P < 0.05), without changes in blood levels. After microdialysis experiments the same results were found, excluding artifacts in the interpretation of Pgp functionality by the use of this technique. However the 4-fold ratio in brain was not reflected in corresponding microdialysates. No local differences of R123 in the brain were found. By the no-net-flux method in vivo recovery appeared to 4.6-fold lower in mdrla (-/-) mice compared with wild-type mice. Conclusions. Pgp plays an important role in R123 distribution into the brain. Using intracerebral microdialysis, changes in in vivo recovery by the absence or inhibition of Pgp (or active efflux in general) need to be considered carefully.     

Application of in vivo brain microdialysis to the study of blood-brain barrier transport of drugs

Recent advances in blood-brain barrier (BBB) research have led to a new understanding of drug transport processes at the BBB. The BBB acts as a dynamic regulatory interface at which nutrients necessary for neural activity are actively taken up into the brain from the blood circulation, and actively excludes metabolites that might interfere with the maintenance of brain homeostasis. Such influx and efflux transport functions at the BBB would also control the concentrations of various drugs in the brain interstitial fluid (ISF), which are an important determinant of the central nervous system (CNS) effects. Thus, direct measurement of the brain ISF concentration of drugs can provide significant information for clarifying the influx and efflux transport functions of drugs across the BBB. Although several experimental techniques have been developed to investigate transport functions across the BBB, in vivo brain microdialysis seems to be one of the most suitable techniques for characterizing the influx and efflux transport functions across the BBB under physiological and pathological conditions. This review covers studies during the past decade, in which the influx and efflux transport of drugs across the BBB was kinetically and mechanistically evaluated by means of the brain microdialysis technique. Some applications of brain microdialysis to studies on neuronal function and neurotherapeutics are also included.     

In vitro and in vivo investigations on fluoroquinolones; effects of the P-glycoprotein efflux transporter on brain distribution of sparfloxacin.

The role of mdr1a-encoded P-glycoprotein on transport of several fluoroquinolones across the blood-brain barrier was investigated. In vitro, P-glycoprotein substrates were selected by using a confluent monolayer of MDR1-LLC-PK1 cells. The inhibition of fluoroquinolones (100 microM) on transport of rhodamine-123 (1 microM) was compared with P-glycoprotein inhibitors verapamil (20 microM) and SDZ PSC 833 (2 microM). Subsequently, transport polarity of fluoroquinolones was studied. Sparfloxacin showed the strongest inhibition (26%) and a large polarity in transport, by P-glycoprotein activity. In vivo, using mdr1a (-/-) and wild-type mice, brain distribution of pefloxacin, norfloxacin, ciprofloxacin, fleroxacin and sparfloxacin was determined at 2, 4, and 6 h following intra-arterial infusion (50 nmol/min). Brain distribution of sparfloxacin was clearly higher in mdr1a (-/-) mice compared with wild-type mice. Sparfloxacin was infused (50 nmol/min) for 1, 2, 3 and 4 h in which intracerebral microdialysis was performed. At 4 h, in vivo recovery (dynamic-no-net-flux method) was 6.5+/-2.2 and 1.5+/-0.5%; brain(ECF) concentrations were 5.1+/-0.2 and 26+/-21 microM; and total brain concentrations were 7.2+/-0.3 and 23+/-0.3 microM in wild-type and mdr1a (-/-) mice, respectively. Plasma concentrations were similar (18.4+/-0.7 and 17.9+/-0.5 microM, respectively). In conclusion, sparfloxacin enters the brain poorly mainly because of P-glycoprotein activity at the blood-brain barrier.     

Toward the prediction of CNS drug-effect profiles in physiological and pathological conditions using microdialysis and mechanism-based pharmacokinetic-pharmacodynamic modeling

Our ultimate goal is to develop mechanism-based pharmacokinetic (PK)-pharmacodynamic (PD) models to characterize and to predict CNS drug responses in both physiologic and pathologic conditions. To this end, it is essential to have information on the biophase pharmacokinetics, because these may significantly differ from plasma pharmacokinetics. It is anticipated that biophase kinetics of CNS drugs are strongly influenced by transport across the blood-brain barrier (BBB). The special role of microdialysis in PK/PD modeling of CNS drugs lies in the fact that it enables the determination of free-drug concentrations as a function of time in plasma and in extracellular fluid of the brain, thereby providing important data to determine BBB transport characteristics of drugs. Also, the concentrations of (potential) extracellular biomarkers of drug effects or disease can be monitored with this technique. Here we describe our studies including microdialysis on the following: (1) the evaluation of the free drug hypothesis; (2) the role of BBB transport on the central effects of opioids; (3) changes in BBB transport and biophase equilibration of anti-epileptic drugs; and (4) the relation among neurodegeneration, BBB transport, and drug effects in Parkinson's disease progression.     

The role of P-glycoprotein in blood-brain barrier transport of morphine: transcortical microdialysis studies in mdr1a (-/-) and mdr1a (+/+) mice.

1. The aim of this study was to investigate whether blood-brain barrier transport of morphine was affected by the absence of mdr1a-encoded P-glycoprotein (Pgp), by comparing mdr1a (-/-) mice with mdr1a (+/+) mice. 2. Mdr1a (-/-) and (+/+) mice received a constant infusion of morphine for 1, 2 or 4 h (9 nmol/min/mouse). Microdialysis was used to estimate morphine unbound concentrations in brain extracellular fluid during the 4 h infusion. Two methods of estimating in vivo recovery were used: retrodialysis with nalorphine as a calibrator, and the dynamic-no-net-flux method. 3. Retrodialysis loss of morphine and nalorphine was similar in vivo. Unbound brain extracellular fluid concentration ratios of (-/-)/(+/+) were 2.7 for retrodialysis and 3.6 for the dynamic-no-net-flux at 4 h, with corresponding total brain concentration ratios of (-/-)/(+/+) being 2.3 for retrodialysis and 2.6 for the dynamic-no-net-flux. The total concentration ratios of brain/plasma were 1.1 and 0.5 for mdr1a (-/-) and (+/+) mice, respectively. 4. No significant differences in the pharmacokinetics of the metabolite morphine-3-glucoronide were observed between (-/-) and (+/+) mice. 5. In conclusion, comparison between mdr1a (-/-) and (+/+) mice indicates that Pgp participates in regulating the amount of morphine transport across the blood-brain barrier.     

Caco-2 permeability,P-glycoprotein transport ratios and brain penetration of heterocyclic drugs

In this study the gastrointestinal absorption and P-glycoprotein (Pgp) efflux transport of heterocyclic drugs was investigated with the Caco-2 cell model. Based on the calculation of the physico-chemical properties a good oral absorption was predicted for all the drugs tested in this study which corresponded well with the measured Caco-2 permeabilities (Papp). Generally a high permeability of the tested heterocyclic drugs was measured being in agreement with earlier published human in vivo absorption data. Based on the transport data of domperidone and verapamil it was found that the Pgp efflux transporter was expressed in the Caco-2 cells. Many of the drugs tested were indicated to be potential Pgp efflux substrates. Since Pgp is expressed at the Blood Brain Barrier (BBB) as well, it was expected that CNS penetration will be impaired if a drug is a Pgp substrate. However, no correlation could be found between brain penetration in rats and the Pgp efflux ratio as measured with the Caco-2 cells. From the data it is concluded that Pgp efflux ratio's as determined in in vitro High Throughput Screening (HTS) tests, where the transport conditions are fixed (pH gradient, concentration, etc.), cannot routinely be used to predict a possible limited brain penetration.     

Do ATP-binding cassette transporters cause pharmacoresistance in epilepsy? Problems and approaches in determining which antiepileptic drugs are affected

Resistance to multiple antiepileptic drugs (AEDs) is a common problem in epilepsy, affecting at least 30% of patients. One prominent hypothesis to explain this resistance suggests an inadequate penetration or excess efflux of AEDs across the blood - brain barrier (BBB) as a result of overexpressed efflux transporters such as P-glycoprotein (Pgp), the encoded product of the multidrug resistance- 1 (MDR1, ABCB1) gene. Pgp and MDR1 are markedly increased in epileptogenic brain tissue of patients with AED-resistant partial epilepsy and following seizures in rodent models of partial epilepsy. In rodent models, AED-resistant rats exhibit higher Pgp levels than responsive animals; increased Pgp expression is associated with lower brain levels of AEDs; and, most importantly, co-administration of Pgp inhibitors reverses AED resistance. Thus, it is reasonable to conclude that Pgp plays a significant role in mediating resistance to AEDs in rodent models of epilepsy - however, whether this phenomenon extends to at least some human refractory epilepsy remains unclear, particularly because it is still a matter of debate which AEDs, if any, are transported by human Pgp. The difficulty in determining which AEDs are substrates of human Pgp is mainly a consequence of the fact that AEDs are highly permeable compounds, which are not easily identified as Pgp substrates in in vitro models of the BBB, such as monolayer (Transwell(?)) efflux assays. By using a modified assay (concentration equilibrium transport assay; CETA), which minimizes the influence of high transcellular permeability, two groups have recently demonstrated that several major AEDs are transported by human Pgp. Importantly, it was demonstrated in these studies that Pgp-mediated transport highly depends on the AED concentration and may not be identified if concentrations below or above the therapeutic range are used. In addition to the efflux transporters, seizure-induced alterations in BBB integrity and activity of drug metabolizing enzymes (CYPs) affect the brain uptake of AEDs. For translating these findings to the clinical arena, in vivo imaging studies using positron emission tomography (PET) with (11)C-labelled AEDs in epileptic patients are under way.     

The Use of Intracerebral Microdialysis to Determine Changes in Blood-Brain Barrier Transport Characteristics

The aim of this study was to determine whether changes in the transport of drugs into the brain could be determined by in vivo intracerebral microdialysis. Atenolol was used as a model drug to determine blood-brain barrier (BBB) transport characteristics. In rats, unilateral opening of the blood-brain barrier was achieved by infusion of hyperosmolar mannitol (25%, w/v) into the left internal carotid artery. BBB transport, expressed as the ratio of the area under the curve (AUC) of atenolol in brain extracellular fluid over plasma, was three times higher for the mannitol treated hemisphere as compared with the contralateral brain or after infusion of saline, being (mean ± SEM) 0.094 ± 0.024 (n = 16), 0.029 ± 0.007 (n = 12) and 0.030 ± 0.009 (n = 12) respectively. Further evaluation of the data indicated that for experiments performed in the morning the mannitol infusion had little effect on the extent of transport of atenolol into the brain, while in the afternoon BBB transport was about 10-fold higher than in the contralateral and saline group. The mean afternoon ratios ± SEM were 0.155 ± 0.038 (n = 8), 0.012 ± 0.003 (n = 6) and 0.018 ± 0.006 (n = 6) respectively. It is concluded that intracerebral microdialysis is capable of revealing changes in BBB transport and regional and time-dependent differences in drug levels can be demonstrated with the use of this technique.     

Application of intracerebral microdialysis to study regional distribution kinetics of drugs in rat brain.

1. The purpose of the present study was to determine whether intracerebral microdialysis can be used for the assessment of local differences in drug concentrations within the brain. 2. Two transversal microdialysis probes were implanted in parallel into the frontal cortex of male Wistar rats, and used as a local infusion and detection device respectively. Within one rat, three different concentrations of atenolol or acetaminophen were infused in randomized order. By means of the detection probe, concentration-time profiles of the drug in the brain were measured at interprobe distances between 1 and 2 mm. 3. Drug concentrations were found to be dependent on the drug as well as on the interprobe distance. It was found that the outflow concentration from the detection probe decreased with increasing lateral spacing between the probes and this decay was much steeper for acetaminophen than for atenolol. A model was developed which allows estimation of kbp/Deff (transfer coefficient from brain to blood/effective diffusion coefficient in brain extracellular fluid), which was considerably larger for the more lipohilic drug, acetaminophen. In addition, in vivo recovery values for both drugs were determined. 4. The results show that intracerebral microdialysis is able to detect local differences in drug concentrations following infusion into the brain. Furthermore, the potential use of intracerebral microdialysis to obtain pharmacokinetic parameters of drug distribution in brain by means of monitoring local concentrations of drugs in time is demonstrated.     

Blood-brain barrier transport and brain distribution of morphine-6-glucuronide in relation to the antinociceptive effect in rats--pharmacokinetic/pharmacodynamic modelling.

1. The objective of this study was to investigate the contribution of the blood-brain barrier (BBB) transport to the delay in antinociceptive effect of morphine-6-glucuronide (M6G), and to study the equilibration of M6G in vivo across the BBB with microdialysis measuring unbound concentrations. 2. On two consecutive days, rats received an exponential infusion of M6G for 4 h aiming at a target concentration of 3000 ng ml(-1) (6.5 microM) in blood. Concentrations of unbound M6G were determined in brain extracellular fluid (ECF) and venous blood using microdialysis and in arterial blood by regular sampling. MD probes were calibrated in vivo using retrodialysis by drug prior to drug administration. 3. The half-life of M6G was 23+/-5 min in arterial blood, 26+/-10 min in venous blood and 58+/-17 min in brain ECF (P<0.05; brain vs blood). The BBB equilibration, expressed as the unbound steady-state concentration ratio, was 0.22+/-0.09, indicating active efflux in the BBB transport of M6G. A two-compartment model best described the brain distribution of M6G. The unbound volume of distribution was 0.20+/-0.02 ml g brain(-1). The concentration-antinociceptive effect relationships exhibited a clear hysteresis, resulting in an effect delay half-life of 103 min in relation to blood concentrations and a remaining effect delay half-life of 53 min in relation to brain ECF concentrations. 4. Half the effect delay of M6G can be explained by transport across the BBB, suggesting that the remaining effect delay of 53 min is a result of drug distribution within the brain tissue or rate-limiting mechanisms at the receptor level.     

Influence of multidrug resistance (MDR) proteins at the blood-brain barrier on the transport and brain distribution of enaminone anticonvulsants.

Previous in vitro studies evaluating the permeability of enaminones suggested that their blood-brain barrier (BBB) transport might be influenced by the presence of an efflux mechanism. Therefore, transport mechanisms responsible for these anticonvulsants across the BBB were examined. The transport of enaminones (1 x 10(-4) M) were evaluated over 120 min with verapamil (50 microM) and probenecid (100 microM) using bovine brain microvessel endothelial cells (BBMECs) to assess the role of multidrug resistant (MDR) transport proteins [i.e., P-glycoprotein (Pgp) and MDR protein 1 (MRP1)] on efflux, respectively. Uptake studies in the presence and absence of rhodamine 123 (R123; 3.2 and 5.0 microM) were also performed in a Pgp overexpressing cell line, MCF-7/Adr. Select enaminone esters (12.5 mg/kg) were administered intravenously to mdr 1 a/b (+/+), mdr 1 a/b (-/-) knockout and probenecid pretreated mice (20 +/- 5g). Enaminones and R123 were assayed with validated ultraviolet and fluorescence high-performance liquid chromatography methods, respectively. Verapamil and probenecid significantly ( p>0.05) inhibited the transport of select enaminone esters across BBMECs. Two enaminones caused a statistically significant increase in the uptake of R123 in MCF-7/Adr cells. Concentrations of select enaminones in mdr 1 a/b (-/-) mice brains were significantly higher ( p<0.05) compared with those in mdr 1 a/b (+/+) mice brains; however, no differences were observed in probenecid pretreated animals. Taken together, these results strongly suggest that Pgp may influence enaminone transport at the BBB and hence affect epilepsy treatment with these agents.     

In Situ Transport of Vinblastine and Selected P-glycoprotein Substrates: Implications for Drug-Drug Interactions at the Mouse Blood-Brain Barrier

PURPOSE: To study the intrinsic parameters of P-glycoprotein (P-gp) transport and drug-drug interactions at the blood-brain barrier (BBB), as few quantitative in vivo data are available. These parameters could be invaluable for comparing models and predicting the in vivo implications of in vitro studies. METHODS: The brains of P-gp-deficient mice mdr1a(-/-) and wild-type mice were perfused in situ using a wide range of colchicine, morphine, and vinblastine concentrations. The difference between the uptake by the wild-type and P-gp-deficient mice gave the P-gp-linked apparent transport at the BBB. Drug-drug interactions were examined using vinblastine and compounds that bind to P-gp sites (verapamil, progesterone, PSC833) other than the vinblastine site to take into account the multispecific drug P-gp recognition. RESULTS: P-gp limited the brain uptake of morphine and colchicine in a concentration-independent way up to 2 mM. In contrast, vinblastine inhibited its own P-gp transport with an IC50 of approximately 56 microM and a Hill coefficient of approximately 4. The vinblastine efflux by P-gp was described by a Km at 16 microM and a maximal efflux velocity, Jmax, of approximately 8 pmol s(-1) g(-1) of brain. Similarly, vinblastine brain transport was increased by inhibiting P-gp as shown by the IC50 ranking, which was PSC833 < verapamil < vinblastine < progesterone. CONCLUSIONS: P-gp is responsible for both capacity-limited and -unlimited transport of P-gp substrates at the mouse BBB. In situ perfusion of mdr1a(-/-) and wild-type mouse brains could be used to predict drug-drug interactions for P-gp at the mouse BBB.     

An integrated microdialysis rat model for multiple pharmacokinetic/pharmacodynamic investigations of serotonergic agents

INTRODUCTION: Integrated in vivo models applying intracerebral microdialysis in conjunction with automated serial blood sampling in conscious, freely moving rodents are an attractive approach for pharmacokinetic (PK) and simultaneous pharmacokinetic/pharmacodynamic (PK/PD) investigations of CNS active drugs within the same animal. In this work, the ability to obtain and correlate data in this manner was evaluated for the selective serotonin (5-HT) reuptake inhibitor (SSRI) escitalopram. METHODS: An instrumented rat model equipped with an intracerebral hippocampal microdialysis probe and indwelling arterial and venous catheters was applied in the studies. Concomitant with brain microdialysis, serial blood sampling was conducted by means of an automated blood sampling device. The feasibility of the rat model for simultaneous PK/PD investigations was examined by monitoring plasma and brain extracellular concentrations of escitalopram along with SSRI-associated pharmacological activity, monitored as changes in brain 5-HT levels and plasma corticosterone levels. RESULTS: Combining intracerebral microdialysis and automated blood sampling did not cause any detectable physiological changes with respect to basal levels of plasma corticosterone or brain 5-HT levels. Furthermore, the PK of escitalopram in hippocampus following intravenous injection was not influenced by the presence of vascular catheters. Conversion of escitalopram dialysate concentrations into absolute extracellular levels by means of in vivo retrodialysis was verified by the no-net-flux method, which gave similar recovery estimates. The PK of escitalopram could be characterized simultaneously in plasma and the hippocampus of conscious, freely moving rats. Concomitantly, the modulatory and functional effects of escitalopram could be monitored as increases in brain 5-HT and plasma corticosterone levels following drug administration. DISCUSSION: The applicability of intracerebral microdialysis combined with arterial blood sampling was demonstrated for simultaneous PK/PD investigations of escitalopram in individual rats under non-stressful conditions. Together, these temporal relationships provide multiple PK/PD information in individual animals, hence minimizing inter-animal variation using a reduced number of animals.     

Pharmacokinetic modelling of blood-brain barrier transport of escitalopram in rats

This study examined the pharmacokinetics and distribution of escitalopram in the brain extracellular fluid in rats by the concurrent use of intracerebral microdialysis and serial blood sampling. Following three constant intravenous infusions, drug concentrations in the hippocampus and plasma were monitored for 6 h. To estimate the integrated pharmacokinetics and intercompartmental transport parameters, including blood-brain barrier (BBB) transport over the entire dose range, unbound brain and plasma escitalopram concentration data from all doses were simultaneously analysed using compartmental modelling. The pharmacokinetic analysis revealed that systemic clearance decreased as a function of dose, which was incorporated in the integrated model. Escitalopram was rapidly and extensively transported across the BBB and distributed into the brain extracellular fluid. The modelling resulted in an estimated influx clearance into the brain of 535 microl/min/g brain, resulting in an unbound brain-to-plasma AUC ratio of 0.8 independent of escitalopram dose. The model may be applied for preclinical evaluations or predictions of escitalopram concentration-time courses in plasma as well as at the target site in the CNS for various dosing scenarios. In addition, this modelling approach may also be valuable for studying BBB transport characteristics for other psychotropic agents.     

Application of an in vivo brain microdialysis technique to studies of drug transport across the blood-brain barrier

There is a wide range of methods available for studying the transport of drugs across the blood-brain barrier (BBB) which is equipped with several systems to transport drugs as well as endogenous nutrients and waste products. The in vivo brain microdialysis technique, which allows direct sampling of the brain interstitial fluid (ISF), is a powerful means of characterizing influx and efflux transport across the BBB. In this paper, we review our results from the successful application of this technique to BBB drug transport studies. The drugs investigated include novel and CNS-active peptides, some agents that are actively removed from the brain ISF across the BBB, and a brain-directed prodrug.     

The use of microdialysis in CNS drug delivery studies. Pharmacokinetic perspectives and results with analgesics and antiepileptics

Microdialysis can give simultaneous information on unbound drug concentration-time profiles in brain extracellular fluid (ECF) and blood, separating the information on blood-brain barrier (BBB) processes from confounding factors such as binding to brain tissue or proteins in blood. This makes microdialysis suitable for studies on CNS drug delivery. It is possible to quantify influx and efflux processes at the BBB in vivo, and to relate brain ECF concentrations to central drug action. The half-life in brain ECF vs. the half-life in blood gives information on rate-limiting steps in drug delivery and elimination from the CNS. Examples are given on microdialysis studies of analgesic and antiepileptic drugs.     

The blood-brain barrier efflux transporters as a detoxifying system for the brain

The role played by efflux transport systems across the blood-brain barrier (BBB) in the disposition of xenobiotics in the brain is described. Several drugs and organic anions are transported across the BBB via P-glycoprotein and other carrier-mediated efflux transport systems. Studies using in vitro cultured brain capillary endothelial cells, kinetic analysis, and mdr1a gene knock-out mice have shown that P-glycoprotein, located on the BBB, restricts the entry of vincristine and quinidine to the brain. Brain microdialysis studies have demonstrated that the brain interstitial fluid (ISF) concentrations of quinolone antibiotics are significantly lower than their corresponding unbound serum concentrations. A distributed model analysis supports the finding that efflux transport systems on the BBB restrict distribution of 3'-azido-3'-deoxythymidine (AZT), 2',3'-dideoxyinosine (DDI), and quinolone antibiotics. A brain efflux index (BEI) method has been developed to provide direct evidence of an efflux transport system for carrying substrates from the cerebrum to the circulating blood across the BBB. The BEI method revealed the existence of carrier-mediated efflux organic anion transport systems for compounds such as p-aminohippuric acid, AZT, DDI, taurocholic acid, BQ-123, and estron sulfate. Moreover, cerebral neurotransmitters such as gamma-aminobutyric acid, L-glutamic acid, and L-aspartic acid are transported from brain to the circulating blood in the intact form via a carrier-mediated efflux transport system. The BBB not only restricts nonspecific permeation from the circulating blood to the brain, but also functions as an active efflux transport system for xenobiotics. Accordingly, the BBB plays a very important role by pumping xenobiotics and some endogenous compounds out of the brain, acting as a central nervous system (CNS)-specific detoxifying system supporting and maintaining normal cerebral function.