Drug Levels In Brain Research Articles

Carbohydrate Nanoparticles for Brain Delivery.

Many brain tumors and neurological diseases can greatly benefit from the use of emerging nanotechnologies based on targeted nanomedicines that are able to noninvasively transport highly potent and specific pharmaceuticals across the blood-brain barrier. Carbohydrates have received considerable interest as materials for drug carriers due to their natural origin and inherent biodegradability and biocompatibility, as well as due to their hydrophilic character and ease of chemical modification combined with low cost and the possibility for large-scale manufacturing. This chapter provides an overview of the latest research involving the use of carbohydrate-based nanoparticles for drug delivery to the central nervous system. After reviewing the challenges posed by delivering drugs into the brain, the current state-of-the-art approaches for delivery of actives across the blood-brain barrier, including invasive and noninvasive strategies, are presented. A particular focus has been placed on chitosan polymers as they are among the most promising carbohydrate nanocarriers for the preparation and testing of chitosan-based nanomedicines that led, in preclinical proof-of-concept studies, to enhanced brain drug levels and increased pharmacodynamics responses after intravenous, nasal, and oral administration. While chitosan nanoparticles are to date among the most studied and most promising carriers, approaches based on other polysaccharides such as dextran, pullulan, and cellulose warrant further research in the attempt to advance the existing technologies for overcoming the blood-brain barrier.

Chronic treatment with varenicline changes expression of four nAChR binding sites in mice

IntroductionChronic treatment with nicotine is known to increase the α4β2-nAChR sites in brain, to decrease α6β2-nAChR sites and to have minimal effect on α3β4-and α7-nAChR populations. Varenicline is now used as a smoking cessation treatment, with and without continued smoking or nicotine replacement therapy. Varenicline, like nicotine, upregulates the α4β2-nAChR sites; however, it is not known whether varenicline treatment changes expression of the other nAChR subtypes. MethodsUsing a mouse model, chronic treatments (10 days) with varenicline (0.12 mg/kg/h) and/or nicotine (1 mg/kg/hr), alone or in combination, were compared for plasma and brain levels of drugs, tolerance to subsequent acute nicotine and expression of four subtypes of nAChR using autoradiography. ResultsThe upregulation of α4β2-nAChR sites elicited by chronic varenicline was very similar to that elicited by chronic nicotine. Treatment with both drugs somewhat increased up-regulation, indicating that these doses were not quite at maximum effect. Similar down-regulation was seen for α6β2-nAChR sites. Varenicline significantly increased both α3β4-and α7-nAChR sites while nicotine had less effect on these sites. The drug combination was similar to varenicline alone for α3β4-nAChR sites, while for α7 sites the drug combination was less effective than varenicline alone. Varenicline had small but significant effects on tolerance to acute nicotine. ConclusionsEffects of varenicline in vivo may not be limited to the α4β2*-nAChR subtype. In addition, smoking cessation treatment with varenicline may not allow receptor numbers to be restored to baseline and may, in addition, change expression of other receptor subtypes.

Effect of Brain CYP2B Inhibition on Brain Nicotine Levels and Nicotine Self-Administration.

The CYP2B enzyme is expressed in human and rat brain, and metabolizes many CNS-acting drugs. The gene that encodes human CYP2B6 is highly polymorphic, where the variation in brain enzyme levels could result in altered brain drug levels. CYP2B can metabolize nicotine, the main psychoactive ingredient in cigarettes; if altered brain CYP2B activity can influence nicotine brain levels, it could influence nicotine-mediated behaviors. To investigate this, a mechanism-based inhibitor selective for CYP2B, C8-xanthate (20 μg), was administered intracerebroventricularly (ICV) into the brain of rats, and 22 h later, nicotine levels were measured by in vivo microdialysis following nicotine (150 μg/kg intravenous). Brain nicotine levels from 15 to 30 min and the AUC0-45 min were both twofold higher (p<0.05) with C8-xanthate vs vehicle pretreatment; there was no difference in peripheral nicotine levels. Rats were then given ICV pretreatment with C8-xanthate/ASCF and underwent intravenous nicotine self-administration with 3.75-30 μg/kg per infusion dose. C8-xanthate pretreatment increased responding in progressive ratio (15 μg/kg per infusion dose, p<0.05). In a separate cohort, C8-xanthate increased the percentage of rats that acquired self-administration (7.5 μg/kg per infusion dose, p<0.05) from 40% after vehicle pretreatment to 100%, with no difference in peripheral nicotine levels measured at the end of behavior. In a third cohort, C8-xanthate increased the number of sessions required to meet extinction criteria (p<0.05). Together these data demonstrate that the brain CYP2B activity can influence nicotine brain levels and subsequent behaviors independent of hepatic metabolism. This suggests that human smokers with variable CYP2B brain levels could have different nicotine levels and reinforcement, which might have a role in smoking behaviors and dependence.

A critique of the drug discovery and phase 3 clinical programs targeting the amyloid hypothesis for Alzheimer disease.

In 1906, Alois Alzheimer described the neuropathology of the disease that was to bear his name. Subsequently, our understanding of Alzheimer disease (AD) has grown significantly. The autosomal dominant mutations to the amyloid precursor protein (APP), presenilin (PS) 1, and PS2 genes that cause early onset AD have been very informative, leading to the articulation of the amyloid cascade hypothesis. This hypothesis has been the basis for several disease-modifying therapeutic approaches for AD. This has been partly because it provided a coherent framework for understanding AD pathogenesis but also because several pharmacological approaches that targeted the amyloid peptide (amyloidocentric) were sufficiently well-founded scientifically to enter clinical development. In the past 5 years, there have been 6 amyloidocentric programs that completed phase 3 clinical testing. None met their primary outcome measures (Table 1), although 1, solanezumab, showed encouraging results in a prespecified secondary outcome measure. This disappointing track record has brought into question the amyloidocentric therapeutic approach. This review will consider these programs from the following perspectives:

Pharmacological blockade of IL-1β/IL-1 receptor type 1 axis during epileptogenesis provides neuroprotection in two rat models of temporal lobe epilepsy

We studied whether pharmacological blockade of the IL-1β-mediated signaling, rapidly activated in forebrain by epileptogenic injuries, affords neuroprotection in two different rat models of status epilepticus (SE). As secondary outcome, we measured treatment's effect on SE-induced epileptogenesis. IL-1β signaling was blocked by systemic administration of two antiinflammatory drugs, namely human recombinant IL-1 receptor antagonist (anakinra), the naturally occurring and clinically used competitive IL-1 receptor type 1 antagonist, and VX-765 a specific non-peptide inhibitor of IL-1β cleavage and release. Antiinflammatory drugs were given 60min after antiepileptic (AED) drug-controlled SE induced by pilocarpine, or 180min after unrestrained electrical SE, for 7days using a protocol yielding therapeutic drug levels in brain. This drug combination significantly decreased both IL-1β expression in astrocytes and cell loss in rat forebrain. Neuroprotection and the antiinflammatory effect were more pronounced in the electrical SE model. Onset of epilepsy, and frequency and duration of seizures 3months after electrical SE were not significantly modified. Transcriptomic analysis in the hippocampus showed that the combined treatment did not affect the broad inflammatory response induced by SE during epileptogenesis. In particular, the treatment did not prevent the induction of the complement system and Toll-like receptors, both contributing to cell loss and seizure generation.We conclude that the IL-1β signaling represents an important target for reducing cell loss after SE. The data highlight a new class of clinically tested agents affording neuroprotection after a delayed post-injury intervention. Earlier blockade of this rapid onset inflammatory pathway during SE, or concomitant treatment with antiinflammatory drugs targeting additional components of the broad inflammatory response to SE, or co-treatment with AEDs, is likely to be required for optimizing beneficial outcomes.

Discovery of neuroprotective soluble guanylate cyclase modulators (GCMs) aciting via NO/GC/cGMP/CREB pathway

NO/cGMP signaling is essential for normal brain function, including learning and memory, and mediation of long-term potentiation (LTP). NO/cGMP signaling is coupled to cholinergic, glutamatergic, and dopaminergic systems and plays key roles in motor function associated with Parkinson’s disease pathogenesis and L-DOPA therapy. In Alzheimer’s Disease (AD), early synaptic failure, has been linked to dysfunction of gene expression programs mediated via the transcription factor cAMP-response element binding protein (CREB), activation of which is tightly regulated by NO/cGMP. Since several neurodegenerative disorders continue to be dogmatically linked to the chemical toxicity of NO, activation of soluble guanylyl cyclase (sGC) represents a potential therapeutic approach in both AD and PD; whereas negative modulation of sGC may be of use in some stages of PD. Such small molecule sGC modulators (GCMs) can be assayed in cell cultures by measuring levels of phosphorylated CREB (pCREB). GCMs that allosterically potentiate NO activation of sGC have proven successful in clinical trials for peripheral indications, however, there are no reports directed at therapeutic activity in the CNS. The aim of this study is to develop GCMs for use in CNS disorders, including AD and PD. A library of GCMs was synthesized, including positive allosteric modulators (PAMs) and negative modulators, as assessed by increasing levels of pCREB in SH-SY5Y human neuroblastoma cell cultures. Molecules were designed by classical bioisosteric replacement, aiming for desirable physiochemical properties and chemical diversity. GCM PAMs were assayed for cGMP elevation and reversal of neurotoxicity induced by 6-hydroxydopamine in dopaminergic neuronal cells. One GCM PAM, active in cell culture, was further tested for the reversal of memory deficits in mice treated with scopolamine, and drug levels in brain and plasma measured. The ligand binding site for sGC stimulators and GCM PAMs on the sGC protein remains to be definitively defined. Photoaffinity probes were designed that retained the activity of the parent GCM PAM in cell cultures in order to elucidate the binding mode to sGC and to indicate other protein partners for such compounds.

SAHA Enhances Synaptic Function and Plasticity In Vitro but Has Limited Brain Availability In Vivo and Does Not Impact Cognition

Suberoylanilide hydroxamic acid (SAHA) is an inhibitor of histone deacetylases (HDACs) used for the treatment of cutaneous T cell lymphoma (CTCL) and under consideration for other indications. In vivo studies suggest reducing HDAC function can enhance synaptic function and memory, raising the possibility that SAHA treatment could have neurological benefits. We first examined the impacts of SAHA on synaptic function in vitro using rat organotypic hippocampal brain slices. Following several days of SAHA treatment, basal excitatory but not inhibitory synaptic function was enhanced. Presynaptic release probability and intrinsic neuronal excitability were unaffected suggesting SAHA treatment selectively enhanced postsynaptic excitatory function. In addition, long-term potentiation (LTP) of excitatory synapses was augmented, while long-term depression (LTD) was impaired in SAHA treated slices. Despite the in vitro synaptic enhancements, in vivo SAHA treatment did not rescue memory deficits in the Tg2576 mouse model of Alzheimer’s disease (AD). Along with the lack of behavioral impact, pharmacokinetic analysis indicated poor brain availability of SAHA. Broader assessment of in vivo SAHA treatment using high-content phenotypic characterization of C57Bl6 mice failed to demonstrate significant behavioral effects of up to 150 mg/kg SAHA following either acute or chronic injections. Potentially explaining the low brain exposure and lack of behavioral impacts, SAHA was found to be a substrate of the blood brain barrier (BBB) efflux transporters Pgp and Bcrp1. Thus while our in vitro data show that HDAC inhibition can enhance excitatory synaptic strength and potentiation, our in vivo data suggests limited brain availability may contribute to the lack of behavioral impact of SAHA following peripheral delivery. These results do not predict CNS effects of SAHA during clinical use and also emphasize the importance of analyzing brain drug levels when interpreting preclinical behavioral pharmacology.

Methods for intravenous self administration in a mouse model.

Animal models have been developed to study the reinforcing effects of drugs, including the intravenous self-administration (IVSA) paradigm. The advantages of using an IVSA paradigm to study the reinforcing properties of drugs of abuse such as cocaine include the fact that the drug is self-administered instead of experimenter-administered, the schedule of reinforcement can be altered, and accurate measurement of the quantities of drug consumed as well as the timing and pattern of IV injections can be obtained. Furthermore, the intravenous route of administration avoids potential confounds related to first pass metabolism or taste, and produces rapid increases in blood and brain drug levels. As outlined in this video, intravenous self-administration can be obtained without prior food restriction or prior drug training following careful catheter placement during surgery and meticulous daily catheter flushing and maintenance. Experimental procedures outlined in this paper include a description of animal housing and acclimation methods, operant training using sweetened milk solutions, and catheter implantation surgery.

Methods for Intravenous Self Administration in a Mouse Model

Animal models have been developed to study the reinforcing effects of drugs, including the intravenous self-administration (IVSA) paradigm. The advantages of using an IVSA paradigm to study the reinforcing properties of drugs of abuse such as cocaine include the fact that the drug is self-administered instead of experimenter-administered, the schedule of reinforcement can be altered, and accurate measurement of the quantities of drug consumed as well as the timing and pattern of IV injections can be obtained. Furthermore, the intravenous route of administration avoids potential confounds related to first pass metabolism or taste, and produces rapid increases in blood and brain drug levels. As outlined in this video, intravenous self-administration can be obtained without prior food restriction or prior drug training following careful catheter placement during surgery and meticulous daily catheter flushing and maintenance. Experimental procedures outlined in this paper include a description of animal housing and acclimation methods, operant training using sweetened milk solutions, and catheter implantation surgery.

Anti-cocaine antibody and butyrylcholinesterase-derived cocaine hydrolase exert cooperative effects on cocaine pharmacokinetics and cocaine-induced locomotor activity in mice

We are investigating treatments for cocaine abuse based on viral gene transfer of a cocaine hydrolase (CocH) derived from human butyrylcholinesterase, which can reduce cocaine-stimulated locomotion and cocaine-primed reinstatement of drug-seeking behavior in rats for many months. Here, in mice, we explored the possibility that anti-cocaine antibodies can complement the actions of CocH to reduce cocaine uptake in brain and block centrally-evoked locomotor stimulation. Direct injections of test proteins showed that CocH (0.3 or 1mg/kg) was effective by itself in reducing drug levels in plasma and brain of mice given cocaine (10mg/kg, s.c., or 20mg/kg, i.p). Administration of cocaine antibody per se at a low dose (8mg/kg, i.p.) exerted little effect on cocaine distribution. However, a higher dose of antibody (12mg/kg) caused peripheral trapping (increased plasma drug levels), which led to increased cocaine metabolism by CocH, as evidenced by a 6-fold rise in plasma benzoic acid. Behavioral tests with small doses of CocH and antibody (1 and 8mg/kg, respectively) showed that neither agent alone reduced mouse locomotor activity triggered by a very large cocaine dose (100mg/kg, i.p.). However, dual treatment completely suppressed the locomotor stimulation. Altogether, we found cooperative and possibly synergistic actions that warrant further exploration of dual therapies for treatment of cocaine abuse.

Enhanced brain accumulation of pazopanib by modulating P-gp and Bcrp1 mediated efflux with canertinib or erlotinib

Primary objective of this investigation was to delineate the differential impact of efflux transporters P-glycoprotein (P-gp/Abcb1) and breast cancer resistance protein (Bcrp1/Abcg2) on brain disposition and plasma pharmacokinetics of pazopanib. In addition, this research investigated whether inhibition of these efflux transporters with clinically relevant efflux modulators canertinib or erlotinib could be a viable strategy for improving pazopanib brain delivery. In vitro assays with MDCKII cell monolayers suggested that pazopanib is a high affinity substrate for Bcrp1 and a moderate substrate for P-gp. Co-incubation with specific transport inhibitors restored cell accumulation and completely abolished the directionality of pazopanib flux. Brain and plasma pharmacokinetic studies were conducted in FVB wild type mice in the absence and presence of specific transport inhibitors. Drug levels in plasma and brain were determined using a validated high performance liquid chromatography method using vandetanib as an internal standard. In vivo studies indicated that specific inhibition of either P-gp (by zosuquidar or LY335979) or Bcrp1 (by Ko143) alone did not significantly alter pazopanib brain accumulation. However, dual P-gp/Bcrp1 inhibition by elacridar (GF120918), significantly enhanced pazopanib brain penetration by ~5-fold without altering its plasma concentrations. Thus, even though Bcrp1 showed higher affinity towards pazopanib in vitro, in vivo at the mouse BBB both P-gp and Bcrp1 act in concert to limit brain accumulation of pazopanib. Furthermore, erlotinib and canertinib as clinically relevant efflux modulators efficiently abrogated directionality in pazopanib efflux in vitro and their co-administration resulted in 2-2.5-fold increase in pazopanib brain accumulation in vivo. Further pre-clinical and clinical investigations are warranted as erlotinib or canertinib may have a synergistic pharmacological effect in addition to their primary role of pazopanib efflux modulation as a combination regimen for the treatment of recurrent brain tumors.

An investigator-initiated monocentric phase I dose escalation trial of temsirolimus and irinotecan (TEMIR) in patients with relapsing glioblastoma multiforme (reGBM).

2086 Background: Deregulation of the PI3K/AKT pathway has been preclinically involved in the pathophysiology of GBM. The mammalian target of rapamycin (mTOR) is an important downstream mediator of PI3K/AKT signalling. The mTOR-inhibitor temsirolimus (Tem) achieves significant drug levels in brain. Thus, Tem may be effectively combined with irinotecan (Iri) which has shown promising results in combination with bevacizumab in patients (pts) with reGBM refractory to temozolomide (Tmz) in phase II. Exposure to Tem as well as Iri is substantially reduced in pts receiving CYP3A4 enzyme-inducing anticonvulsants (CYP3A4-Ind). Methods: TEMIR is a phase I trial of escalating doses of Tem in combination with Iri in pts with reGBM refractory to Tmz depending on the cotreatment with CYP3A4-Ind. In pts without CYP3A4-Ind dose escalation of Tem was performed according to the “3+3 protocol” from 15 via 20 to 25 mg iv wkly together with 85 mg/m2 Iri iv wkly. In pts with CYP3A4-Ind the doses of Tem were 30, 40 and 50 mg iv wkly together with 170 mg/m2 Iri iv wkly, respectively. The determination of the pharmacokinetics (PK) of Tem and its influence on the PK of Iri and its active metabolite SN38 was performed by validated RP-HPLC methods with fluorescence detection. Results: Up to now, 14 pts [4 female and 10 male, median age 47 yrs (range 41-65 yrs), 9 without and 5 with CYP3A4-Ind] have been treated. All 9 pts without CYP3A4-Ind (3 pts on 15, 20 and 25 mg Tem each) are evaluable for safety with only mild toxicity [highest CTC-grade ≥2 (gr) per pt]: diarrhea 4 (gr2) and 1 (gr3), neutropenia 1 (gr3), thrombopenia 1 (gr2), anemia 1 (gr2), pneumonia 2 (gr2), rash 1 (gr2). PK parameters of Iri and SN38 were in agreement with previously published studies and there was no significant effect of 15 to 25 mg Tem combined with 85 mg/m2 Iri on the PK of Iri and SN38. In 7 pts evaluable for efficacy there was no remission (RECIST) and median time to symptomatic and/or MRT progression was 10 wks (7, 9+, 10, 10+, 11, 15, 20 wks). Conclusions: The combination of Tem in standard dose of 25 mg iv wkly with 85 mg/m2 Iri wkly is safe in pts with reGBM without CYP3A4-Ind. Tem has no significant effect on the PK of Iri and SN38.

A Prodrug Nanoparticle Approach for the Oral Delivery of a Hydrophilic Peptide, Leucine5-enkephalin, to the Brain

The oral use of neuropeptides to treat brain disease is currently not possible because of a combination of poor oral absorption, short plasma half-lives and the blood-brain barrier. Here we demonstrate a strategy for neuropeptide brain delivery via the (a) oral and (b) intravenous routes. The strategy is exemplified by a palmitic ester prodrug of the model drug leucine(5)-enkephalin, encapsulated within chitosan amphiphile nanoparticles. Via the oral route the nanoparticle-prodrug formulation increased the brain drug levels by 67% and significantly increased leucine(5)-enkephalin's antinociceptive activity. The nanoparticles facilitate oral absorption and the prodrug prevents plasma degradation, enabling brain delivery. Via the intravenous route, the nanoparticle-prodrug increases the peptide brain levels by 50% and confers antinociceptive activity on leucine(5)-enkephalin. The nanoparticle-prodrug enables brain delivery by stabilizing the peptide in the plasma although the chitosan amphiphile particles are not transported across the blood-brain barrier per se, and are excreted in the urine.

The effect of prolyl oligopeptidase inhibition on extracellular acetylcholine and dopamine levels in the rat striatum

Prolyl oligopeptidase (PREP, EC 3.4.21.26) inhibitors have potential as cognition enhancers, but the mechanism of action behind the cognitive effects remains unclear. Since acetylcholine (ACh) and dopamine (DA) are known to be associated with the regulation of cognitive processes, we investigated the effects of two PREP inhibitors on the extracellular levels of ACh and DA in the rat striatum using in vivo microdialysis. KYP-2047 and JTP-4819 were administered either as a single systemic dose (50μmol/kg∼17mg/kg i.p.) or directly into the striatum by retrodialysis via the microdialysis probe (12.5, 37.5 or 125μM at 1.5μl/min for 60min). PREP inhibitors had no significant effect on striatal DA levels after systemic administration. JTP-4819 significantly decreased ACh levels both after systemic (by ∼25%) and intrastriatal (by ∼30–50%) administration. KYP-2047 decreased ACh levels only after intrastriatal administration by retrodialysis (by ∼40–50%) when higher drug levels were reached, indicating that higher brain drug levels are needed to modulate ACh levels than to inhibit PREP. This result does not support the earlier hypothesis that the positive cognitive effects of PREP inhibitors in rodents would be mediated through the cholinergic system. In vitro specificity studies did not reveal any obvious off-targets that could explain the observed effect of KYP-2047 and JTP-4819 on ACh levels, instead confirming the concept that these compounds have a high selectivity towards PREP.

Brain-Cocaine Concentrations Determine the Dose Self-Administered by Rats on a Novel Behaviorally Dependent Dosing Schedule

A novel behaviorally dependent dosing (BDD) schedule was used to examine the relationship between doses of cocaine self-administered by rats and brain drug levels within a session. The BDD schedule used a hold-down response to activate a syringe pump. The length of time the lever was held down determined the duration that the syringe pump was activated. In the first experiment, rats self-administered cocaine for daily 3 h sessions and brain levels of cocaine were modeled using well-established parameters. Although analysis revealed that rats self-administered doses within a predicted range, one extremely large dose was consistently observed at the beginning of each session when brain levels of cocaine were low. In the second experiment, we introduced a range of timeout periods (10-25 min) in order to produce variability in brain-cocaine concentrations. Animals self-administered larger doses immediately following each timeout period and the dose size was inversely correlated with the length of the timeout. These results show that the dose of cocaine that rats self-administer within a session is inversely related to the amount of drug on board.

Design and Discovery of a Selective Small Molecule κ Opioid Antagonist (2-Methyl-N-((2′-(pyrrolidin-1-ylsulfonyl)biphenyl-4-yl)methyl)propan-1-amine, PF-4455242)

By use of parallel chemistry coupled with physicochemical property design, a series of selective κ opioid antagonists have been discovered. The parallel chemistry strategy utilized key monomer building blocks to rapidly expand the desired SAR space. The potency and selectivity of the in vitro κ antagonism were confirmed in the tail-flick analgesia model. This model was used to build an exposure-response relationship between the κ K(i) and the free brain drug levels. This strategy identified 2-methyl-N-((2'-(pyrrolidin-1-ylsulfonyl)biphenyl-4-yl)methyl)propan-1-amine, PF-4455242, which entered phase 1 clinical testing and has demonstrated target engagement in healthy volunteers.

Kinetic interaction between fluoxetine and imipramine as a function of elevated serum alpha-1-acid glycoprotein levels.

The effect of elevated serum alpha-1-acid glycoprotein (AAG) levels on the pharmacokinetic interaction between imipramine and fluoxetine has been examined by utilizing a novel strain of transgenic mice which express serum AAG levels several times greater than normal. Before fluoxetine treatment, serum imipramine levels were approximately three times greater in transgenic mice than in control mice. Despite higher serum imipramine levels in transgenic mice, brain drug levels were lower than those found in control mice. Fluoxetine pre-treatment (20 mg kg(-1) for 5 days) resulted in an increase in serum imipramine levels in both groups of mice and the extent of the increase was greater in transgenic mice than in control mice (4.5-fold increase compared with 3.1-fold). Similarly, fluoxetine pre-treatment resulted in an increase in brain levels of imipramine in both groups of mice and the extent of the increase was greater in transgenic mice than in control mice (3.0-fold increase compared with 2.0-fold). Similar trends were observed for levels of desipramine in the serum and brain. Serum imipramine and desipramine levels did not correlate with their respective brain levels in the presence of elevated serum AAG levels before and after pre-treatment. These findings indicate that the extent of increases in imipramine and desipramine serum and brain levels are greater during elevated serum AAG states than during normal AAG states when imipramine is co-administered with fluoxetine.

BCRP at the Blood−Brain Barrier: Genomic Regulation by 17β-Estradiol

At the blood-brain barrier (BBB), the ABC transporter breast cancer resistance protein (BCRP) actively extrudes a variety of therapeutic drugs, including cytostatics, and diminishes their pharmacological efficacy in the brain. Consequently, new strategies to circumvent BCRP-mediated multidrug resistance in the CNS are required. One major approach to increase brain drug levels is to manipulate signaling mechanisms that control transporter expression and function. In the present study, we investigated the long-term effect of 17β-estradiol on BCRP in an ex vivo model of isolated rat brain capillaries. BCRP function and protein expression were decreased after 6 h of incubation with nanomolar concentrations of 17β-estradiol in capillaries from male and female rats. Concomitantly, levels of BCRP mRNA were also reduced by 17β-estradiol suggesting that the transporter is down-regulated via a genomic pathway. Additionally, we identified the presence of both estrogen receptor (ER) subtypes α and β at the rat BBB. Experiments using selective ER agonists and antagonists revealed that ER subtype β is responsible for the hormone-induced reduction of BCRP function and protein expression. These findings were confirmed by the use of ERKO mice. Blocking the proteasome-dependent degradation by lactacystin reversed the 17β-estradiol-mediated decrease of BCRP supposing that transcriptional down-regulation of the efflux transporter is paralleled by protein degradation. This study demonstrates that 17β-estradiol induces the down-regulation of BCRP on transcriptional and translational levels via the activation of ERβ in rat brain capillaries after 6 h. These results could help to improve brain targeting of BCRP substrates in the treatment of CNS diseases such as brain tumors and also contribute to an enlarged understanding of BCRP-drug interactions at a chronic intake of phytoestrogens and oral contraceptives.

Involvement of Vitamin D Receptor in the Intestinal Induction of Human ABCB1

ABCB1 (P-glycoprotein) is an efflux transporter that limits the cellular uptake levels of various drugs in intestine, brain, and other tissues. The expression of human ABCB1 has recently been reported to be under the control of nuclear receptor NR1I subfamily members, pregnane X receptor (PXR, NR1I2) and constitutive androstane receptor (CAR, NR1I3). Here, we have investigated the involvement of another NR1I member, vitamin D receptor (VDR, NR1I1), in ABCB1 expression. In the human colorectal adenocarcinoma cell line LS174T, which abundantly expresses VDR, both 1alpha,25-dihydroxyvitamin D(3) (1,25-VD3) and lithocholic acid (LCA) increased ABCB1 mRNA levels. Reporter gene assays in LS174T cells with constructs containing various lengths of the ABCB1 regulatory region revealed that the region containing multiple nuclear receptor binding motifs located at -7.8 kilobases [termed nuclear receptor-responsive module (NURREM)], to which PXR and CAR also bind, is essential for the VDR-mediated ABCB1 transactivation. Further reporter assays with constructs containing truncated NURREM and gel shift assays suggested simultaneous binding of multiple VDR/retinoid X receptor alpha heterodimers to NURREM. Furthermore, knockdown of VDR expression in LS174T cells blocked the LCA- and the 1,25-VD3-induced transcription of ABCB1 reporter genes. In human hepatoma HepG2 cells, in contrast with LS174T cells, 1,25-VD3 activated the ABCB1 transcription only in the presence of ectopically expressed VDR. These results suggest that the NR1I subfamily members regulate the ABCB1 expression sharing the binding sites within NURREM and that the physiologically produced LCA and 1,25-VD3 may modulate the ABCB1 expression in human intestines, possibly associated with interindividual variations of ABCB1 expression.

The Effect of Breast Cancer Resistance Protein and P-Glycoprotein on the Brain Penetration of Flavopiridol, Imatinib Mesylate (Gleevec), Prazosin, and 2-Methoxy-3-(4-(2-(5-methyl-2-phenyloxazol-4-yl)ethoxy)phenyl)propanoic Acid (PF-407288) in Mice

The role of breast cancer resistance protein (Bcrp) and the combined activities of Bcrp and P-glycoprotein (P-gp, Mdr1a/1b) in limiting the brain penetration of drugs at the blood-brain barrier (BBB) were investigated using wild-type FVB, Mdr1a/1b(-/-), (-/-), Bcrp(-/-), and Mdr1a/1b(-/-), (-/-)Bcrp(-/-) mice. Four drugs, flavopiridol, imatinib mesylate (Gleevec), PF-407288, and prazosin, with different transport specificity for BCRP/Bcrp and MDR1/Mdr1a were selected, and the drug levels in plasma, cerebrospinal fluid, and brain of mice were determined. Flavopiridol and prazosin were identified as substrates for both mouse Bcrp and Mdr1a with greater transport associated with Bcrp. The brain/plasma (B/P) ratios at 0.5 and 2 h in Mdr1a/1b(-/-), (-/-) and Bcrp(-/-) mice were 1- to 2-fold for both compounds, whereas the ratios in Mdr1a/1b(-/-), (-/-)Bcrp(-/-) mice were more than 5-fold of those observed in FVB mice. For imatinib, a better substrate of P-gp than Bcrp, the B/P ratios in Bcrp(-/-) were comparable to those in FVB mice, whereas the B/P ratios in Mdr1a/1b(-/-), (-/-) and Mdr1a/1b(-/-), (-/-)Bcrp(-/-) mice were more than 4- and 28-fold of those in FVB mice at both time points, respectively. Finally, the Bcrp-specific substrate PF-407288 exhibited comparable B/P ratios in Mdr1a/1b(-/-), (-/-) and Bcrp(-/-) mice and slightly but significantly increased B/P ratios in Mdr1a/1b(-/-), (-/-)Bcrp(-/-) mice compared with those in FVB mice. The B/P ratios of compounds in Mdr1a/1b(-/-), (-/-)Bcrp(-/-) mice compared with those in Mdr1a/1b(-/-), (-/-) mice clearly demonstrate that Bcrp impairs the brain penetration of its substrates. Moreover, P-gp and Bcrp at BBB function synergistically to limit the brain penetration of shared substrates.