Population Pharmacokinetic Modeling and Simulations to Evaluate a Potential Dose Regimen of Testosterone Undecanoate in Hypogonadal Males.

Intramuscular testosterone undecanoate is indicated as testosterone replacement in adult males with a deficiency in or absence of endogenous testosterone (hypogonadism). Intramuscular testosterone undecanoate 750 mg is approved to be administered at initiation and at 4 weeks, followed by a maintenance dose every 10 weeks. However, a more frequent maintenance regimen may improve symptom management of low testosterone at the end of each dosing interval. The current objective was to develop a population pharmacokinetic (PK) model for intramuscular testosterone undecanoate 750 mg and to perform PK simulations to assess the impact of an 8-week maintenance regimen on testosterone exposure. A 1-compartment model with first-order absorption and first-order elimination best described the PK of testosterone undecanoate. The model included time-dependent suppression and gradual recovery of endogenous testosterone production during testosterone undecanoate administration. Significant covariates included body weight and sex hormone-binding globulin level. With the final PK model, simulations were performed to evaluate the impact of an 8-week vs a 10-week maintenance regimen on testosterone exposure. The 8-week testosterone undecanoate regimen had a predicted 11% increase in average concentration and last observed concentration during a dosing interval before a subsequent dose and a 5% increase in maximum concentration. This translated into an ≈10% increase in the percentage of patients predicted to have a last observed concentration during a dosing interval before a subsequent dose >300 ng/dL, minimal change in the percentage of patients with average concentration in the normal range, and a low likelihood of maximum concentration >2500 ng/dL. These simulations suggest that more frequent administration of intramuscular testosterone undecanoate may be beneficial in some patients. Further clinical evaluation of an 8-week dose regimen is warranted.

Human Pharmacokinetics and Safety of Subcutaneous Collagenase Clostridium Histolyticum in Women.

BACKGROUND: Clostridium collagenase histolyticum (CCH) is being evaluated in women as a cellulite treatment. OBJECTIVE: To report preclinical safety and human pharmacokinetics (PK) and safety data for CCH. METHODS: Across 3 PK studies, 41 women received 12 subcutaneous injections per thigh/buttock in 1 session (up to 3.36 mg/dose). Blood samples were taken at baseline; at 5, 10, 20, and 30 minutes postdose; and at 1, 2, 4, 8, 12, 24, 48, 168, and 504 hours postdose. In a preclinical study, rats received 0, 0.029, 0.13, or 0.29 mg/dose of CCH intravenously (IV) every other day (QOD) for 16 days (total, 8 doses) and were evaluated for histopathologic changes. RESULTS: In human PK studies, no quantifiable plasma concentrations of AUX-I or AUX-II were observed postdose (n= 39 evaluable). Adverse events were injection site–related (bruising [97.6%], pain [87.8%], and edema/swelling [46.3%]). Antidrug antibodies were seen in most women at 504 hours postdose. In rats, plasma concentrations of AUX-I and AUX-II (CCH components) were measurable for 30 minutes and 1-2 hours, respectively, after IV administration. At ≥43× proposed human therapeutic dose on a mg/kg basis, rats experienced elevated liver enzyme levels, increased liver weights, and histologic changes that were mostly reversed during a 14-day recovery period. CONCLUSIONS: In human studies, no quantifiable circulating CCH levels were observed after a single subcutaneous dose of CCH up to 3.36 mg. Preclinical data indicated that repeat IV dosing (QOD; 8 doses) at ≥43× proposed human dose on a mg/kg basis for CCH was generally well tolerated.J Drugs Dermatol. 2020;19(9):852-856. doi:10.36849/JDD.2020.5048THIS ARTICLE HAD BEEN MADE AVAILABLE FREE OF CHARGE. PLEASE SCROLL DOWN TO ACCESS THE FULL TEXT OF THIS ARTICLE WITHOUT LOGGING IN. NO PURCHASE NECESSARY. PLEASE CONTACT THE PUBLISHER WITH ANY QUESTIONS.

Converting from Transdermal to Buccal Formulations of Buprenorphine: A Pharmacokinetic Meta-Model Simulation in Healthy Volunteers.

Objective: To develop a model to predict buprenorphine plasma concentrations during transition from transdermal to buccal administration. Design: Population pharmacokinetic model-based meta-analysis of published data. Methods: A model-based meta-analysis of available buprenorphine pharmacokinetic data in healthy adults, extracted as aggregate (mean) data from published literature, was performed to explore potential conversion from transdermal to buccal buprenorphine. The time course of mean buprenorphine plasma concentrations following application of transdermal patch or buccal film was digitized from available literature, and a meta-model was developed using specific pharmacokinetic parameters (e.g., absorption rate, apparent clearance, and volumes of distribution) derived from analysis of pharmacokinetic data for intravenously, transdermally, and buccally administered buprenorphine. Results: Data from six studies were included in this analysis. The final transdermal absorption model employed a zero-order input rate that was scaled to reflect a nominal patch delivery rate and time after patch application (with decline in rate over time). The transdermal absorption rate constant became zero following patch removal. Buccal absorption was a first-order process with a time lag and bioavailability term. Simulations of conversion from transdermal 20 mcg/h and 10 mcg/h to buccal administration suggest that transition can be made rapidly (beginning 12 hours after patch removal) using the recommended buccal formulation titration increments (75-150 mcg) and schedule (every four days) described in the product labeling. Conclusions: Computer modeling and simulations using a meta-model built from data extracted from publications suggest that rapid and straightforward conversion from transdermal to buccal buprenorphine is feasible.

EN3427: a novel cationic aminoindane with long-acting local anesthetic properties.

BACKGROUND: Currently approved local anesthetic drugs provide relatively brief local anesthesia that is appropriate and even desirable in some settings, but an extended duration of action beyond their capabilities would be a distinct benefit in other clinical situations. We implemented a drug discovery program that sought to identify novel local anesthetic molecules that specifically demonstrated a long-acting, preferential action on nociceptor sensory afferents that expressed transient receptor potential (TRP) channels. The hypothesis we tested was whether relatively membrane-impermeant local anesthetic molecules could confer long-lasting anesthesia if neuronal access was facilitated by TRP channel activation. The current work describes in vivo studies on a lead molecule that emerged from the discovery program, EN3427, in several rodent pain models. METHODS: Studies were performed on male Sprague-Dawley rats using 2 models of acute mechanical paw-pinch-evoked and pinprick-evoked nociceptive pain. Behavioral responses to noxious stimuli were assessed at baseline, that is, before any pharmacologic intervention, and at various timepoints after a single perisciatic or subcutaneous administration of either EN3427 alone or in combination with lidocaine. Paw withdrawal thresholds or cutaneous trunci reflexes were quantified, and pre-post drug values were compared statistically with analysis of variance followed by post hoc Dunnett multiple range test. RESULTS: A single perisciatic injection of lidocaine (2%) produced relief of paw-pinch-evoked pain that was significantly different from baseline through to the 1-hour timepoint (Dunnett multiplicity-adjusted P = 0.0081), as assessed using paw withdrawal or vocalization end points. EN3427 (0.2%), in the same model, produced a long-lasting block, with pain thresholds being significantly above baseline through to the 18-hour timepoint (Dunnett multiplicity-adjusted P = 0.0002); the combination of EN3427 (0.2%) plus lidocaine (2%) produced even longer lasting analgesia, with pain thresholds being significantly above baseline through to the 24-hour timepoint (Dunnett multiplicity-adjusted P = 0.0073). Similar results were obtained with use of the pinprick approach. A single subcutaneous injection of lidocaine (2%) produced complete loss of sensation to cutaneous pinprick through 0.5 hours, but sensitivity thresholds were no different to baseline by the 1-hour timepoint, a similar injection of EN3427 alone (0.2%) produced a loss of sensation that was significantly different from baseline through the 8-hour timepoint (Dunnett multiplicity-adjusted P = 0.0045), and the combination of lidocaine (2%) plus EN3427 (0.2%) appeared to further enhance duration of analgesia, although this was significantly different from baseline only through the 10-hour timepoint (Dunnett multiplicity-adjusted P = 0.0048). Analgesic efficacy was dose related; using the combined injection approach, we found that increases in the dose of EN3427 with a fixed 2% lidocaine led to substantially extended analgesia and increasing doses of lidocaine combined with a fixed dose of EN3427 (0.2%) led to only modestly increased duration of action. CONCLUSIONS: The present studies demonstrate that a new molecular entity, EN3427, produces effective and long-lasting analgesia in 2 rodent pain models. The analgesic effects of EN3427 are significantly longer-lasting than lidocaine and are further extended when EN3427 is combined with lidocaine. The results are discussed with respect to a possible lidocaine-mediated TRP channel activation and facilitated neuronal access of EN3427, with subsequent entrapment conferring extended-duration efficacy.

Using wastewater and high-rate algal ponds for nutrient removal and the production of bioenergy and biofuels.

This paper projects a positive outcome for large-scale algal biofuel and energy production when wastewater treatment is the primary goal. Such a view arises partly from a recent change in emphasis in wastewater treatment technology, from simply oxidising the organic matter in the waste (i.e. removing the biological oxygen demand) to removing the nutrients - specifically nitrogen and phosphorus - which are the root cause of eutrophication of inland waterways and coastal zones. A growing need for nutrient removal greatly improves the prospects for using new algal ponds in wastewater treatment, since microalgae are particularly efficient in capturing and removing such nutrients. Using a spreadsheet model, four scenarios combining algae biomass production with the making of biodiesel, biogas and other products were assessed for two of Australia's largest wastewater treatment plants. The results showed that super critical water reactors and anaerobic digesters could be attractive pathway options, the latter providing significant savings in greenhouse gas emissions. Combining anaerobic digestion with oil extraction and the internal economies derived from cheap land and recycling of water and nutrients on-site could allow algal oil to be produced for less than US$1 per litre.

T-type calcium channel blockers: spiro-piperidine azetidines and azetidinones-optimization, design and synthesis.

A series of spiro-azetidines and azetidinones has been evaluated as novel blockers of the T-type calcium channel (Ca(V)3.2) which is a new therapeutic target for the potential treatment of both inflammatory and neuropathic pain. Confirmation and optimization of the potency, selectivity and DMPK properties of leads will be described.

Protein binding-dependent decreases in hERG channel blocker potency assessed by whole-cell voltage clamp in serum.

In vitro hERG blocking potency is measured in drug discovery as part of an integrated cardiovascular risk assessment. Typically, the concentrations producing 50% inhibition are measured in protein-free saline solutions and compared with calculated free therapeutic in vivo Cmax values to estimate a hERG safety multiple. The free/unbound fraction is believed responsible for activity. We tested the validity of this approach with 12 compounds by determining potencies in voltage clamp studies conducted in the absence and presence of 100% dialyzed fetal bovine serum (FBS). Bath drug concentrations in saline solutions were measured to account for loss of compounds due to solubility, stability, and/or adsorption. Protein binding in dialyzed FBS was measured to enable predictions of serum IC50s based on the unbound fraction and the saline IC50. For 11 of 12 compounds, the measured potency in the presence of dialyzed FBS was within 2-fold of the predicted potency. The predicted IC50 in dialyzed FBS for one highly bound compound, amiodarone, was 9-fold higher than the measured serum IC50. These data suggest that for highly bound compounds, direct measurement of IC50s in the presence of 100% serum may provide a more accurate estimate of in vivo potencies than the approach based on calculated serum shifts.

Tetrahydroquinoline sulfonamides as vasopressin 1b receptor antagonists.

Vasopressin 1b (V1b) antagonists have been postulated as possible treatments for depression and anxiety. A novel series of potent and selective V1b antagonists has been identified starting from an in-house screen hit. The incorporation of a sulfonamide linker between a tetrahydroisoquinoline core and amino piperidine lead to the identification of a V1b antagonist with similar affinity for human and rat receptors. Further optimization of the right hand portion afforded potent V1b antagonists that possessed moderate to high selectivity over other receptors.

Structural determinants for histamine H(1) affinity, hERG affinity and QTc prolongation in a series of terfenadine analogs.

In the late 1980's reports linking the non-sedating antihistamines terfenadine and astemizole with torsades de pointes, a form of ventricular tachyarrhythmia that can degenerate into ventricular fibrillation and sudden death, appeared in the clinical literature. A substantial body of evidence demonstrates that the arrhythmogenic effect of these cardiotoxic antihistamines, as well as a number of structurally related compounds, results from prolongation of the QT interval due to suppression of specific delayed rectifier ventricular K+ currents via blockade of the hERG-IKr channel. In order to better understand the structural requirements for hERG and H(1) binding for terfenadine, a series of analogs of terfenadine has been prepared and studied in both in vitro and in vivo hERG and H(1) assays.

Predicting therapeutic efficacy - experimental pain in human subjects.

The pharmaceutical industry faces tough times. Despite tremendous advances in the science and technology of new lead identification and optimization, attrition rates for novel drug candidates making it into the clinic remain unacceptably high. A seamless boundary between basic preclinical and clinical arms of the discovery process, embodying the concept of 'translational research' is viewed by many as the way forward. The rational application of human experimental pain models in early clinical development is reviewed. Capsaicin, UV-irradiation and electrical stimulation methods have each been used to establish experimental hyperalgesia in Phase-I human volunteers and the application of these approaches is discussed in the context of several pharmacological examples. However, data generated from such studies must be integrated into a well-conceived and executed series of Phase-II efficacy trials in patients in order to derive maximal benefit. The challenges involved in optimal Phase-II/III trial design are reviewed with specific attention to the issues of sample size and placebo response. Finally, the application and potential of cortical EEG studies are discussed as an objective alternative to more conventional pain assessment tools with specific examples of how this technique has been applied to the study of NSAID and opiate-based therapeutics.

The antipsychotic drug, fluphenazine, effectively reverses mechanical allodynia in rat models of neuropathic pain.

RATIONALE: Fluphenazine is a potent antipsychotic drug used to treat schizophrenia and other psychotic symptoms. Its clinical benefit is mainly mediated by the antagonism of dopamine D2 receptors. We have recently discovered, however, that fluphenazine is also a potent sodium channel blocker, a property that may offer additional therapeutical indications, including analgesia. OBJECTIVES: The present study sought to determine the analgesic effect of fluphenazine on neuropathic pain in animal models. METHODS: The effect of fluphenazine on mechanical allodynia was assessed in three animal neuropathic pain models, including spinal nerve ligation, chronic constriction nerve injury (CCI), and sural-spared sciatic nerve injury models. RESULTS: Systemic fluphenazine effectively attenuated mechanical allodynia in all three rat neuropathic pain models at doses (0.03-0.3 mg/kg) that approximate those used in rodent models of psychosis. In parallel with its in vivo antiallodynic effect, fluphenazine (3-30 microM) effectively suppressed the ectopic discharges in injured afferent fibers without affecting the propagation of action potentials evoked by electrical nerve stimulation in an ex vivo dorsal root ganglia (DRG)-nerve preparation excised from CCI rats. Furthermore, similar concentrations of fluphenazine significantly blocked sodium channels in DRG neurons. CONCLUSIONS: The inhibitory action of fluphenazine on ectopic afferent discharges may be due to its ability to block voltage-gated sodium channels, and this may also provide a mechanistic basis for the drug's antiallodynic effect in animal models of neuropathic pain. In summary, our study demonstrates that the classic antipsychotic drug fluphenazine has antiallodynic properties in multiple rodent models of nerve injury-induced neuropathic pain.

Novel steroidal saponins, Sch 725737 and Sch 725739, from a marine starfish, Novodinia antillensis.

Bioassay-guided fractionation of an active fraction from an extract of a marine starfish, Novodinia antillensis, led to the isolation and identification of two new saponins, Sch 725737 (1) and Sch 725739 (2). Compound 1 was identified as the NaV1.8 inhibitor with IC(50) of approximately 9 microM. The purification and the structure elucidation of these two saponins are described.

The neuroleptic drug, fluphenazine, blocks neuronal voltage-gated sodium channels.

Fluphenazine (Prolixin(R)) is a potent phenothiazine-based dopamine receptor antagonist, first introduced into clinical practice in the late 1950s as a novel antipsychotic. The drug emerged as a 'hit' during a routine ion channel screening assay, the present studies describe our electrophysiological examination of fluphenazine at tetrodotoxin-sensitive (TTX-S) and resistant (TTX-R) voltage-gated sodium channel variants expressed in three different cell populations. Constitutively expressed TTX-S conductances were studied in ND7/23 cells (a dorsal root ganglion-derived clonal cell line) and rat primary cerebrocortical neurons. Recombinant rat Na(V)1.8 currents were studied using ND7/23 cells as a host line for heterologous expression. Sodium currents were examined using standard whole-cell voltage-clamp electrophysiology. Current-voltage relationships for either ND7/23 cell or Na(V)1.8 currents revealed a prominent fluphenazine block of sodium channel activity. Steady-state inactivation curves were shifted by approximately 10 mV in the hyperpolarizing direction by fluphenazine (3 microM for ND7/23 currents and 10 microM for Na(V)1.8), suggesting that the drug stabilizes the inactivated channel state. Fluphenazine's apparent potency for blocking either ND7/23 or Na(V)1.8 sodium channels was increased by membrane depolarization, corresponding IC(50) values for the ND7/23 cell conductances were 18 microM and 960 nM at holding potentials of -120 mV and -50 mV, respectively. Frequency-dependent channel block was evident for each of the cell/channel variants, again suggesting a preferential binding to inactivated channel state(s). These experiments show fluphenazine to be capable of blocking neuronal sodium channels. Several unusual pharmacokinetic features of this drug suggest that sodium channel block may contribute to the overall clinical profile of this classical neuroleptic agent.

Discovery and characterization of vicriviroc (SCH 417690), a CCR5 antagonist with potent activity against human immunodeficiency virus type 1.

Inhibiting human immunodeficiency virus type 1 (HIV-1) infection by blocking the host cell coreceptors CCR5 and CXCR4 is an emerging strategy for antiretroviral therapy. Currently, several novel coreceptor inhibitors are being developed in the clinic, and early results have proven promising. In this report, we describe a novel CCR5 antagonist, vicriviroc (formerly SCH-D or SCH 417690), with improved antiviral activity and pharmacokinetic properties compared to those of SCH-C, a previously described CCR5 antagonist. Like SCH-C, vicriviroc binds specifically to the CCR5 receptor and prevents infection of target cells by CCR5-tropic HIV-1 isolates. In antiviral assays, vicriviroc showed potent, broad-spectrum activity against genetically diverse and drug-resistant HIV-1 isolates and was consistently more active than SCH-C in inhibiting viral replication. This compound demonstrated synergistic anti-HIV activity in combination with drugs from all other classes of approved antiretrovirals. Competition binding assays revealed that vicriviroc binds with higher affinity to CCR5 than SCH-C. Functional assays, including inhibition of calcium flux, guanosine 5'-[35S]triphosphate exchange, and chemotaxis, confirmed that vicriviroc acts as a receptor antagonist by inhibiting signaling of CCR5 by chemokines. Finally, vicriviroc demonstrated diminished affinity for the human ether a-go-go related gene transcript ion channel compared to SCH-C, suggesting a reduced potential for cardiac effects. Vicriviroc represents a promising new candidate for the treatment of HIV-1 infection.

Regulation of two rat mas-related genes in a model of neuropathic pain.

The mas-related gene (Mrg) family is a large family of G-protein-coupled receptors which are variable in number depending on species. The so-called sensory-neuron-specific receptors (SNSRs) make up a subset of the Mrg family, and several of these have been implicated in nociceptive processes. To verify their specific localization in sensory ganglia, we have determined the expression patterns of two of them, rMrgA and rMrgC, in a panel of rat tissues. The quantitative PCR results in the rat tissue panel indicate that, while several non-neuronal tissues contain significant levels of mRNA for both receptors, these two receptors are most highly expressed in dorsal root ganglia and trigeminal ganglia. Given this, we have examined the effects of spinal nerve ligation (SNL) on the expression of these genes. Peripheral neuropathy induced by ligation of spinal nerves at L5 and L6 resulted in a pronounced mechanical allodynia. These behavioral changes in tactile sensitivity were accompanied by significant decreases (10- to 100-fold) in the mRNA expression of both rMrgA and rMrgC exclusively in the L5 and L6 dorsal root ganglia ipsilateral to the SNL. In situ hybridization studies demonstrated that this decrease did not result from neuronal loss but rather from a reduction in the hybridization signals for rMrgC over small-to-medium diameter L5 and L6 dorsal root ganglia neurons. While the functional implications of the altered regulation of rMrgA and rMrgC in neuropathic pain models remain unclear, the results suggest that therapeutics targeting these receptors may have limited utility.

Characterization of a hERG screen using the IonWorks HT: comparison to a hERG rubidium efflux screen.

The introduction of parallel patch clamp instruments offers the promise of moderate-throughput, high-fidelity voltage clamp for drug screening assays. One such device, the IonWorks HT (Molecular Devices, Sunnyvale, CA), was evaluated and compared to conventional human ethera- go-go-related gene (hERG) patch clamp data and an alternative functional screen based on rubidium flux. Data generated by the IonWorks HT and rubidium assays were compared to determine if either offered superior predictive value compared to conventional patch clamp. Concentration-effect curves for a panel of known hERG blockers were shifted to higher concentrations on the IonWorks HT compared to conventional voltage clamp determinations. The magnitude of the potency shifts was compound-specific and ranged from no shift (e.g., quinidine) to over 200-fold (astemizole). When the extreme value for astemizole was disregarded, the potency shift for 13 other known reference standards was 12-fold or less, with an average shift of fivefold. The same subset of compounds in the rubidium efflux assay exhibited an average potency shift of 12-fold. To provide a simulation of how the IonWorks HT assay might perform in a single concentration screening mode, a panel of test compounds was evaluated. The IonWorks HT screen did not outperform the rubidium efflux screen in predicting conventional voltage clamp measurements. The most likely explanation appears to rest with variable and compound-specific potency shifts in the IonWorks HT assay. The variable potency shifts make it difficult to select a screening concentration that meets the criterion of a high positive predictive value while avoiding false-positives.

Electrophysiological analysis of tetrodotoxin-resistant sodium channel pharmacology.

This unit describes essential procedures to record the activity of and the effects of pharmacological manipulation upon tetrodotoxin-resistant (TTXr) sodium channels. Readers are guided through the process of assembling a functional |patch-clamp| electrophysiology apparatus and construction of software-controlled voltage protocols that address various aspects of channel gating. Guidelines are also presented for analysis and display of the data typically generated by these experiments. For investigators wishing to study native channels in their appropriate cellular environment, protocols describing the isolation of viable cells from the main tissues that commonly express TTXr channels are also included.

Vinpocetine is a potent blocker of rat NaV1.8 tetrodotoxin-resistant sodium channels.

Vinpocetine is a clinically used synthetic vincamine derivative with a diverse pharmacological profile that includes action at several ion channels, principally "generic" populations of sodium channels that give rise to tetrodotoxin-sensitive conductances. A number of cell types are known to express tetrodotoxin-resistant (TTXr) sodium conductances, the molecular bases of which have remained elusive until recently. One such TTXr channel, termed NaV1.8, is of particular interest because of its prominent and selective expression in peripheral afferent nerves. The effects of vinpocetine on TTXr channels specifically, are unknown. We have assessed the effects of the drug on cloned rat NaV1.8 channels expressed in a dorsal root ganglion-derived cell line, ND7/23. Vinpocetine produced a concentration- and state-dependent inhibition of NaV1.8 sodium channel activity. Voltage-clamp experiments revealed an approximately 3-fold increase in vinpocetine potency when whole-cell NaV1.8 conductances were elicited from relatively depolarized potentials (-35 mV; IC50 = 3.5 microM) compared with hyperpolarized holding potentials (-90 mV; IC50 = 10.4 microM). Vinpocetine also produced an approximately 22 mV leftward shift in the voltage dependence of NaV1.8 channel inactivation but did not affect the voltage range of channel activation. These properties are reminiscent of several other known sodium channel blockers and suggested that vinpocetine may exhibit frequency-dependent block. Accordingly, tonic block of NaV1.8 channels by vinpocetine (3 microM) increased proportionally with increasing depolarizing commands over the frequency range 0.1 to 1Hz. In summary, the present data demonstrate that vinpocetine is capable of blocking NaV1.8 sodium channel activity and suggest a potential additional utility in various sensory abnormalities arising from abnormal peripheral nerve activity.

Activation of spinal ORL-1 receptors prevents acute cutaneous neurogenic inflammation: role of nociceptin-induced suppression of primary afferent depolarization.

Neurogenic inflammation is an inflammatory response of peripheral tissue to vasoactive substances released from sensory afferent terminals. It can be triggered via a local axon reflex and by dorsal root reflex (DRR) activity involving the spinal cord. Nociceptin, an endogenous ligand for the opioid receptor-like (ORL-1) G-protein coupled receptor, has been found to inhibit the local axon reflex-mediated neurogenic inflammation by suppressing the release of vasoactive neuropeptides from sensory afferent terminals. The present study was to explore the role of spinal ORL-1 receptors in the modulation of DRR-induced neurogenic inflammation. We first examined the effect of nociceptin on DRR by recording dorsal root potentials (DRPs) and the associated antidromic discharges, evoked by electrical stimulation of an adjacent dorsal root in an in vitro neonatal rat spinal cord preparation. Nociceptin reversibly inhibited the DRP in a concentration-dependent manner (IC50: approximately 45 nM, maximal inhibition: approximately 50%), an effect that was antagonized by the ORL-1 receptor antagonist, J-113397. Neurochemical studies demonstrated that nociceptin (10 microM) also produced an approximately 40% reduction in gamma amino butyric acid (GABA) release evoked by electrical stimulation of neonatal rat spinal cord slices. On the other hand, nociceptin had no effect on exogenous GABA-evoked DRP. These findings suggest that the nociceptin-induced inhibition of the DRP is most likely due to the suppression of GABA release, the principle transmitter mediating DRP, from GABAergic neurons that are pre-synaptic to primary afferent terminals. Finally, in order to explore the physiological significance of such modulation in a fully integrated system, we evaluated the effect of intrathecally administered nociceptin on capsaicin-induced acute cutaneous neurogenic inflammation in rat hind paw, quantified by examining the degree of paw edema in anesthetized rats. The magnitude of capsaicin-induced increase of paw thickness was reduced by approximately 50% from 31+/-1.34% (n=6) to 15+/-1.63% (n=8; P<0.05) by nociceptin (10 micromol). We conclude that spinal ORL-1 receptors can modulate neurogenic inflammation by suppressing the GABAergic neuronal activity in the dorsal horn that is responsible for generating DRRs.

The identification of intestinal scavenger receptor class B, type I (SR-BI) by expression cloning and its role in cholesterol absorption.

The molecular mechanisms of cholesterol absorption in the intestine are poorly understood. With the goal of defining candidate genes involved in these processes a fluorescence-activated cell sorter-based, retroviral-mediated expression cloning strategy has been devised. SCH354909, a fluorescent derivative of ezetimibe, a compound which blocks intestinal cholesterol absorption but whose mechanism of action is unknown, was synthesized and shown to block intestinal cholesterol absorption in rats. Pools of cDNAs prepared from rat intestinal cells enriched in enterocytes were introduced into BW5147 cells and screened for SCH354909 binding. Several independent clones were isolated and all found to encode the scavenger receptor class B, type I (SR-BI), a protein suggested by others to play a role in cholesterol absorption. SCH354909 bound to Chinese hamster ovary (CHO) cells expressing SR-BI in specific and saturable fashion and with high affinity (K(d) approximately 18 nM). Overexpression of SR-BI in CHO cells resulted in increased cholesterol uptake that was blocked by micromolar concentrations of ezetimibe. Analysis of rat intestinal sections by in situ hybridization demonstrated that SR-BI expression was restricted to enterocytes. Cholesterol absorption was determined in SR-B1 knockout mice using both an acute, 2-h, assay and a more chronic fecal dual isotope ratio method. The level of intestinal cholesterol uptake and absorption was similar to that seen in wild-type mice. When assayed in the SR-B1 knockout mice, the dose of ezetimibe required to inhibit hepatic cholesterol accumulation induced by a cholesterol-containing 'western' diet was similar to wild-type mice. Thus, the binding of ezetimibe to cells expressing SR-B1 and the functional blockade of SR-B1-mediated cholesterol absorption in vitro suggest that SR-B1 plays a role in intestinal cholesterol metabolism and the inhibitory activity of ezetimibe. In contrast studies with SR-B1 knockout mice suggest that SR-B1 is not essential for intestinal cholesterol absorption or the activity of ezetimibe.