The "induced hyperactivity" test for the de-risking of potential off-target activity of antihypertensive drugs.

INTRODUCTION: Compound X is a new proprietary antihypertensive agent that induces its pharmacodynamic effect at an approximate plasma Cmax.u of 0.6nmol/L (rat hypertension model). However, Compound X also shows potent off-target activity at PDE-10a (IC50~12nmol/L). Since PDE-10a is expressed predominantly in brain (striatum) and inhibition/knockout of PDE-10a have been reported to result in anti-psychotic effects, we have established the "induced hyperactivity" test for CNS de-risking of Compound X. METHODS: Male Wistar rats treated orally with vehicle or Compound X (single dose; 1-3-10mg/kg) were assessed for exploratory locomotor activity following induction of hyperactivity by d-amphetamine (2mg/kg) or the NMDA antagonist MK-801 (0.2mg/kg). The assay was validated with anti-psychotic drugs (haloperidol, clozapine). RESULTS: Induced hyperactivity was not antagonized by Compound X at doses relevant for its primary pharmacodynamic activity (0.1-0.3mg/kg, rat). Although sufficient plasma concentrations were reached with Compound X (Cmax.u up to ~8nmol/L at 10mg/kg) to show its PDE-10a activity, its low brain penetration (~10%) likely precluded any meaningful PDE-10a inhibition. In comparison, other blood pressure lowering agents such as prazosin (alpha-1 adrenoceptor antagonist) and isradipine (L-Type Ca(2+) channel blocker), but not the NO-donor ISDN, tended to attenuate induced hyperactivity in rats at high doses. CONCLUSION: The relevance of a potent in-vitro off-target hit (PDE-10a inhibition) by Compound X was attenuated by a robust in-vivo assay (rat induced hyperactivity test), hence lowering the potential liability profile of Compound X. Finally, this piece of investigative safety pharmacology work enabled early de-risking of Compound X based on its primary pharmacodynamic activity in a relevant rat model.

Abuse liability assessment in preclinical drug development: predictivity of a translational approach for abuse liability testing using methylphenidate in four standardized preclinical study models.

OBJECTIVES: Preclinical abuse liability assessment of novel clinical CNS-active candidates involves several tests, addressing different aspects characteristic for abuse potential, which are considered predictive for substance abuse of these candidates, thus ensuring an appropriate translational approach. To demonstrate how such a strategy could work, a known drug of abuse, methylphenidate was evaluated in a full rodent test battery, comprising four test models, and in accordance with the requirements of the FDA, ICH and EMA guidelines. METHODS: Methylphenidate was tested orally at 2.5, 5 or 10mg/kg for its physical dependence potential in a repeated dose non-precipitated withdrawal test, for its drug profiling in a drug discrimination learning procedure (single escalating doses), and for its reinforcing properties in a conditioned place preference test (alternate dosing days) and an intravenous self-administration procedure (0.05 to 1mg/kg/IV infusion during 5 daily 1-h test sessions). The stimulant d-amphetamine served as positive control and was administered subcutaneously at 0.8mg/kg in the first three test models. In the intravenous self-administration procedure rats were habituated to intravenously self-administer d-amphetamine at 0.06mg/kg/IV infusion prior to methylphenidate substitution. RESULTS: Cessation of subchronic dosing up to 10mg/kg methylphenidate led to sustained or even exacerbated effects on locomotion and behavior, body temperature, body weight, food consumption, and alteration of the diurnal rhythm during withdrawal. Clear generalization to d-amphetamine was obtained in the drug discrimination test at 5 and 10mg/kg. Distinct reinforcing properties were present in the conditioned place preference test at 10mg/kg and in the intravenous self-administration study from 0.05mg/kg/IV infusion onwards. The maximum plasma exposure after oral administration of methylphenidate over the dose ranges tested in the present rat studies covered at least 1.9-fold to 18.9-fold the recommended human therapeutic exposure of 10ng/ml, a plasma level that is considered representative of the human efficacious methylphenidate dose. The ratio Cmax Hu/rat calculated from the intravenous self-administration data ranged from 14.9 to 576.5. Consequently the regulatory requirements, stating that preclinical drug abuse liability studies should include high doses that produce plasma levels that are multiples of the therapeutic dose were fulfilled (FDA, EMA, ICH). DISCUSSION: The presented preclinical models, implemented within a drug development environment, were considered highly predictive to assess the abuse potential of methylphenidate, and in accordance with the regulatory requirements of drug licensing authorities in terms of appropriate methods, dose selection and subsequent plasma exposure.

Combination effects of amphetamines under hyperthermia - the role played by oxidative stress.

Rise in body temperature is a life-threatening consequence of 3,4-methylenedioxymethamphetamine (MDMA, ecstasy) abuse. We evaluated the impact of hyperthermia on the cytotoxicity of combinations of MDMA and three other amphetamines, often co-ingested. For this, Hep G2 cells were exposed to MDMA, d-amphetamine, methamphetamine and 4-methylthioamphetamine, individually or combined, at 40.5 °C. The results were compared with normothermia data (37.0 °C). Mixture additivity expectations were calculated by independent action and concentration addition (CA) models. To delineate the mechanism(s) underlying the elicited effects, a range of stress endpoints was evaluated, including quantification of reactive oxygen/nitrogen species (ROS/RNS), lipid peroxidation, reduced/oxidized glutathione (GSH/GSSG), ATP and mitochondrial membrane potential (Δψm) changes. Our data show that, in hyperthermia, amphetamines acted additively and mixture effects were accurately predicted by CA. At 40.5 °C, even slight increases in the concentrations of each drug/mixture promoted significant rises in cytotoxicity, which quickly shifted from roughly undetectable to maximal mortality. Additionally, the increase of RNS/ROS production, decrease of GSH, ATP depletion and mitochondrial impairment were exacerbated under hyperthermia. Importantly, when equieffective cytotoxic concentrations of the mixture and individual amphetamines were compared for all tested stress endpoints, mixture effects did not deviate from those elicited by individual treatments, suggesting that these amphetamines have a similar mode of action, which is not altered in combination. Concluding, our data indicate that amphetamine mixtures produce deleterious effects, even when individual drugs are combined at negligible concentrations. These effects are strongly exacerbated in hyperthermia, emphasizing the potential increased risks of ecstasy intake, especially when hyperthermia occurs concurrently with polydrug abuse.

The neurotensin-1 receptor agonist PD149163 inhibits conditioned avoidance responding without producing catalepsy in rats.

Agonists for neurotensin (NT)-1 receptors have produced antipsychotic-like effects in many animals, including reversal of prepulse inhibition deficits and psychostimulant-induced increases in spontaneous activity. The present study sought to provide a basic assessment of the putative antipsychotic effects of PD149163 in rats using a two way conditioned avoidance response task, which is highly validated for screening antipsychotic drugs, and an inclined grid assessment, which is used to assess extrapyramidal side effect liability. PD149163 (0.0625-8.0 mg/kg) significantly suppressed conditioned avoidance responding (CAR) following administration of a 1.0 or 8.0 mg/kg dose. PD149163 failed to significantly increase catalepsy scores. The typical antipsychotic drug haloperidol (0.01-1.0 mg/kg) significantly suppressed CAR at a 0.1, 0.3, and 1.0 mg/kg dose, and a significant increase in catalepsy scores was found at the 1.0 mg/kg dose. The atypical antipsychotic drug clozapine (2.5-10.0 mg/kg) also produced a significant inhibition of CAR, which occurred following administration of a 10.0 mg/kg dose. Clozapine failed to significantly increase catalepsy scores. Finally, D-amphetamine (1.0 mg/kg), serving as a negative control, failed to suppress CAR or increase catalepsy scores. These data further suggest that PD149163 may have atypical antipsychotic-like properties.

Neurochemical changes and neurotoxic effects of an acute treatment with sydnocarb, a novel psychostimulant: comparison with D-amphetamine.

Sydnocarb [(phenylisopropyl)N-phenylcarbamoylsydnonimine; SYD] was introduced to clinical practice in Russia as a psychostimulant drug used for the treatment of asthenia and apathy, which accompany schizophrenia and manic depression. It has been described as a psychostimulant with addiction liability and toxicity less than amphetamine (AMPH). The precise cellular mechanisms by which sydnocarb elicits its psychostimulant effect are still unclear. At present its neurochemical and neurotoxic effects are compared to those of AMPH in the striatum, the main input structure of the basal ganglia. The expression of c-fos protein in striatal neurons was much more increased after a single injection of D-AMPH (5 mg/kg) than after an equimolar concentration of SYD (23.8 mg/kg) in both the anterior and the posterior part of the striatum. Using in situ hybridization on striatal slices, we observed that AMPH increased the striatal levels of preprodynorphin (PPDYN) mRNAs in both parts of the striatum, while SYD did not affect basal levels of PPDYN mRNAs. Furthermore, AMPH and SYD increased striatal preprotachykinin (PPT-A) and preproenkephalin (PPE) mRNA levels. The effects of AMPH and SYD on PPT-A-mRNA levels were similar. A differential effect of AMPH and SYD was observed only on the PPE-mRNA levels measured in the anterior striatum where SYD increased these levels more than AMPH. The acute neurotoxicity of these two psychostimulants was analyzed by measuring their effects on the parameters of oxidative stress, such as nitric oxide (NO) generation, as well as specific indices of lipid peroxidation (i.e., thiobarbituric acid reactive substances; TBARS), while, on the other hand, the alpha-tocopherol level was taken as an index of antioxidant defense processes. Measuring generation of NO directly by electron paramagnetic resonance, it was observed that AMPH shows a more pronounced increase in comparison to SYD, in the striatum and in cortex. TBARS levels in the striatum and cortex were significantly less enhanced than AMPH after a single injection of SYD. Similarly, the alpha-tocopherol level was decreased only by AMPH in the striatum, and neither AMPH nor SYD had any effect in the cortex. Results show that a single injection of a high dose of AMPH is able to induce several neurotoxic effects. The study also demonstrates that SYD has mild neurochemical effects as well as fewer neurotoxic properties than AMPH.

L-ephedrine-induced neurodegeneration in the parietal cortex and thalamus of the rat is dependent on hyperthermia and can be altered by the process of in vivo brain microdialysis.

Multiple doses of the dietary supplement L-ephedrine can cause severe hyperthermia and modest dopamine depletions in the rat brain. Since D-amphetamine treatment can result in neurodegeneration, the potential of L-ephedrine to produce similar types of degeneration was investigated. Adult male rats, some implanted in the caudate/putamen (CPu) for microdialysis, were given four doses of 25 mg/kg L-ephedrine or 5 mg/kg D-amphetamine (2 h between doses) at an ambient temperature of 23 degrees C. L-ephedrine-induced degeneration in the forebrain was dependent on the degree of hyperthermia. Layer IV of the parietal cortex was the most sensitive to L-ephedrine treatment with peak body temperatures of at most 40.0 degrees C necessary to produce degeneration. Extensive neurodegeneration in the parietal cortex after L-ephedrine treatment was as pronounced as that previously described for D-amphetamine treatment and also occurred in the intralaminar, ventromedial and ventrolateral thalamic nuclei in rats with severe hyperthermia (peak body temperatures>41.0 degrees C). The neurodegeneration induced by L-ephedrine may have resulted in part from excitotoxic mechanisms involving the indirect pathways of the basal ganglia and related areas. No differences were observed between microdialysis and non-implanted rats with respect to degree of tyrosine hydroxylase (TH) loss in the CPu after either D-amphetamine or L-ephedrine treatment. However, neurodegeneration resulting from D-amphetamine and L-ephedrine was reduced in the microdialysis animals in the hemisphere ipsilateral to the probe, which raises concerns when using the technique of in vivo microdialysis to evaluate neurodegeneration. The results of this study, in conjunction with human clinical evaluation of ephedrine neurotoxicity, indicate that regionally specific damage may occur in the cortex of some humans exposed to ephedrine in the absence of stroke or hemorrhage.

Neurotoxic effects of amphetamine plus L-DOPA.

1. Male Swiss Webster mice were administered a series of amphetamine injections preceded by either saline or L-DOPA. 2. This injection regimen was performed for either one, two or three consecutive weeks and neurotoxic effects of the drugs were determined one week later. 3. Amphetamine treatment for two weeks produced a greater striata-dopaminergic lesion that treatment for only one week. Three weeks of treatment did not exacerbate the lesion, indicating that the damage had reached maximal levels. 4. L-DOPA pretreatment did not significantly alter any of the toxic effects of the amphetamine. Therefore, some dopaminergic neurons may be resistant to the toxic effects of amphetamine.

d-Amphetamine as a behavioral teratogen: effects depend on dose, sex, age and task.

Reports on the behavioral effects of prenatal exposure to d-amphetamine in rodents are inconsistent. Activity levels have been variously reported to increase, decrease, or show no change (as in the Collaborative Study) following such exposure. As a follow-up to the Collaborative Behavioral Teratology Study, 3 experiments have been conducted at the NCTR to examine the behavioral teratogenicity of this compound following SC dosing on days 12-15 of gestation. A higher dosage (3 mg/kg) was included and evaluations involved tasks used in the Collaborative Behavioral Teratology Study (startle, figure-8 activity) and other tasks not previously undertaken at the NCTR (short-term reactivity to novel open fields, intake of sweetened solutions). Activity measures gave especially mixed results. There was no effect of prenatal exposure, even at 3 mg/kg, upon longer-term activity, before or after amphetamine challenge, in figure-8 mazes or rectangular photocell chambers, at postnatal days (PND) 47 or 120. In one experiment, changes in reactivity to brief exposure to an open field daily over 3 days were seen in higher dosage PND 135 males but not females, while higher dosage females but not males showed lowered emergence latencies at this age. In a second experiment, no exposure-related changes were seen in reactivity to an open field in offspring of either sex at PND 47 or 70. Auditory startle amplitude showed complex dose effects in these two experiments. Females exposed to 3 mg/kg had elevated startle amplitude at PNDs 47 and 120, but not at PND 19. Males in the 3 mg/kg group had elevated startle at PND 19, but not thereafter.(ABSTRACT TRUNCATED AT 250 WORDS)

Involvement of adrenergic receptor mechanisms within hypothalamus in the fever induced by amphetamine and thyrotropin-releasing hormone in the rat.

The mechanisms underlying the thermal effects induced by intrahypothalamic administration of either d-amphetamine or thyrotropin-releasing hormone (TRH) has been investigated in conscious rats. Direct administration of d-amphetamine (1-10 micrograms in 1 microliter) or TRH (1-4 micrograms in 1 microliter) into the preoptic anterior hypothalamus caused hyperthermia or fever at the ambient temperature (Ta: 8, 22 and 30 degrees C) studied. The fever induced by d-amphetamine or TRH was due to increased metabolic heat production at Ta 8 degrees C, while at Ta 30 degrees C the fever was due to cutaneous vasoconstriction in the rat. At Ta 22 degrees C, the fever was due to both increased metabolism and cutaneous vasoconstriction. Furthermore, the fever induced by intrahypothalamic administration of TRH was greatly reduced by pretreatment with intrahypothalamic administration of either yohimbine (a blocking agent of alpha-adrenergic receptors), phentolamine (a blocking agent of alpha-adrenergic receptors) or DL-propranolol (a blocking agent of beta-adrenergic receptors) in the rat. However, the fever induced by d-amphetamine was antagonized by pretreatment with yohimbine or phentolamine, but not with DL-propranolol in the rat. These observations indicate that the adrenergic receptor mechanisms within the hypothalamus are involved in the fever induced by both d-amphetamine and TRH.

Barbiturate and amphetamine activity in rats fed a magnesium-deficient diet.

Hexobarbital hypnosis and d-amphetamine toxicity were observed in rats fed a commercially available rat food preparation (lab chow) and in another two groups fed complete nutritionally defined diets with or without magnesium. Neither hexobarbital sleeping time nor hexobarbital blood concentration at awakening were affected after 4, 8 or 12 days of feeding the deficient diet. However, increased sensitivity to d-amphetamine was observed after 11 days of feeding the same magnesium deficient diet to other rats. The LD50 of d-amphetamine in magnesium deficient rats was less than 0.5 that recorded for the groups fed lab chow or the nutritionally defined diet with a magnesium supplement.