ICI 204,636, a novel, atypical antipsychotic: early indication of safety and efficacy in patients with chronic and subchronic schizophrenia.

We evaluated the effects of ICI 204,636 in 12 hospitalized patients with schizophrenia in a double-blind, placebo-controlled, parallel-group, rising-dose study. Patients met the Diagnostic and Statistical Manual of Mental Disorders, Third Edition, Revised criteria for chronic or subchronic schizophrenia and had a total score > or = 30 on the 18-item Brief Psychiatric Rating Scale (BPRS) and a score > or = 3 on the Clinical Global Impression (CGI) Severity of Illness item. Patients received 21 days of double-blind treatment with increasing doses of ICI 204,636 (25 to 250 mg/d) or placebo. Efficacy was assessed using the BPRS and CGI. Response to treatment was defined as a > or = 30% decrease in the BPRS total score from baseline. Extrapyramidal symptoms and abnormal involuntary movements were assessed using the Simpson Scale and Abnormal Involuntary Movement Scale. Changes from baseline in the BPRS and CGI were significantly greater at end point for patients who received ICI 204,636 versus placebo (BPRS, -20.9 vs -4.8; CGI, -2.9 vs -1.0; P < 0.05, analysis of covariance; P < or = 0.06, Wilcoxon rank sum test). All patients in the ICI 204,636 group responded to treatment (P < 0.10) versus only two patients in the placebo group. Mild somnolence occurred in 50% of ICI 204,636-treated patients. No treatment-emergent extrapyramidal symptoms or dystonic reactions were observed. ICI 204,636 showed efficacy in the positive and negative symptoms of schizophrenia and was well tolerated.

Seroquel: behavioral effects in conventional and novel tests for atypical antipsychotic drug.

Seroquel was compared to clozapine and several other antipsychotic agents in tests predictive of antipsychotic activity or extrapyramidal symptoms. In the conditioned avoidance test in squirrel monkeys as well as several paradigms using apomorphine or amphetamine-induced behavioral alterations, seroquel displayed the profile of a drug with potential antipsychotic activity. In these paradigms the potency of seroquel was somewhat less than clozapine in rodent tests, while the reverse was true in higher species, i.e. monkeys, cats. In tests designed to evaluate the propensity to induce EPS or tardive dyskinesia, for example, the production of dyskinetic reactions in haloperidol-sensitized cebus monkeys, seroquel displayed a profile similar to clozapine and disparate from typical antipsychotic drugs. In drug-naive cebus monkeys seroquel sensitized significantly fewer monkeys than haloperidol and the dyskinetic reactions were of significantly less intensity. It is anticipated that this novel antipsychotic agent will have a significantly reduced propensity to produce extrapyramidal symptoms and tardive dyskinesia than typical antipsychotics.

Seroquel: electrophysiological profile of a potential atypical antipsychotic.

Extracellular single unit recording techniques were employed to compare the effects of seroquel with the reference antipsychotic (AP) agents clozapine and haloperidol in electrophysiological tests that may predict AP activity. Seroquel and clozapine were differentially more active in reversing the inhibitory actions of d-amphetamine on mesolimbic (A10) than nigrostriatal (A9) dopamine (DA)-containing neurons, whereas haloperidol exhibited the opposite selectivity. In cell population studies, acute treatment with seroquel and clozapine selectively increased the number of spontaneously active A10 DA cells, which was found to correlate with the ability of both these drugs to cause depolarization inactivation (DI) of A10 DA cells following repeated (28 day) administration. This profile of activity was unlike that of haloperidol, which acutely caused a nonselective increase in the number of active A9 and A10 DA cells, associated with the ability of this agent to cause DI of both A9 and A10 DA cells after repeated treatment. Since DI of A10 DA cells may be correlated with AP efficacy whereas DI of A9 DA cells may predict the ability of an AP to cause extrapyramidal side effects (EPS) and tardive dyskinesia (TD), seroquel, like clozapine, may be an atypical AP with a reduced likelihood for producing EPS/TD.

A novel potent non-benzodiazepine anxioselective agent with reduced dependence liability: ICI 198, 256.

ICI 198,256, a member of the cinnoline series, was shown to be a potent anxiolytic agent in several species of animals. In addition, ICI 198,256 exhibited potent activity as an antagonist of both metrazole and bicuculline-induced convulsions. The salient features of ICI 198,256 are that it possesses minimal sedative liability, lower ethanol interaction and possibly lower dependence liability than benzodiazepines (e.g., diazepam). Neurochemically, this structurally novel anxiolytic compound is potent and selective for the Type 1 (cerebellar) BZ receptors in vivo as well as ex vivo, and in addition shows an agonist BZ-like profile in a variety of systems. Thus, ICI 198,256 may offer several significant advantages in the treatment of anxiety in humans than existing benzodiazepines.

Effects of ICI 169,369, a selective serotonin2 antagonist, in electrophysiological tests predictive of antipsychotic activity.

Extracellular single unit recording techniques were used to compare the effects of ICI 169,369, a selective serotonin2 receptor antagonist, with the reference antipsychotic (AP) agents clozapine and haloperidol, in electrophysiological tests that may predict AP activity. ICI 169,369 was found to reverse the inhibitory actions of amphetamine on A9 and A10 dopamine (DA) neurons, a common property shared by other AP drugs, and was comparable in potency to clozapine. In cell population studies, acute treatment with ICI 169,369 (at a low dose only) and clozapine selectively increased the number of spontaneously active A10 DA cells, which was found to correlate with the ability of both these drugs to cause depolarization inactivation (DI) of A10 DA cells after chronic administration. Interestingly, chronic treatment with ICI 169,369 also caused a significant increase in the number of actively discharging A9 DA cells, an effect not predicted on the basis of the acute data. A similar effect was noted for clozapine, although the magnitude did not reach statistical significance. This profile of activity was unlike that of haloperidol, which acutely caused a nonselective increase in the number of active A9 and A10 DA cells, associated with the ability of this agent to cause DI of both A9 and A10 DA cells after chronic treatment. Inasmuch as DI of A10 DA cells may be correlated with AP efficacy whereas DI of A9 DA cells may predict the ability of an AP to cause extrapyramidal side effects, ICI 169,369, like clozapine, may be a potential AP with a reduced likelihood for producing extrapyramidal side effects.

Preclinical studies with pyrazolopyridine non-benzodiazepine anxiolytics: ICI 190,622.

Tracazolate is a pyrazolopyridine anxiolytic that enhances the binding of [3H]-flunitrazepam [( 3H]FLU) to brain tissue. The discovery that a metabolite of tracazolate, desbutyltracazolate, was a weak inhibitor of [3H]FLU binding led to the synthesis of a series of potent anxiolytics. From this series, ICI 190,622 emerged as a viable drug candidate, being a potent anxiolytic in rats and monkeys. This anxiolytic agent appears to produce only minimal sedation. Furthermore, ICI 190,622 appears less likely to potentiate the actions of ethanol than diazepam. ICI 190,622 is also a potent anticonvulsant (anti-metrazol ED50 = 1.1 mg/kg, PO) in rodents. Neurochemically, ICI 190,622 is similar to the benzodiazepine anxiolytics. In vitro, ICI 190,622 competitively inhibited [3H]FLU binding in cerebral cortex with an IC50 of 81 nM and was 4.3-fold more potent in the cerebellum (IC50 = 19 nM). This suggests a selectivity for the Type 1 benzodiazepine binding site. In contrast, diazepam showed similar affinities in both regions (cerebral cortex = 7 nM and cerebellum = 9 nM). Following oral administration, ICI 190,622 displaced [3H]FLU binding from cerebellar membranes more potently than diazepam (ED50 = 3 and 6 mg/kg, respectively, 1 hour after administration). Thus, ICI 190,622 should be an effective anxiolytic with significant advantages over benzodiazepines.

A simple and rapid method of inducing physical dependence with benzodiazepines in mice.

Physical dependence was rapidly induced in mice by administering diazepam intraperitoneally twice daily using an incremental dosing regimen (50 to 450 mg/kg) for nine consecutive days. Withdrawal was induced (24 hr after the last dose) by administration of a benzodiazepine antagonist, RO-15-1788 (10 mg/kg, IP). All of the mice exhibited clear-cut withdrawal symptoms (i.e., convulsions) within minutes of antagonist treatment. This method offers a simple, reliable, high throughput procedure for the assessment of benzodiazepine-like physical dependence liability and withdrawal, and it would be useful for screening purposes.

D-2 dopamine antagonist-like effects of SCH 23390 on A9 and A10 dopamine neurons.

The effects of SCH 23390 on d-amphetamine-induced suppression of A9 and A10 DA neuronal firing were determined. SCH 23390 potently reversed d-amphetamine on both A9 and A10 DA neurons. Compared to haloperidol, SCH 23390 was 5 times more potent on A9 DA neurons and 20 times more potent on A10 DA neurons. However, the magnitude of the reversal effect was greater with haloperidol than SCH 23390. In addition, haloperidol produced a further increase in firing of both A9 and A10 DA neurons after SCH 23390 maximally increased firing. It was concluded that SCH 23390 has D-2 DA antagonist-like properties, possibly mediated via an interaction at D-1 DA receptors, which may be functionally linked with D-2 DA receptors. The marked potency of SCH 23390 in reversing d-amphetamine could be due to its combined antagonist effects at 5HT2 and D-1 DA receptor sites.

Interactions of Ro 15-1788, CGS 8216 and diazepam on head-turning in rats.

Ro 15-1788 (10 mg/kg, ip) and CGS 8216 (10 mg/kg, ip) significantly reversed the inhibitory effect of diazepam (5 mg/kg, ip) on electrically induced head-turning in rats. Neither antagonist alone, at the dose level which blocked diazepam, had any intrinsic activity in this model. The specificity of the interaction between CGS 8216 and diazepam was further confirmed by the lack of antagonism by CGS 8216 of muscimol's inhibitory effect on head-turning. These results provide additional evidence that the inhibition of head-turning induced by diazepam is mediated via the benzodiazepine binding site. Furthermore, this model provides a functional expression of the interaction between the benzodiazepine recognition site, the chloride ionophore, and the GABA receptor complex.

Pharmacology of pyrazolopyridines.

Pyrazolopyridines (PZP's) in general represent a chemically unique class of non-sedative anxiolytic agents. Tracazolate (ICI 136,753) is a member of pyrazolopyridine series that has shown anxiolytic properties in animal models. Tracazolate demonstrates a wider separation between sedative and therapeutic doses than do benzodiazepines. In addition, tracazolate appears to cause fewer adverse interactions than the benzodiazepines in combination with barbiturates and alcohol. In interaction studies, tracazolate potentiated both the antimetrazol and anticonflict effects of chlordiazepoxide. Pyrazolopyridines cause enhancement of both 3H-flunitrazepam (3H-FLU) and 3H-GABA to their binding sites in brain. The enhancement of 3H-FLU binding by PZP's and GABA are additive and reversed by bicuculline. The enhancement of 3H-GABA binding by PZP's and benzodiazepines are additive and reversed by picrotoxin. It is hypothesized that the action of PZP's, and particularly tracazolate, may be related to their effects upon a GABA-stimulated chloride ionophore site. Finally, benzodiazepine antagonists (e.g., RO-15 1788) fail to reverse either the anxiolytic properties of 3H-FLU enhancers or their 3H-GABA binding enhancement effects. In contrast, benzodiazepine antagonists readily reverse the anxiolytic effects of benzodiazepines and non-benzodiazepines which cause 3H-FLU displacement. These data suggest that tracazolate, a non-benzodiazepine, has a pharmacological profile suggestive of novel anxiolytic activity.

Behavioral evidence for beta-adrenoceptor subsensitivity after subacute antidepressant/alpha 2-adrenoceptor antagonist treatment.

The behavioral consequences of beta-adrenoceptor subsensitivity were investigated by determining whether a physiological response that is mediated by beta-receptors, isoproterenol-induced drinking (IID), would be reduced by subacute antidepressant/alpha 2-antagonist treatment. The coadministration of typical (e.g., imipramine) or atypical (e.g., mianserin) antidepressants with yohimbine or piperoxan twice daily for four consecutive days reduced IID. Both the time course as well as the magnitude of beta-adrenoceptor subsensitivity could be behaviorally demonstrated. In addition, the reduction in IID observed after coadministration of imipramine with yohimbine was a centrally mediated effect since it was observed after systemic (subcutaneous) and central (intraventricular) administration of isoproterenol. These results provide evidence that IID is an appropriate behavioral model to demonstrate beta-adrenoceptor subsensitivity following subacute antidepressant/alpha 2-antagonist treatment.

Neurochemical characteristics of rats distinguished as benzodiazepine responders and non-responders in a new conflict test.

Using a new rat conflict test it was found that 30% of the subjects failed to respond to benzodiazepines and other anxiolytic agents. This value is similar to that reported using more classical procedures such as the Geller-Seifter and Vogel conflict tests. Biochemical analysis of various brain regions from responder (R) and non-responder (NR) subjects revealed no significant differences in 5-HT1, 5-HT2, GABA receptor binding or GABA-activated benzodiazepine binding. However, a small, but significant, increase in basal benzodiazepine binding was noted in the hippocampus of NR rats. These findings suggest that the insensitivity of these animals to anxiolytics is probably unrelated to an alteration in serotonin, GABA or benzodiazepine binding sites in brain.

Novel non-benzodiazepine anxiolytics.

Several new non-benzodiazepine anxiolytics are reported. These include tracazolate, zopiclone, CL218,872, CGS9896, buspirone, MK-801 and fenobam. A comparison of anticonflict effects and propensity to cause sedation and potentiate the actions of ethanol is given as well as their effects upon the binding of [3H]flunitrazepam in vitro. Their anxiolytic properties after treatment with the benzodiazepine antagonist, RO15-1788, are reported also. Tracazolate shows a wide separation between anxiolytic activity and ability to cause sedation and to potentiate alcohol. It enhanced binding of [3H]-flunitrazepam in contrast to benzodiazepines which displace it. Buspirone was without anticonflict activity and had no effect on benzodiazepine binding while fenobam and MK-801, also without effect on binding, showed large and small differences on causing sedation and potentiating alcohol respectively. Among the displacers of [3H]flunitrazepam zopiclone showed diminished sedation liability, compared to diazepam, as did CL218,872 and CGS9896. Zopiclone caused potentiation of ethanol however, at doses close to anxiolytic doses, while CL218,872 and CGS9896 showed a wider safety margin for potentiation of ethanol compared to anxiolytic doses. The drug RO15-1788 antagonised the anticonflict effects of benzodiazepine displacers and had no effects upon the other agents studied.

Electrophysiological demonstration of both alpha 2-agonist and antagonist properties of RX 781094.

The effects of RX 781094, a new and potent alpha 2-adrenoceptor antagonist, on locus coeruleus (LC) unit activity were examined. Low doses of RX 781094 produced suppression of spontaneous LC unit activity which could be reversed with yohimbine. The increase in LC firing produced by WB 4101 could also be reversed with a low dose of RX 781094. Thus, at low doses, RX 781094 has clonidine-like alpha 2-agonist activity. At higher doses, RX 781094 reversed the effects of clonidine and markedly shifted the dose of clonidine required to suppress LC unit activity. These data suggest that at high doses RX 781094 has alpha 2-antagonist properties. It is concluded that RX 781094 may be a partial agonist at alpha 2-adrenoceptors in the CNS.

Gabamimetic properties of anxiolytic drugs.

Diazepam (5 mg/kg, ip) and tracazolate (40 mg/kg, ip), a nonbenzodiazepine anxiolytic, blocked electrically-induced head-turning without producing sedation. Bicuculline and picrotoxin, GABA antagonists, at doses not affecting head-turning (2 mg/kg, ip) antagonized the effects of diazepam and tracazolate on head-turning. However, at the same dose, bicuculline was more effective as an antagonist of diazepam whereas picrotoxin was more effective as an antagonist of tracazolate. These results suggest that benzodiazepine as well as nonbenzodiazepine anxiolytics possess GABAmimetic activity. The difference in potency between bicuculline and picrotoxin as antagonists of diazepam and tracazolate may be related to their reported differences as GABA antagonists (e.g., site of receptor interaction).

Differential antagonism of the anticonflict effects of typical and atypical anxiolytics.

Selected benzodiazepine and non-benzodiazepine agents were studied alone or in the presence of benzodiazepine antagonists in the shock-induced suppression of drinking (SSD) procedure in rats. The disinhibitory activity of chlordiazepoxide, CL218,872, zopiclone and CGS 9896 was antagonized by two benzodiazepine antagonists, RO-15-1788 and CGS 8216. In contrast, the disinhibitory activity of fenobam, meprobamate, phenobarbital and tracazolate was not antagonized by either RO 15-1788 and CGS 8216. From these data it is apparent that the anticonflict activity of agents that bind to benzodiazepine receptors is blocked by benzodiazepine antagonists. In contrast, the activity of anxiolytics that are not displacers are unaffected even at higher doses.

Effects of acute and subacute antidepressant treatment on kindled seizures in rats.

The effects of acute and subacute administration of the tricyclic antidepressants imipramine and amitriptyline, and the atypical antidepressants mianserin and iprindole, on seizures kindled from the amygdala and the cortex were examined. Whereas amitriptyline selectively antagonized seizures kindled from the amygdala after a single dose, neither amitriptyline nor imipramine was any more effective in antagonizing seizures kindled from the amygdala than from the cortex following subacute treatment. Both acute and subacute administration of iprindole failed to significantly alter seizures kindled from either site. Although only the highest acute dose of mianserin tested selectively attenuated amygdaloid seizures, a lower dose that was ineffective when given acutely, was selective when given subacutely. In contrast to an earlier report, the present findings suggest that kindling may not be a particularly useful model for the evaluation of potential antidepressant agents.

Pharmacological properties of tracazolate: a new non-benzodiazepine anxiolytic agent.

Tracazolate (ICI 136,753, 4-butylamino-1-ethyl-6-methyl-1H-pyrazolo[3,4-b]pyridine-5-carboxylic acid ethyl ester) demonstrated dose-related anticonflict activity in rats and mice. The potency of tracazolate appears to be one-quarter to one-half that of chlordiazepoxide. No tolerance to the anticonflict activity of either tracazolate or chlordiazepoxide was evident following 12 consecutive days of treatment. Tracazolate exhibits a much greater separation between sedative and therapeutic doses than does chlordiazepoxide. Furthermore, based on rodent studies, tracazolate should be much less likely than the benzodiazepines to potentiate the actions of barbiturates and ethanol in man. Tracazolate potentiated both the anticonvulsant and anxiolytic effects of chlordiazepoxide in rodents. Unlike benzodiazepines, tracazolate enhances the binding of benzodiazepines to its receptor site. These results suggest that tracazolate is a novel agent with potential clinical utility as an anxiolytic drug.

Benzodiazepine receptor binding in young, mature and senescent rat brain and kidney.

Clinical reports have described age-altered pharmacological effects of anxiolytic drugs especially an increased susceptibility to their sedative actions. In order to test whether such changes may be due to age-related alterations in central benzodiazepine receptors, 3H-flunitrazepam binding was assayed in the frontal cortex and cerebellum of young, mature and senescent rats. The numbers of 3H-flunitrazepam binding sites and their affinity was determined by Scatchard analysis of saturation isotherms and the relative abundance of type I and type II benzodiazepine receptors was assessed by drug-inhibition studies using diazepam and the triazolopyridazine, CL 218,872. In addition, age related changes in the kidney and hippocampus of the Ro5-4864-sensitive benzodiazepine receptor were studied using 3H-Ro5-4864. No age-related alterations were noted in the binding characteristics of 3H-flunitrazepam. Furthermore, drug-inhibition of 3H-flunitrazepam binding by diazepam and CL 218,872 was nearly identical in young, mature and senescent rats, indicating that also the ratio of type I and type II receptors does not change with age. Binding of 3H-Ro5-4864 to membranes from rat hippocampus was not age-related. However, a significant decrease in 3H-Ro5-4864 binding to kidney membranes was demonstrated. Hence, central benzodiazepine receptors appear unaltered in the senescent rat model of aging. The clinical findings of an increased susceptibility to the sedative effects of benzodiazepines in the elderly may therefore be attributed to pharmacokinetic variables, or to events occurring secondarily to receptor activation.