Quetiapine: an effective antipsychotic in first-episode schizophrenia despite only transiently high dopamine-2 receptor blockade

BACKGROUND: It has been suggested that transiently high dopamine-2 (D(2)) receptor occupancy by antipsychotic medication may be sufficient for inducing an antipsychotic response. We treated patients experiencing their first episode of schizophrenia with a single daily dose of quetiapine to achieve a transient daily peak of D(2) receptor blockade, to determine if this would lead to an antipsychotic response. METHOD: Fourteen patients with a DSM-IV diagnosis of schizophrenia or schizophreniform or schizoaffective disorder were treated with quetiapine titrated to a single daily dose (mean +/- SD dose at the time of the positron emission tomography [PET] scan = 427 +/- 69 mg) for 12 weeks. Peak D(2) occupancy approximately 2 hours postdose and trough D(2) occupancy approximately 20 hours postdose were determined using PET and [(11)C]raclopride. Clinical symptoms and side effects were measured at baseline and every 2 weeks during the treatment phase. RESULTS: Quetiapine administration led to a mean peak D(2) occupancy of 62% +/- 10% 2 hours postdose, which declined to 14% +/- 8% approximately 20 hours postdose. Ten (71%) of 14 patients responded to treatment with quetiapine, scoring "much improved" or greater on the Clinical Global Impressions-Improvement scale. Plasma drug levels and peak D(2) occupancy were highly correlated (r = 0.84; p =.003), as were prolactin and plasma drug levels when measured 2.5 hours after drug administration (r = 0.60; p <.05). Mean weight gain for the 10 subjects who completed the 12-week study was 4.2 +/- 4.6 kg (9.3 +/- 10.2 lb). No clinically relevant motor side effects occurred during the trial. CONCLUSION: Patients with a first episode of schizophrenia responded to treatment with a single daily dose of quetiapine despite only transiently high D(2) receptor occupancy. Our findings raise the question of whether continuously high D(2) blockade is necessary for obtaining an antipsychotic response. Future studies aimed at evaluating the relative merits of "transiently high" versus "continuously high" D(2) occupancy are warranted.     

A PET study of dopamine D2 and serotonin 5-HT2 receptor occupancy in patients with schizophrenia treated with therapeutic doses of ziprasidone

OBJECTIVE: Ziprasidone is an atypical antipsychotic drug that shows a higher affinity for serotonin 5-HT(2) receptors compared with dopamine D(2) receptors in vitro. The affinity of ziprasidone for these receptors in vivo in patients was examined in a positron emission tomography (PET) study. METHOD: The authors conducted a PET study to evaluate D(2) occupancy (using [(11)C]raclopride) and 5-HT(2) occupancy (using [(18)F]setoperone) in brain regions of interest in 16 patients with schizophrenia or schizoaffective disorder randomly assigned to receive 40, 80, 120, or 160 mg/day of ziprasidone, which reflected the recommended dose range. PET scanning was done after 3 weeks of administration and at trough plasma levels, i.e., 12-16 hours after the last dose. RESULTS: The mean 5-HT(2) receptor occupancy was significantly higher than the mean D(2) receptor occupancy (mean=76%, SD=15%, and mean=56%, SD=18%, respectively). The estimated plasma ziprasidone concentration associated with 50% maximal 5-HT(2) receptor occupancy was almost four times lower than that for D(2) receptor occupancy. CONCLUSIONS: These data affirm that ziprasidone is similar to other novel antipsychotics in having greater 5-HT(2) than D(2) receptor occupancy at therapeutic doses and suggest that the optimal effective dose of ziprasidone is closer to 120 mg/day than to the lower doses suggested by previous PET studies. The relatively high D(2) receptor occupancy, even at trough plasma levels, suggests that ziprasidone is more similar to risperidone and olanzapine in receptor occupancy profile than to clozapine and quetiapine. Since ziprasidone plasma levels show significant (more than twofold) variation within a single dose cycle, studies that are aimed at peak plasma levels (6 hours after the last dose) and that examine extrastriatal regions are required to fully characterize the in vivo occupancy profile of ziprasidone.     

Atypical antipsychotics: mechanism of action.

BACKGROUND: Although the principal brain target that all antipsychotic drugs attach to is the dopamine D2 receptor, traditional or typical antipsychotics, by attaching to it, induce extrapyramidal signs and symptoms (EPS). They also, by binding to the D2 receptor, elevate serum prolactin. Atypical antipsychotics given in dosages within the clinically effective range do not bring about these adverse clinical effects. To understand how these drugs work, it is important to examine the atypical antipsychotics' mechanism of action and how it differs from that of the more typical drugs. METHOD: This review analyzes the affinities, the occupancies, and the dissociation time-course of various antipsychotics at dopamine D2 receptors and at serotonin (5-HT) receptors, both in the test tube and in live patients. RESULTS: Of the 31 antipsychotics examined, the older traditional antipsychotics such as trifluperazine, pimozide, chlorpromazine, fluphenazine, haloperidol, and flupenthixol bind more tightly than dopamine itself to the dopamine D2 receptor, with dissociation constants that are lower than that for dopamine. The newer, atypical antipsychotics such as quetiapine, remoxipride, clozapine, olanzapine, sertindole, ziprasidone, and amisulpride all bind more loosely than dopamine to the dopamine D2 receptor and have dissociation constants higher than that for dopamine. These tight and loose binding data agree with the rates of antipsychotic dissociation from the human-cloned D2 receptor. For instance, radioactive haloperidol, chlorpromazine, and raclopride all dissociate very slowly over a 30-minute time span, while radioactive quetiapine, clozapine, remoxipride, and amisulpride dissociate rapidly, in less than 60 seconds. These data also match clinical brain-imaging findings that show haloperidol remaining constantly bound to D2 in humans undergoing 2 positron emission tomography (PET) scans 24 hours apart. Conversely, the occupation of D2 by clozapine or quetiapine has mostly disappeared after 24 hours. CONCLUSION: Atypicals clinically help patients by transiently occupying D2 receptors and then rapidly dissociating to allow normal dopamine neurotransmission. This keeps prolactin levels normal, spares cognition, and obviates EPS. One theory of atypicality is that the newer drugs block 5-HT2A receptors at the same time as they block dopamine receptors and that, somehow, this serotonin-dopamine balance confers atypicality. This, however, is not borne out by the results. While 5-HT2A receptors are readily blocked at low dosages of most atypical antipsychotic drugs (with the important exceptions of remoxipride and amisulpride, neither of which is available for use in Canada) the dosages at which this happens are below those needed to alleviate psychosis. In fact, the antipsychotic threshold occupancy of D2 for antipsychotic action remains at about 65% for both typical and atypical antipsychotic drugs, regardless of whether 5-HT2A receptors are blocked or not. At the same time, the antipsychotic threshold occupancy of D2 for eliciting EPS remains at about 80% for both typical and atypical antipsychotics, regardless of the occupancy of 5-HT2A receptors. RELEVANCE: The "fast-off-D2" theory, on the other hand, predicts which antipsychotic compounds will or will not produce EPS and hyperprolactinemia and which compounds present a relatively low risk for tardive dyskinesia. This theory also explains why L-dopa psychosis responds to low atypical antipsychotic dosages, and it suggests various individualized treatment strategies.     

Receptor occupancy and antipsychotic drug action measured by PET and SPECT]

Positron emission tomography (PET) and single photon emission computed tomography (SPECT) studies have demonstrated consistent findings of high dopamine D2 receptor occupancy (> 65-70%) in patients treated with antipsychotic drugs. Further, the risk of extrapyramidal side effects has been shown high in patients with occupancy above 80%. On the basis of these findings, an optimal interval for D2 receptor occupancy between 70% and 80% has been suggested. It has also been shown that several atypical antipsychotics induce marked occupancy of central 5-HT2 and D2 receptors in vivo. However, a low D2 occupancy has been observed in patients with clinical dose of clozapine or quetiapine. The antipsychotic effect of these atypical drugs with a low D2 receptor occupancy has been widely discussed with respect to actions on other receptor systems, limbic selectivity of antipsychotic action and episodic transient occupancy. The recent advances in PET/SPECT and developments of new radioligands have made it possible to evaluate antipsychotic drug actions directly in humans. The empirical data from occupancy measurements will enable us to open future directions of investigation of antipsychotic action and improvement of antipsychotic treatment.     

Suggested minimal effective dose of risperidone based on PET-measured D2 and 5-HT2A receptor occupancy in schizophrenic patients.

OBJECTIVE: Multicenter trials with the novel antipsychotic risperidone have suggested a standard dose of 6 mg/day. However, a dose producing the highest response rate in fixed-dose studies is likely to exceed the minimal effective dose in most patients. The aim of this positron emission tomography (PET) study was to suggest a minimal effective dose of risperidone based on measurements of dopamine D2 and serotonin 5-HT2A receptor occupancy. METHOD: Eight first-episode or drug-free schizophrenic patients were treated with risperidone, 6 mg/day, for 4 weeks and then 3 mg/day for 2 weeks. PET was performed after 4 and 6 weeks, with [11C]raclopride to measure D2 receptor occupancy and [11C]N-methylspiperone to measure 5-HT2A receptor occupancy. RESULTS: Seven patients completed the study and responded to treatment with risperidone. No patient had extrapyramidal side effects at the time of inclusion in the study. At the 6-mg/day dose, mean D2 receptor occupancy was 82% (range = 79%-85%), 5-HT2A receptor occupancy was 95% (range = 86%-109%), and six patients had developed extrapyramidal side effects. After dose reduction to 3 mg/day, D2 receptor occupancy was 72% (range = 53%-78%), and 5-HT2A receptor occupancy was 83% (range = 65%-112%). Three patients had extrapyramidal side effects at this time. CONCLUSIONS: Treatment with risperidone, 6 mg/day, is likely to induce unnecessarily high D2 receptor occupancy, with a consequent risk of extrapyramidal side effects. High 5-HT2A receptor occupancy did not prevent extrapyramidal side effects completely. The authors previously suggested an optimal interval for D2 receptor occupancy of 70%-80%. To achieve this, resperidone, 4 mg/day, should be a suitable initial dose for antipsychotic effect with a minimal risk of extrapyramidal side effects in most patients.     

Antipsychotic drugs,dopamine receptors,and schizophrenia

The clinical potencies of antipsychotic drugs are directly related to their affinities for the dopamine D2 receptor. In addition, the concentrations of antipsychotic drugs (given at therapeutic maintenance doses) in the plasma water or in the spinal fluid are almost identical to the antipsychotic dissociation constants at the dopamine D2 receptor. A consistent 70–75% of brain D2 receptors are occupied by antipsychotic drugs, as calculated from the therapeutic concentration and the antipsychotic dissociation constant. The D3 and D4 dopamine receptors, however, are not consistently occupied by antipsychotic drugs, the occupancies being 0–85% for D3, and 0–95% for D4. Human brain imaging also reveals that therapeutic doses of antipsychotic drugs occupy ∼70% of D2 receptors. Between 2 and 4 h after the daily oral dose, clozapine and quetiapine occupy high levels (∼70%) of the dopamine D2 receptors in schizophrenia patients, with lower occupancies at 6 and 12 h. Although clozapine and quetiapine occupy low levels of D2 receptors many hours after the oral dose, the observed fraction of D2 receptors occupied by these drugs, however, depends on the radioligand used, with high occupancy seen when using [¹¹C]raclopride, and low occupancy seen with [¹¹C]methylspiperone (which is tightly bound to D2). This dependence on the radioligand occurs because clozapine and quetiapine are loosely bound to D2. The loose binding of clozapine and quetiapine to D2 permits endogenous dopamine to displace these antipsychotic drugs much more quickly than haloperidol. In addition, the small dose of radioactive raclopride injected (in brain imaging) can displace a little of the D2-bound clozapine. Hence, the observed low level of D2 occupancy by clozapine in patients may arise from a combination of the above three factors – the ligand dependency, the endogenous dopamine, and the displacement by the imaging dose. Parkinsonism and extrapyramidal effects occur with antipsychotics which have a high affinity for D2 and which are, therefore, tightly bound to D2. Clozapine and quetiapine have a low affinity for D2, and, being readily displaced by endogenous dopamine, do not give rise to extrapyramidal effects. Because the loosely bound antipsychotics dissociate from D2 more rapidly, clinical relapse may occur earlier than that found with the tightly bound traditional antipsychotics. The dopamine hypothesis of schizophrenia is supported by the fact that D2 is the main target of antipsychotic action, that monomers of D2 appear elevated in schizophrenia, and that the synaptic levels of dopamine in schizophrenia are at least two-fold higher than in control subjects.     

Differential effects of aripiprazole on D(2), 5-HT(2), and 5-HT(1A) receptor occupancy in patients with schizophrenia: a triple tracer PET study

OBJECTIVE: Aripiprazole has a unique pharmacological profile that includes partial agonism at D(2) receptors, antagonism at 5-HT(2) receptors, and partial agonism at 5-HT(1A) receptors. The authors conducted a positron emission tomography (PET) study to characterize the simultaneous effects of aripiprazole at the D(2), 5-HT(2), and 5-HT(1A) receptors in patients with schizophrenia or schizoaffective disorder. METHOD: Twelve patients who had previously received antipsychotic treatment were randomly assigned to receive 10 mg, 15 mg, 20 mg, or 30 mg of aripiprazole. After at least 14 days of treatment, participants underwent high-resolution PET scans using [(11)C]raclopride, [(18)F]setoperone, and [(11)C]WAY100635. RESULTS: Very high occupancy was observed at striatal D(2) receptors (average putamen, 87%; caudate, 93%; and ventral striatum, 91%), lower occupancy at 5-HT(2) receptors (54%-60%), and even lower occupancy at 5-HT(1A) receptors (16%). D(2) occupancy levels were significantly correlated with plasma drug concentrations, and even the lowest dose (10 mg) led to 85% D(2) occupancy. Extrapyramidal side effects were seen only in two of the four participants with occupancies exceeding 90%. CONCLUSIONS: Aripiprazole exhibits a unique occupancy profile as compared with other conventional and atypical antipsychotics. The threshold for response appears to be higher than 60%, extrapyramidal side effects appear to be uncommon even at occupancies that exceed the conventional extrapyramidal side effects threshold of 80%, and 5-HT(2) occupancy is lower than D(2) occupancy. Implications for aripiprazole's mechanism of action are discussed.     

Is amoxapine an atypical antipsychotic? Positron-emission tomography investigation of its dopamine2 and serotonin2 occupancy.

BACKGROUND: All currently available atypical antipsychotics have, at clinically relevant doses: i) high serotonin (5-HT)2 occupancy; ii) greater 5-HT2 than dopamine (D)2 occupancy; and iii) a higher incidence of extrapyramidal side effects when their D2 occupancy exceeds 80%. A review of pharmacologic and behavioral data suggested that amoxapine should also conform to this profile; therefore, we undertook a positron-emission tomography (PET) study of its 5-HT2 and D2 occupancy. METHODS: Seven healthy volunteers received 50-250 mg/day of amoxapine for 5 days and then had [11C]-raclopride and [18F]-setoperone PET scans. RESULTS: 5-HT2 receptors showed near saturation at doses of 100 mg/day and above. The D2 receptor occupancies showed a dose-dependent increase, never exceeding 80%; at all doses 5-HT2 occupancy exceeded D2 occupancy. CONCLUSIONS: PET data show that amoxapine's profile is very similar to that of the established atypical antipsychotics. These data, together with amoxapine's in vitro pharmacologic profile, effectiveness in animal models, and efficacy in psychotic depression raise the possibility of amoxapine as an "atypical" antipsychotic agent in the treatment of schizophrenia.     

Are animal studies of antipsychotics appropriately dosed? Lessons from the bedside to the bench.

Animal models are crucial for understanding the mechanism of action of antipsychotics. However, the dose of an antipsychotic in animal studies is often arbitrarily chosen, with haloperidol 1 mg/kg being a rather common standard. Recent clinical positron emission tomography (PET) studies in patients show all antipsychotics to block dopamine D2 receptors, and most are effective at doses that lead to 60% to 80% D2 occupancy. When occupancy exceeds 80%, the incidence of side effects rises sharply. To use this "bedside" information to inform the "bench," we measured D2 occupancy in rats using a method similar in principle to the [11C]-raclopride PET method in humans. We found that: 1) as in humans, haloperidol is effective in animal models of antipsychotic action when D2 occupancy > 70% and leads to effects in models of extrapyramidal side effects when D2 occupancy is > 80%; 2) very low doses, 0.06 mg/kg/sc, cause acute D2 occupancy of 75%; 3) and even doses that acutely saturate D2 receptors give little D2 occupancy after 24 hours due to the very short half-life of haloperidol in rats (2.5 hours versus 24 hours in humans). We conclude that most previous animal studies of antipsychotics have used doses giving rise to inappropriately high acute D2 occupancy and inappropriately low D2 occupancy between doses. We exemplify how this dosing confounder could lead to inappropriate conclusions. Data from the bedside translated to the bench--using D2 occupancy as a mediating variable--will lead to more valid animal models.     

Is regionally selective D2/D3 dopamine occupancy sufficient for atypical antipsychotic effect? an in vivo quantitative [123I]epidepride SPET study of amisulpride-treated patients

OBJECTIVE: Atypical antipsychotic drug treatment is clinically effective with a low risk of extrapyramidal symptoms. Explanations for the mechanism underlying this beneficial therapeutic profile of atypical over typical antipsychotic agents include 1) simultaneous antagonism of dopamine D(2) and serotonin 5-HT(2A) receptors or 2) selective action at limbic cortical dopamine D(2)-like receptors with modest striatal D(2) receptor occupancy. Amisulpride is an atypical antipsychotic drug with selective affinity for D(2)/D(3) dopamine receptors and provides a useful pharmacological model for examining these hypotheses. The authors' goal was to evaluate whether treatment with amisulpride results in "limbic selective" D(2)/D(3) receptor blockade in vivo. METHOD: Five hours of dynamic single photon emission tomography data were acquired after injection of [(123)I]epidepride (approximately 150 MBq). Kinetic modeling was performed by using the simplified reference region model to obtain binding potential values. Estimates of receptor occupancy were made relative to a healthy volunteer comparison group (N=6). RESULTS: Eight amisulpride-treated patients (mean dose=406 mg/day) showed moderate levels of D(2)/D(3) receptor occupancy in the striatum (56%), and significantly higher levels were seen in the thalamus (78%) and temporal cortex (82%). CONCLUSIONS: Treatment with amisulpride results in a similar pattern of limbic cortical over striatal D(2)/D(3) receptor blockade to that of other atypical antipsychotic drugs. This finding suggests that modest striatal D(2) receptor occupancy and preferential occupancy of limbic cortical dopamine D(2)/D(3) receptors may be sufficient to explain the therapeutic efficacy and low extrapyramidal symptom profile of atypical antipsychotic drugs, without the need for 5-HT(2A) receptor antagonism.     

Prediction and assessment of extrapyramidal side effects induced by risperidone based on dopamine D(2) receptor occupancy

In the present study, we attempted to predict the risk of extrapyramidal side effects of a selective monoaminergic antagonist, risperidone, by analyzing the correlation between the dopamine D(2) receptor occupancy and the degree of extrapyramidal side effects of the drug. The occupancies of D(2) and 5-HT(2) receptors at various doses of risperidone were calculated by means of a receptor occupancy theory. The extrapyramidal side effects after administration of risperidone were attempted to predict by theoretical analysis of the correlation between the calculated occupancies and the evidence of extrapyramidal symptoms using a ternary complex model. The pharmacokinetic/pharmacodynamic analysis utilized the data concerning the pharmacokinetics of risperidone and 9-hydroxyrisperidone (active metabolite), their binding affinities with D(2) and 5-HT(2) receptors, and the clinical evidence of extrapyramidal symptoms (Extrapyramidal Symptom Rating Scale: ESRS), gathered from the literature. The mean occupancy of 5-HT(2) receptors after the administration of regular doses of risperidone was suggested to be more than 90%, whereas the mean occupancy of D(2) receptors varied between 50-80%, depending on the dose. The correlation between the occupancy of D(2) receptors and the extrapyramidal symptoms could be successfully analyzed with a ternary complex model, showing the predictability of the model for the extrapyramidal side effects of risperidone. Since the estimated risk of the extrapyramidal side effects varied with the dose, the present method of predicting the extrapyramidal side effects of risperidone may provide a basis for developing a rational dosing regimen for the drug.     

Theory in antipsychotic drug therapy for schizophrenia]

In Japan, antipsychotic polypharmacy with high doses for schizophrenia has been traditionally used. However, antipsychotic polyphamacy with high doses provide disadvantages for patient. Recent PET studies show that dopamine D2 occupancy with antipsychotics is important for the treatment of schizophrenia. First, antipsychotics become effective only at which their D2 occupancy exceeds 65%. Second, antipsychotics with D2 occupancy below 90% rarely causes occupancy exceeds 65%. Second, antipsychotics with D2 occupancy below 90% rarely causes extrapyramidal side effect. These results suggest that monopharmacy which uses a single antipsychotic agent with appropriate dose is recommended for schizophrenia treatment.     

Increased dopamine d(2) receptor occupancy and elevated prolactin level associated with addition of haloperidol to clozapine

OBJECTIVE: The authors added haloperidol, a potent D(2) blocker, to ongoing treatment with clozapine in patients with schizophrenia to determine the effects of this combination on dopamine D(2) receptor blockade, prolactin level, and extrapyramidal side effects. METHOD: At baseline and 4-8 weeks after the addition of haloperidol (4 mg/day) to ongoing clozapine treatment, five patients were examined for prolactin elevation, extrapyramidal side effects, drug plasma levels, and D(2) receptor occupancy measured with [(11)C]raclopride and positron emission tomography imaging. RESULTS: Adding haloperidol significantly increased D(2) receptor occupancy, from a mean of 55% to 79%, and significantly increased the prolactin level. One patient developed akathisia, and another manifested mild extrapyramidal side effects. CONCLUSIONS: Adding a modest dose of haloperidol to clozapine results in the high D(2) receptor occupancy and sustained prolactin elevation usually associated with typical antipsychotics. These findings suggest that the lack of prolactin elevation associated with clozapine derives mainly from low D(2) receptor occupancy and not from the medication's effects on other receptors.     

The next generation of "atypical" antipsychotics: the role of positron emission tomography

Almost fifteen years of research with Positron Emission Tomography (PET) and Single Photon Emission Computed Tomography (SPECT) have led to a profound understanding of the relationships between antipsychotic doses and plasma levels on the one hand and occupancy of (striatal) D2 -like dopamine receptors on the other hand as well as with the associated clinical effects and side effects. Furthermore, with the development of clinically "atypical" antipsychotics PET studies helped to generate hypotheses regarding the essential pharmacological properties of this heterogeneous class of drugs. Possible mechanisms of action include combined D2 -/5-HT2 antagonism, preferential mesolimbic binding, and fast dissociation from the D2 -receptor. Our recently published PET study on the in vivo characterization of the partial dopamine receptor agonist, aripiprazole, suggests a novel mechanism of action, which leads to clinically "atypical" properties of an antipsychotic. Aripiprazole, of which the antipsychotic efficacy has been proven in various multicenter clinical trials, leads to almost complete saturation of D2 -like dopamine receptors at clinically used doses; however, the incidence of extrapyramidal side effects under aripiprazole is not higher than under placebo. PET like no other method is suitable to display in vivo a novel mechanism of "atypicality" of a new class of antipsychotics.     

Does fast dissociation from the dopamine d(2) receptor explain the action of atypical antipsychotics?: A new hypothesis

OBJECTIVE: Although atypical antipsychotics are becoming the treatment of choice for schizophrenia, what makes an antipsychotic "atypical" is not clear. This article provides a new hypothesis about the mechanism of action of atypical antipsychotics. METHOD: Published data regarding the molecular, animal model, neuroimaging, and clinical aspects of typical and atypical antipsychotics were reviewed to develop this hypothesis. Particular attention was paid to data regarding the role of the serotonin 5-HT(2) and dopamine D(4) receptors in atypicality. RESULTS: Neuroimaging data show that optimal dopamine D(2) occupancy is sufficient to produce the atypical antipsychotic effect. Freedom from motor side effects results from low D(2) occupancy, not from high 5-HT(2) occupancy. If D(2) occupancy is excessive, atypicality is lost even in the presence of high 5-HT(2) occupancy. Animal data show that a rapid dissociation from the D(2) receptor at a molecular level produces the atypical antipsychotic effect. In vitro data show that the single most powerful predictor of atypicality for the current generation of atypical antipsychotics is fast dissociation from the D(2) receptor, not its high affinity at 5-HT(2), D(4), or another receptor. CONCLUSIONS: The authors propose that fast dissociation from the D(2) receptor makes an antipsychotic more accommodating of physiological dopamine transmission, permitting an antipsychotic effect without motor side effects, prolactin elevation, or secondary negative symptoms. In contrast to the multireceptor hypotheses, the authors predict that the atypical antipsychotic effect can be produced by appropriate modulation of the D(2) receptor alone; the blockade of other receptors is neither necessary nor sufficient.     

A PET study evaluating dopamine D2 receptor occupancy for long-acting injectable risperidone

OBJECTIVE: Long-acting injectable risperidone represents the first clinically available depot atypical antipsychotic. The present study used positron emission tomography (PET) to evaluate its dopamine D(2) binding profile at doses of 25, 50, or 75 mg administered every 2 weeks. METHOD: After achieving stabilization with one of the doses, nine patients with a diagnosis of schizophrenia or schizoaffective disorder underwent [(11)C]raclopride PET to measure D(2) occupancy. Participants were scanned twice during the 2-week injection interval: within 3 days after injection (postinjection) and within 5 days before the next injection (preinjection). At the same time, plasma was collected for measurements of risperidone plus 9-hydroxyrisperidone. RESULTS: Mean post- and preinjection D(2) occupancy levels for the 25-, 50-, and 75-mg doses were 71.0% and 54.0%, 74.4% and 65.4%, and 81.5% and 75.0%, respectively. There was a significant correlation between dose and plasma concentrations of risperidone plus 9-hydroxyrisperidone, and the estimated plasma concentration associated with 50% D(2) occupancy (ED(50)) was 11.06 ng/ml. Prolactin levels were not correlated with drug levels or D(2) occupancy. CONCLUSIONS: All three doses of injectable risperidone showed peak D(2) occupancy levels above the 65% threshold associated with optimal clinical response; the 75-mg dose approximated the 80% threshold linked to increased risk of extrapyramidal symptoms. Doses of 25 or 50 mg should provide therapeutic efficacy while minimizing the risk of extrapyramidal symptoms.     

Equivalent occupancy of dopamine D1 and D2 receptors with clozapine: differentiation from other atypical antipsychotics

OBJECTIVE: Clozapine, the prototype of atypical antipsychotics, remains unique in its efficacy in the treatment of refractory schizophrenia. Its affinity for dopamine D(4) receptors, serotonin 5-HT(2A) receptor antagonism, effects on the noradrenergic system, and its relatively moderate occupancy of D(2) receptors are unlikely to be the critical mechanism underlying its efficacy. In an attempt to elucidate the molecular/synaptic mechanism underlying clozapine's distinctiveness in refractory schizophrenia, the authors studied the in vivo D(1) and D(2) receptor profile of clozapine compared with other atypical antipsychotics. METHOD: Positron emission tomography with the radioligands [(11)C]SCH23390 and [(11)C]raclopride was used to investigate D(1) and D(2) receptor occupancy in vivo in 25 schizophrenia patients receiving atypical antipsychotic treatment with clozapine, olanzapine, quetiapine, or risperidone. RESULTS: Mean striatal D(1) occupancies ranged from 55% with clozapine to 12% with quetiapine (rank order: clozapine > olanzapine > risperidone > quetiapine). The striatal D(2) occupancy ranged from 81% with risperidone to 30% with quetiapine (rank order: risperidone > olanzapine > clozapine > quetiapine). The ratio of striatal D(1)/D(2) occupancy was significantly higher for clozapine (0.88) relative to olanzapine (0.54), quetiapine (0.41), or risperidone (0.31). CONCLUSIONS: Among the atypical antipsychotics, clozapine appears to have a simultaneous and equivalent occupancy of dopamine D(1) and D(2) receptors. Whether its effect on D(1) receptors represents agonism or antagonism is not yet clear, as this issue is still unresolved in the preclinical arena. This distinctive effect on D(1)/D(2) receptors may be responsible for clozapine's unique effectiveness in patients with schizophrenia refractory to other typical and atypical antipsychotics.     

Efficacy and tolerability of quetiapine in poorly responsive, chronic schizophrenia

With the notable exception of clozapine, there is at present insufficient information on the efficacy of atypical antipsychotic medications in patients with poorly responsive schizophrenia. The present study reports on the efficacy and tolerability of quetiapine and haloperidol in patients with schizophrenia who showed no response to treatment with fluphenazine. This study is a post hoc subanalysis of an 8-week, double-blind study of patients receiving quetiapine 600 mg/day or haloperidol 20 mg/day. The proportion of patients classified as "Clinical Global Impression responders" (defined as Clinical Global Impression Severity of Illness score of < or = 3 at study end) was greater in the quetiapine group compared with the haloperidol group (51% vs. 25%; P = 0.023). Overall, quetiapine was well tolerated with less extrapyramidal side-effects and reduction in prolactin when compared to haloperidol. Weight gain was modest but more apparent in quetiapine-treated patients. Quetiapine is an appropriate treatment choice in patients who do not respond to prior antipsychotic treatment.     

Relationship between dopamine D(2) occupancy, clinical response, and side effects: a double-blind PET study of first-episode schizophrenia

OBJECTIVE: Since all antipsychotics block dopamine D(2) receptors, the authors investigated how well D(2) receptor occupancy in vivo predicts clinical response, extrapyramidal side effects, and hyperprolactinemia. METHOD: In a double-blind study, 22 patients with first-episode schizophrenia were randomly assigned to 1.0 or 2. 5 mg/day of haloperidol. After 2 weeks of treatment, D(2) receptor occupancy was determined with [(11)C]raclopride and positron emission tomography, and clinical response, extrapyramidal side effects, and prolactin levels were measured. Patients who showed adequate responses continued taking their initial doses, those who did not respond had their doses increased to 5.0 mg/day, and evaluations were repeated at 4 weeks for all patients. RESULTS: The patients showed a wide range of D(2) occupancy (38%-87%). The degree of receptor occupancy predicted clinical improvement, hyperprolactinemia, and extrapyramidal side effects. The likelihood of clinical response, hyperprolactinemia, and extrapyramidal side effects increased significantly as D(2) occupancy exceeded 65%, 72%, and 78%, respectively. CONCLUSIONS: The study confirms that D(2) occupancy is an important mediator of response and side effects in antipsychotic treatment. The data are consistent with a "target and trigger" hypothesis of antipsychotic action, i.e., that the D(2) receptor specificity of antipsychotics permits them to target discrete neurons and that their antagonist properties trigger within those neurons intracellular changes that ultimately beget antipsychotic response. While limited to haloperidol, the relationship between D(2) occupancy and side effects in this study helps explain many of the observed clinical differences between typical and atypical antipsychotics.     

Cortical dopamine D2/D3 receptors are a common site of action for antipsychotic drugs--an original patient data meta-analysis of the SPECT and PET in vivo receptor imaging literature

Subject numbers in neuroreceptor imaging studies of antipsychotic treatment in schizophrenia are generally insufficient to directly test the relationship of regional D(2)/D(3) and 5HT(2A) receptor binding to clinical efficacy. We selected positron emission tomography (PET) and single photon emission computed tomography (SPECT) studies of antipsychotic dose vs occupancy at both temporal cortex and striatal D(2)/D(3) receptors. We selected corresponding SPECT and PET studies of 5HT(2A) receptor occupancy. We also selected randomized double-blind clinical trials of antipsychotics, where patients were treated with randomly assigned fixed doses. For each antipsychotic drug, we compared the optimum effective antipsychotic dose with the dose inducing maximal occupancy of D(2)/D(3) receptors in striatum and in temporal cortex as well as at 5HT(2A) receptors. Both first- and second-generation antipsychotic (FGA, SGA) drugs produced high temporal cortex D(2)/D(3) occupancy. Only FGA produced high striatal D(2)/D(3) receptor occupancy. The clinically effective dose showed correlation with doses inducing maximal dopamine D(2)/D(3) receptor occupancy both in striatum and in temporal cortex, the strongest correlation being with temporal cortex binding. Extrapyramidal side effects (EPSE) were primarily related to striatal D(2)/D(3) receptor occupancy. There was no correlation between 5HT(2A) occupancy and clinically effective dose. We conclude that cortical dopamine D(2)/D(3) receptor occupancy is involved in antipsychotic efficacy, with striatal D(2)/D(3) occupancy having a likely therapeutic role while also inducing EPSE. We found no evidence for 5HT(2A) blockade involvement in antipsychotic action, although we cannot exclude this possibility.