Carcinogenicity studies were conducted in C57BL mice and Wistar rats. Quetiapine was administered in the diet to mice at doses of 20, 75, 250, and 750 mg/kg and to rats by gavage at doses of 25, 75, and 250 mg/kg for two years. These doses are equivalent to 0.1, 0.5, 1.5, and 4.5 times the MRHD of 800 mg/day based on mg/m 2 body surface area (mice) or 0.3, 1, and 3 times the MRHD based on mg/m 2 body surface area (rats). There were statistically significant increases in thyroid gland follicular adenomas in male mice at doses 1.5 and 4.5 times the MRHD based on mg/m 2 body surface area and in male rats at a dose of 3 times the MRHD based on mg/m 2 body surface area. Mammary gland adenocarcinomas were statistically significantly increased in female rats at all doses tested (0.3, 1, and 3 times the MRHD based on mg/m 2 body surface area).
Thyroid follicular cell adenomas may have resulted from chronic stimulation of the thyroid gland by thyroid stimulating hormone (TSH) resulting from enhanced metabolism and clearance of thyroxine by rodent liver. Changes in TSH, thyroxine, and thyroxine clearance consistent with this mechanism were observed in subchronic toxicity studies in rat and mouse and in a 1-year toxicity study in rat; however, the results of these studies were not definitive. The relevance of the increases in thyroid follicular cell adenomas to human risk, through whatever mechanism, is unknown.
Antipsychotic drugs have been shown to chronically elevate prolactin levels in rodents. Serum measurements in a 1-year toxicity study showed that quetiapine increased median serum prolactin levels a maximum of 32- and 13-fold in male and female rats, respectively. Increases in mammary neoplasms have been found in rodents after chronic administration of other antipsychotic drugs and are considered to be prolactin-mediated. The relevance of this increased incidence of prolactin-mediated mammary gland tumors in rats to human risk is unknown [see Warnings and Precautions ( 5.15)] .
Quetiapine was not mutagenic or clastogenic in standard genotoxicity tests. The mutagenic potential of quetiapine was tested in the in vitro Ames bacterial gene mutation assay and in the in vitro mammalian gene mutation assay in Chinese Hamster Ovary cells. The clastogenic potential of quetiapine was tested in the in vitro chromosomal aberration assay in cultured human lymphocytes and in the in vivo bone marrow micronucleus assay in rats up to 500 mg/kg which is 6 times the MRHD based on mg/m 2 body surface area.
Impairment of Fertility
Quetiapine decreased mating and fertility in male Sprague-Dawley rats at oral doses of 50 and 150 mg/kg or approximately 1 and 3 times the MRHD of 800 mg/day based on mg/m 2 body surface area. Drug-related effects included increases in interval to mate and in the number of matings required for successful impregnation. These effects continued to be observed at 3 times the MRHD even after a two-week period without treatment. The no-effect dose for impaired mating and fertility in male rats was 25 mg/kg, or 0.3 times the MRHD based on mg/m 2 body surface area. Quetiapine adversely affected mating and fertility in female Sprague-Dawley rats at an oral dose approximately 1 times the MRHD of 800 mg/day based on mg/m 2 body surface area. Drug-related effects included decreases in matings and in matings resulting in pregnancy, and an increase in the interval to mate. An increase in irregular estrus cycles was observed at doses of 10 and 50 mg/kg, or approximately 0.1 and 1 times the MRHD of 800 mg/day based on mg/m 2 body surface area. The no-effect dose in female rats was 1 mg/kg, or 0.01 times the MRHD of 800 mg/day based on mg/m 2 body surface area.
Quetiapine caused a dose-related increase in pigment deposition in thyroid gland in rat toxicity studies which were 4 weeks in duration or longer and in a mouse 2-year carcinogenicity study. Doses were 10, 25, 50, 75, 150 and 250 mg/kg in rat studies which are approximately 0.1, 0.3, 0.6, 1, 2 and 3-times the MRHD of 800 mg/day based on mg/m 2 body surface area, respectively. Doses in the mouse carcinogenicity study were 20, 75, 250 and 750 mg/kg which are approximately 0.1, 0.5, 1.5 and 4.5 times the MRHD of 800 mg/day based on mg/m 2 body surface area. Pigment deposition was shown to be irreversible in rats. The identity of the pigment could not be determined, but was found to be co-localized with quetiapine in thyroid gland follicular epithelial cells. The functional effects and the relevance of this finding to human risk are unknown.
In dogs receiving quetiapine for 6 or 12 months, but not for 1-month, focal triangular cataracts occurred at the junction of posterior sutures in the outer cortex of the lens at a dose of 100 mg/kg, or 4 times the MRHD of 800 mg/day based on mg/m 2 body surface area. This finding may be due to inhibition of cholesterol biosynthesis by quetiapine. Quetiapine caused a dose-related reduction in plasma cholesterol levels in repeat-dose dog and monkey studies; however, there was no correlation between plasma cholesterol and the presence of cataracts in individual dogs. The appearance of delta-8-cholestanol in plasma is consistent with inhibition of a late stage in cholesterol biosynthesis in these species. There also was a 25% reduction in cholesterol content of the outer cortex of the lens observed in a special study in quetiapine treated female dogs. Drug-related cataracts have not been seen in any other species; however, in a 1-year study in monkeys, a striated appearance of the anterior lens surface was detected in 2/7 females at a dose of 225 mg/kg or 5.5 times the MRHD of 800 mg/day based on mg/m 2 body surface area.
The efficacy of quetiapine fumarate in the treatment of schizophrenia was established in 3 short-term (6-week) controlled trials of inpatients with schizophrenia who met DSM III-R criteria for schizophrenia. Although a single fixed dose haloperidol arm was included as a comparative treatment in one of the three trials, this single haloperidol dose group was inadequate to provide a reliable and valid comparison of quetiapine fumarate and haloperidol.
Several instruments were used for assessing psychiatric signs and symptoms in these studies, among them the Brief Psychiatric Rating Scale (BPRS), a multi-item inventory of general psychopathology traditionally used to evaluate the effects of drug treatment in schizophrenia. The BPRS psychosis cluster (conceptual disorganization, hallucinatory behavior, suspiciousness, and unusual thought content) is considered a particularly useful subset for assessing actively psychotic schizophrenic patients. A second traditional assessment, the Clinical Global Impression (CGI), reflects the impression of a skilled observer, fully familiar with the manifestations of schizophrenia, about the overall clinical state of the patient.
The results of the trials follow:
1. In a 6-week, placebo-controlled trial (n=361) (Study 1) involving 5 fixed doses of quetiapine fumarate (75 mg/day, 150 mg/day, 300 mg/day, 600 mg/day and 750 mg/day given in divided doses three times per day), the 4 highest doses of quetiapine fumarate were generally superior to placebo on the BPRS total score, the BPRS psychosis cluster and the CGI severity score, with the maximal effect seen at 300 mg/day, and the effects of doses of 150 mg/day to 750 mg/day were generally indistinguishable.
2. In a 6-week, placebo-controlled trial (n=286) (Study 2) involving titration of quetiapine fumarate in high (up to 750 mg/day given in divided doses three times per day) and low (up to 250 mg/day given in divided doses three times per day) doses, only the high dose quetiapine fumarate group (mean dose, 500 mg/day) was superior to placebo on the BPRS total score, the BPRS psychosis cluster, and the CGI severity score.
3. In a 6-week dose and dose regimen comparison trial (n=618) (Study 3) involving two fixed doses of quetiapine fumarate (450 mg/day given in divided doses both twice daily and three times daily and 50 mg/day given in divided doses twice daily), only the 450 mg/day (225 mg given twice daily) dose group was superior to the 50 mg/day (25 mg given twice daily) quetiapine fumarate dose group on the BPRS total score, the BPRS psychosis cluster, and the CGI severity score.
The primary efficacy results of these three studies in the treatment of schizophrenia in adults is presented in Table 19.
Examination of population subsets (race, gender, and age) did not reveal any differential responsiveness on the basis of race or gender, with an apparently greater effect in patients under the age of 40 years compared to those older than 40. The clinical significance of this finding is unknown.
Adolescents (ages 13 to 17)
The efficacy of quetiapine fumarate in the treatment of schizophrenia in adolescents (13 to 17 years of age) was demonstrated in a 6-week, double-blind, placebo-controlled trial (Study 4). Patients who met DSM-IV diagnostic criteria for schizophrenia were randomized into one of three treatment groups: quetiapine fumarate 400 mg/day (n=73), quetiapine fumarate 800 mg/day (n=74), or placebo (n=75). Study medication was initiated at 50 mg/day and on day 2 increased to 100 mg/per day (divided and given two or three times per day). Subsequently, the dose was titrated to the target dose of 400 mg/day or 800 mg/day using increments of 100 mg/day, divided and given two or three times daily. The primary efficacy variable was the mean change from baseline in total Positive and Negative Syndrome Scale (PANSS).
Quetiapine fumarate at 400 mg/day and 800 mg/day was superior to placebo in the reduction of PANSS total score. The primary efficacy results of this study in the treatment of schizophrenia in adolescents is presented in Table 19.
SD: standard deviation; SE: standard error; LS Mean: least-squares mean; CI: unadjusted confidence interval.
1. Difference (drug minus placebo) in least-squares mean change from baseline.
2. Doses that are statistically significant superior to placebo.
3. Doses that are statistically significant superior to quetiapine tablets 50 mg BID.
|Study Number||Treatment Group||Primary Efficacy Endpoint: BPRS Total|
|Mean Baseline Score (SD)||LS Mean Change from Baseline (SE)||Placebo-subtracted Difference 1 (95% CI)|
|Study 1||Quetiapine fumarate (75 mg/day)||45.7 (10.9)||-2.2 (2.0)||-4.0 (-11.2, 3.3)|
|Quetiapine fumarate (150 mg/day) 2||47.2 (10.1)||-8.7 (2.1)||-10.4 (-17.8, -3.0)|
|Quetiapine fumarate (300 mg/day) 2||45.3 (10.9)||-8.6 (2.1)||-10.3 (-17.6, -3.0)|
|Quetiapine fumarate (600 mg/day) 2||43.5 (11.3)||-7.7 (2.1)||-9.4 (-16.7, -2.1)|
|Quetiapine fumarate (750 mg/day) 2||45.7 (11.0)||-6.3 (2.0)||-8.0 (-15.2, -0.8)|
|Placebo||45.3 (9.2)||1.7 (2.1)||—|
|Study 2||Quetiapine fumarate (250 mg/day)||38.9 (9.8)||-4.2 (1.6)||-3.2 (-7.6, 1.2)|
|Quetiapine fumarate (750 mg/day) 2||41.0 (9.6)||-8.7 (1.6)||-7.8 (-12.2, -3.4)|
|Placebo||38.4 (9.7)||-1.0 (1.6)||—|
|Study 3||Quetiapine fumarate (450 mg/day BID)||42.1 (10.7)||-10.0 (1.3)||-4.6 (-7.8, -1.4)|
|Quetiapine fumarate (450 mg/day TID) 3||42.7 (10.4)||-8.6 (1.3)||-3.2 (-6.4, 0.0)|
|Quetiapine fumarate (50 mg BID)||41.7 (10.0)||-5.4 (1.3)||—|
|Primary Efficacy Endpoint: PANSS Total|
|Mean Baseline Score (SD)||LS Mean Change from Baseline (SE)||Placebo-subtracted Difference 1 (95% CI)|
|Study 4||Quetiapine fumarate (400 mg/day) 2||96.2 (17.7)||-27.3 (2.6)||-8.2 (-16.1, -0.3)|
|Quetiapine fumarate (800 mg/day) 2||96.9 (15.3)||-28.4 (1.8)||-9.3 (-16.2, -2.4)|
|Placebo||96.2 (17.7)||-19.2 (3.0)||—|
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