Source: FDA, National Drug Code (US) Revision Year: 2021
The use of MAOIs intended to treat psychiatric disorders with SYMBYAX or within 5 weeks of stopping treatment with SYMBYAX is contraindicated because of an increased risk of serotonin syndrome. The use of SYMBYAX within 14 days of stopping an MAOI intended to treat psychiatric disorders is also contraindicated [see Dosage and Administration (2.4) and Warnings and Precautions (5.6)].
Starting SYMBYAX in a patient who is being treated with MAOIs such as linezolid or intravenous methylene blue is also contraindicated because of an increased risk of serotonin syndrome [see Dosage and Administration (2.5) and Warnings and Precautions (5.6)].
Pimozide and thioridazine prolong the QT interval. SYMBYAX can increase the levels of pimozide and thioridazine through inhibition of CYP2D6. SYMBYAX can also prolong the QT interval.
Patients with Major Depressive Disorder (MDD), both adult and pediatric, may experience worsening of their depression and/or the emergence of suicidal ideation and behavior (suicidality) or unusual changes in behavior, whether or not they are taking antidepressant medications, and this risk may persist until significant remission occurs. Suicide is a known risk of depression and certain other psychiatric disorders, and these disorders themselves are the strongest predictors of suicide. There has been a long-standing concern, however, that antidepressants may have a role in inducing worsening of depression and the emergence of suicidality in certain patients during the early phases of treatment. Pooled analyses of short-term placebo-controlled trials of antidepressant drugs (SSRIs and others) showed that these drugs increase the risk of suicidal thinking and behavior (suicidality) in children, adolescents, and young adults (ages 18 to 24) with Major Depressive Disorder (MDD) and other psychiatric disorders. Short-term studies did not show an increase in the risk of suicidality with antidepressants compared to placebo in adults beyond age 24; there was a reduction with antidepressants compared to placebo in adults aged 65 and older.
The pooled analyses of placebo-controlled trials in children and adolescents with MDD, Obsessive Compulsive Disorder (OCD), or other psychiatric disorders included a total of 24 short-term trials of 9 antidepressant drugs in over 4400 patients. The pooled analyses of placebo-controlled trials in adults with MDD or other psychiatric disorders included a total of 295 short-term trials (median duration of 2 months) of 11 antidepressant drugs in over 77,000 patients. There was considerable variation in risk of suicidality among drugs, but a tendency toward an increase in the younger patients for almost all drugs studied. There were differences in absolute risk of suicidality across the different indications, with the highest incidence in MDD. The risk differences (drug versus placebo), however, were relatively stable within age strata and across indications. These risk differences (drug-placebo difference in the number of cases of suicidality per 1000 patients treated) are provided in Table 1.
Table 1. Suicidality per 1000 Patients Treated:
Age Range | Drug-Placebo Difference in Number of Cases of Suicidality per 1000 Patients Treated |
---|---|
Increases Compared to Placebo | |
<18 | 14 additional cases |
18-24 | 5 additional cases |
Decreases Compared to Placebo | |
25-64 | 1 fewer case |
≥65 | 6 fewer cases |
No suicides occurred in any of the pediatric trials. There were suicides in the adult trials, but the number was not sufficient to reach any conclusion about drug effect on suicide.
It is unknown whether the suicidality risk extends to longer-term use, i.e., beyond several months. However, there is substantial evidence from placebo-controlled maintenance trials in adults with depression that the use of antidepressants can delay the recurrence of depression.
All patients being treated with antidepressants for any indication should be monitored appropriately and observed closely for clinical worsening, suicidality, and unusual changes in behavior, especially during the initial few months of a course of drug therapy, or at times of dose changes, either increases or decreases.
The following symptoms, anxiety, agitation, panic attacks, insomnia, irritability, hostility, aggressiveness, impulsivity, akathisia (psychomotor restlessness), hypomania, and mania, have been reported in adult and pediatric patients being treated with antidepressants for Major Depressive Disorder as well as for other indications, both psychiatric and nonpsychiatric. Although a causal link between the emergence of such symptoms and either the worsening of depression and/or the emergence of suicidal impulses has not been established, there is concern that such symptoms may represent precursors to emerging suicidality.
Consideration should be given to changing the therapeutic regimen, including possibly discontinuing the medication, in patients whose depression is persistently worse, or who are experiencing emergent suicidality or symptoms that might be precursors to worsening depression or suicidality, especially if these symptoms are severe, abrupt in onset, or were not part of the patient’s presenting symptoms.
If the decision has been made to discontinue treatment, medication should be tapered, as rapidly as is feasible, but with recognition that abrupt discontinuation can be associated with certain symptoms [see Warnings and Precautions (5.25)].
Families and caregivers of patients being treated with antidepressants for Major Depressive Disorder or other indications, both psychiatric and nonpsychiatric, should be alerted about the need to monitor patients for the emergence of agitation, irritability, unusual changes in behavior, and the other symptoms described above, as well as the emergence of suicidality, and to report such symptoms immediately to health care providers. Such monitoring should include daily observation by families and caregivers. Prescriptions for SYMBYAX should be written for the smallest quantity of capsules consistent with good patient management, in order to reduce the risk of overdose.
It should be noted that SYMBYAX is not approved for use in treating any indications in patients less than 10 years of age [see Use in Specific Populations (8.4)].
Elderly patients with dementia-related psychosis treated with antipsychotic drugs are at an increased risk of death. SYMBYAX is not approved for the treatment of patients with dementia-related psychosis [see Boxed Warning and Use in Specific Populations (8.5)].
In olanzapine placebo-controlled clinical trials of elderly patients with dementia-related psychosis, the incidence of death in olanzapine-treated patients was significantly greater than placebo-treated patients (3.5% vs 1.5%, respectively).
Elderly patients with dementia-related psychosis treated with antipsychotic drugs are at an increased risk of death. Analyses of seventeen placebo-controlled trials (modal duration of 10 weeks), largely in patients taking atypical antipsychotic drugs, revealed a risk of death in drug-treated patients of between 1.6 to 1.7 times the risk of death in placebo-treated patients. Over the course of a typical 10-week controlled trial, the rate of death in drug-treated patients was about 4.5%, compared to a rate of about 2.6% in the placebo group. Although the causes of death were varied, most of the deaths appeared to be either cardiovascular (e.g., heart failure, sudden death) or infectious (e.g., pneumonia) in nature. Observational studies suggest that, similar to atypical antipsychotic drugs, treatment with conventional antipsychotic drugs may increase mortality. The extent to which the findings of increased mortality in observational studies may be attributed to the antipsychotic drug as opposed to some characteristic(s) of the patients is not clear. SYMBYAX (olanzapine and fluoxetine) is not approved for the treatment of patients with dementia-related psychosis [see Use in Specific Populations (8.5)].
Cerebrovascular adverse events (e.g., stroke, transient ischemic attack), including fatalities, were reported in patients in trials of olanzapine in elderly patients with dementia-related psychosis. In placebo-controlled trials, there was a significantly higher incidence of cerebrovascular adverse events in patients treated with olanzapine compared to patients treated with placebo. Olanzapine and SYMBYAX are not approved for the treatment of patients with dementia-related psychosis [see Boxed Warning].
A potentially fatal symptom complex sometimes referred to as NMS has been reported in association with administration of antipsychotic drugs, including olanzapine. Clinical manifestations of NMS are hyperpyrexia, muscle rigidity, altered mental status, and evidence of autonomic instability (irregular pulse or blood pressure, tachycardia, diaphoresis, and cardiac dysrhythmia). Additional signs may include elevated creatinine phosphokinase, myoglobinuria (rhabdomyolysis), and acute renal failure.
The diagnostic evaluation of patients with this syndrome is complicated. In arriving at a diagnosis, it is important to exclude cases where the clinical presentation includes both serious medical illness (e.g., pneumonia, systemic infection, etc.) and untreated or inadequately treated extrapyramidal signs and symptoms (EPS). Other important considerations in the differential diagnosis include central anticholinergic toxicity, heat stroke, drug fever, and primary central nervous system pathology.
The management of NMS should include: 1) immediate discontinuation of antipsychotic drugs and other drugs not essential to concurrent therapy, 2) intensive symptomatic treatment and medical monitoring, and 3) treatment of any concomitant serious medical problems for which specific treatments are available. There is no general agreement about specific pharmacological treatment regimens for NMS.
If after recovering from NMS, a patient requires treatment with an antipsychotic, the patient should be carefully monitored, since recurrences of NMS have been reported [see Warnings and Precautions (5.5)].
Drug Reaction with Eosinophilia and Systemic Symptoms (DRESS) has been reported with olanzapine exposure. DRESS may present with a cutaneous reaction (such as rash or exfoliative dermatitis), eosinophilia, fever, and/or lymphadenopathy with systemic complications such as hepatitis, nephritis, pneumonitis, myocarditis, and/or pericarditis. DRESS is sometimes fatal. Discontinue SYMBYAX if DRESS is suspected.
Atypical antipsychotic drugs have been associated with metabolic changes including hyperglycemia, dyslipidemia, and weight gain. Metabolic changes may be associated with increased cardiovascular/cerebrovascular risk. Olanzapine’s specific metabolic profile is presented below.
Adults:
Healthcare providers should consider the risks and benefits when prescribing SYMBYAX to patients with an established diagnosis of diabetes mellitus, or having borderline increased blood glucose level (fasting 100-126 mg/dL, nonfasting 140-200 mg/dL). Patients taking SYMBYAX should be monitored regularly for worsening of glucose control. Patients starting treatment with SYMBYAX should undergo fasting blood glucose testing at the beginning of treatment and periodically during treatment. Any patient treated with atypical antipsychotics should be monitored for symptoms of hyperglycemia including polydipsia, polyuria, polyphagia, and weakness. Patients who develop symptoms of hyperglycemia during treatment with atypical antipsychotics should undergo fasting blood glucose testing. In some cases, hyperglycemia has resolved when the atypical antipsychotic was discontinued; however, some patients required continuation of anti-diabetic treatment despite discontinuation of the suspect drug.
Hyperglycemia, in some cases extreme and associated with ketoacidosis or hyperosmolar coma or death, has been reported in patients treated with atypical antipsychotics, including olanzapine alone, as well as olanzapine taken concomitantly with fluoxetine. Assessment of the relationship between atypical antipsychotic use and glucose abnormalities is complicated by the possibility of an increased background risk of diabetes mellitus in patients with schizophrenia and the increasing incidence of diabetes mellitus in the general population. Epidemiological studies suggest an increased risk of treatment-emergent hyperglycemia-related adverse reactions in patients treated with the atypical antipsychotics. While relative risk estimates are inconsistent, the association between atypical antipsychotics and increases in glucose levels appears to fall on a continuum and olanzapine appears to have a greater association than some other atypical antipsychotics.
Mean increases in blood glucose have been observed in patients treated (median exposure of 9.2 months) with olanzapine in phase 1 of the Clinical Antipsychotic Trials of Intervention Effectiveness (CATIE). The mean increase of serum glucose (fasting and nonfasting samples) from baseline to the average of the 2 highest serum concentrations was 15.0 mg/dL.
In a study of healthy volunteers, subjects who received olanzapine (N=22) for 3 weeks had a mean increase compared to baseline in fasting blood glucose of 2.3 mg/dL. Placebo-treated subjects (N=19) had a mean increase in fasting blood glucose compared to baseline of 0.34 mg/dL.
In an analysis of 7 controlled clinical studies, 2 of which were placebo-controlled, with treatment duration up to 12 weeks, SYMBYAX was associated with a greater mean change in random glucose compared to placebo (+8.65 mg/dL vs. -3.86 mg/dL). The difference in mean changes between SYMBYAX and placebo was greater in patients with evidence of glucose dysregulation at baseline (including those patients diagnosed with diabetes mellitus or related adverse reactions, patients treated with anti-diabetic agents, patients with a baseline random glucose level ≥200 mg/dL, or a baseline fasting glucose level ≥126 mg/dL). SYMBYAX-treated patients had a greater mean HbA1c increase from baseline of 0.15% (median exposure 63 days), compared to a mean HbA1c decrease of 0.04% in fluoxetine-treated subjects (median exposure 57 days) and a mean HbA1c increase of 0.12% in olanzapine-treated patients (median exposure 56 days).
In an analysis of 6 controlled clinical studies, a larger proportion of SYMBYAX-treated subjects had glycosuria (4.4%) compared to placebo-treated subjects (1.4%).
The mean change in nonfasting glucose in patients exposed at least 48 weeks was +5.9 mg/dL (N=425).
Table 2 shows short-term and long-term changes in random glucose levels from adult SYMBYAX studies.
Table 2. Changes in Random Glucose Levels from Adult SYMBYAX Studies:
Up to 12 weeks exposure | At least 48 weeks exposure | |||||
---|---|---|---|---|---|---|
Laboratory Analyte | Category Change (at least once) from Baseline | Treatment Arm | N | Patients | N | Patients |
Random Glucose | Normal to High (<140 mg/dL to ≥200 mg/dL) | SYMBYAX | 609 | 2.3% | 382 | 3.1% |
Placebo | 346 | 0.3% | NAa | NAa | ||
Borderline to High (≥140 mg/dL and <200 mg/dL to ≥200 mg/dL) | SYMBYAX | 44 | 34.1% | 27 | 37.0% | |
Placebo | 28 | 3.6% | NAa | NAa |
a Not Applicable.
In a 47-week SYMBYAX study, the mean change from baseline to endpoint in fasting glucose was +4.81 mg/dL (n=130). Table 3 shows the categorical changes in fasting glucose [see Clinical Studies (14.2)].
Table 3. Changes in Fasting Glucose Levels from a Single Adult SYMBYAX Study:
Up to 27 Weeks Exposure (Randomized, Double-Blind Phase) | Up to 47 Weeks Exposure | |||||
---|---|---|---|---|---|---|
Laboratory Analyte | Category Change (at least once) from Baseline | Treatment Arm | N | Patients | N | Patients |
Fasting Glucose | Normal to High (<100 mg/dL to ≥126 mg/dL) | SYMBYAX | 90 | 4.4% | 130 | 11.5% |
Fluoxetine | 96 | 5.2% | NAa | NAa | ||
Borderline to High (≥100 mg/dL and <126 mg/dL to ≥126 mg/dL) | SYMBYAX | 98 | 18.4% | 79 | 32.9% | |
Fluoxetine | 97 | 7.2% | NAa | NAa |
a Not Applicable.
Controlled fasting glucose data is limited for SYMBYAX; however, in an analysis of 5 placebo-controlled olanzapine monotherapy studies with treatment duration up to 12 weeks, olanzapine was associated with a greater mean change in fasting glucose levels compared to placebo (+2.76 mg/dL vs. +0.17 mg/dL).
The mean change in fasting glucose for olanzapine-treated patients exposed at least 48 weeks was +4.2 mg/dL (N=487). In analyses of patients who completed 9-12 months of olanzapine therapy, mean change in fasting and nonfasting glucose levels continued to increase over time.
Children and Adolescents:
In a single, 8-week, randomized, placebo-controlled clinical trial investigating SYMBYAX for treatment of bipolar I depression in patients 10 to 17 years of age, there were no clinically meaningful differences observed between SYMBYAX and placebo for mean change in fasting glucose levels. Table 4 shows categorical changes in fasting blood glucose from the pediatric SYMBYAX study.
Table 4. Changes in Fasting Glucose Levels from a Single Pediatric SYMBYAX Study in Bipolar Depression:
Up to 8 weeks exposure | ||||
---|---|---|---|---|
Laboratory Analyte | Category Change (at least once) from Baseline | Treatment Arm | N | Patients |
Fasting Glucose | Normal to High (<100 mg/dL to ≥126 mg/dL) | SYMBYAX | 125 | 4.8% |
Placebo | 65 | 1.5% | ||
Normal/IGTa to High (<126 mg/dL to ≥126 mg/dL) | SYMBYAX | 156 | 5.8% | |
Placebo | 78 | 1.3% | ||
Normal/IGT (<126 mg/dL) to ≥140 mg/dL) | SYMBYAX | 156 | 1.9% | |
Placebo | 78 | 0.0% |
a Impaired Glucose Tolerance.
Olanzapine Monotherapy in Adolescents:
In an analysis of 3 placebo-controlled olanzapine monotherapy studies of adolescent patients, including those with Schizophrenia (6 weeks) or Bipolar I Disorder (manic or mixed episodes) (3 weeks), olanzapine was associated with a greater mean change from baseline in fasting glucose levels compared to placebo (+2.68 mg/dL vs -2.59 mg/dL). The mean change in fasting glucose for adolescents exposed at least 24 weeks was +3.1 mg/dL (N=121). Table 5 shows short-term and long-term changes in fasting blood glucose from adolescent olanzapine monotherapy studies.
Table 5. Changes in Fasting Glucose Levels from Adolescent Olanzapine Monotherapy Studies:
Up to 12 weeks exposure | At least 24 weeks exposure | |||||
---|---|---|---|---|---|---|
Laboratory Analyte | Category Change (at least once) from Baseline | Treatment Arm | N | Patients | N | Patients |
Fasting Glucose | Normal to High (<100 mg/dL to ≥126 mg/dL) | Olanzapine | 124 | 0% | 108 | 0.9% |
Placebo | 53 | 1.9% | NAa | NAa | ||
Borderline to High (≥100 mg/dL and <126 mg/dL to ≥126 mg/dL) | Olanzapine | 14 | 14.3% | 13 | 23.1% | |
Placebo | 13 | 0% | NAa | NAa |
a Not Applicable.
Undesirable alterations in lipids have been observed with SYMBYAX use. Clinical monitoring, including baseline and periodic follow-up lipid evaluations in patients using SYMBYAX, is recommended.
Adults:
Clinically meaningful, and sometimes very high (>500 mg/dL), elevations in triglyceride levels have been observed with SYMBYAX use. Clinically meaningful increases in total cholesterol have also been seen with SYMBYAX use.
In an analysis of 7 controlled clinical studies, 2 of which were placebo-controlled, with treatment duration up to 12 weeks, SYMBYAX-treated patients had an increase from baseline in mean random total cholesterol of 12.1 mg/dL compared to an increase from baseline in mean random total cholesterol of 4.8 mg/dL for olanzapine-treated patients and a decrease in mean random total cholesterol of 5.5 mg/dL for placebo-treated patients. Table 6 shows categorical changes in nonfasting lipid values.
In long-term olanzapine and fluoxetine in combination studies (at least 48 weeks), changes (at least once) in nonfasting total cholesterol from normal at baseline to high occurred in 12% (N=150) and changes from borderline to high occurred in 56.6% (N=143) of patients. The mean change in nonfasting total cholesterol was 11.3 mg/dL (N=426).
Table 6. Changes in Nonfasting Lipids Values from Controlled Clinical Studies with Treatment Duration up to 12 Weeks:
Laboratory Analyte | Category Change (at least once) from Baseline | Treatment Arm | N | Patients |
---|---|---|---|---|
Nonfasting Triglycerides | Increase by ≥50 mg/dL | SYMBYAX | 174 | 67.8% |
Olanzapine | 172 | 72.7% | ||
Normal to High (<150 mg/dL to ≥500 mg/dL) | SYMBYAX | 57 | 0% | |
Olanzapine | 58 | 0% | ||
Borderline to High (≥150 mg/dL and <500 mg/dL to ≥500 mg/dL) | SYMBYAX | 106 | 15.1% | |
Olanzapine | 103 | 8.7% | ||
Nonfasting Total Cholesterol | Increase by ≥40 mg/dL | SYMBYAX | 685 | 35% |
Olanzapine | 749 | 22.7% | ||
Placebo | 390 | 9% | ||
Normal to High (<200 mg/dL to ≥240 mg/dL) | SYMBYAX | 256 | 8.2% | |
Olanzapine | 279 | 2.9% | ||
Placebo | 175 | 1.7% | ||
Borderline to High (≥200 mg/dL and <240 mg/dL to ≥240 mg/dL) | SYMBYAX | 213 | 36.2% | |
Olanzapine | 261 | 27.6% | ||
Placebo | 111 | 9.9% |
A 47-week SYMBYAX study demonstrated mean changes from baseline to endpoint in fasting total cholesterol (+1.24 mg/dL), LDL cholesterol (+0.29 mg/dL), direct HDL cholesterol (-2.13 mg/dL), and triglycerides (+11.33 mg/dL). Table 7 shows the categorical changes in fasting lipids [see Clinical Studies (14.2)].
Table 7. Changes in Fasting Lipids Values from a Controlled Study with SYMBYAX Treatment Duration up to 47 Weeks:
Up to 27 Weeks Treatment (Randomized, Double-Blind Phase) | Up to 47 Weeks Treatment | |||||
---|---|---|---|---|---|---|
Laboratory Analyte | Category Change (at least once) from Baseline | Treatment Arm | N | Patients | N | Patients |
Fasting Total Cholesterol | Normal to High (<200 mg/dL to ≥240 mg/dL) | SYMBYAX | 47 | 2.1% | 83 | 19.3% |
Fluoxetine | 59 | 3.4% | NAa | NAa | ||
Borderline to High (≥200 and <240 mg/dL to ≥240 mg/dL) | SYMBYAX | 75 | 28.0% | 73 | 69.9% | |
Fluoxetine | 83 | 20.5% | NAa | NAa | ||
Fasting LDL Cholesterol | Normal to High (<100 mg/dL to ≥160 mg/dL) | SYMBYAX | 22 | 4.5% | 46 | 8.7% |
Fluoxetine | 26 | 0% | NAa | NAa | ||
Borderline to High (≥100 mg/dL and <160 mg/dL to ≥160 mg/dL) | SYMBYAX | 115 | 17.4% | 128 | 46.9% | |
Fluoxetine | 134 | 10.4% | NAa | NAa | ||
Fasting HDL Cholesterol | Normal to Low (≥40 mg/dL to <40 mg/dL) | SYMBYAX | 199 | 39.2% | 193 | 45.1% |
Fluoxetine | 208 | 25.5% | NAa | NAa | ||
Fasting Triglycerides | Normal to High (<150 mg/dL to ≥200 mg/dL) | SYMBYAX | 68 | 16.2% | 115 | 46.1% |
Fluoxetine | 74 | 5.4% | NAa | NAa | ||
Borderline to High (≥150 mg/dL and <200 mg/dL to ≥200 mg/dL) | SYMBYAX | 47 | 51.1% | 40 | 72.5% | |
Fluoxetine | 41 | 26.8% | NAa | NAa |
a Not Applicable.
Fasting lipid data is limited for SYMBYAX; however, in an analysis of 5 placebo-controlled olanzapine monotherapy studies with treatment duration up to 12 weeks, olanzapine-treated patients had increases from baseline in mean fasting total cholesterol, LDL cholesterol, and triglycerides of 5.3 mg/dL, 3.0 mg/dL, and 20.8 mg/dL respectively compared to decreases from baseline in mean fasting total cholesterol, LDL cholesterol, and triglycerides of 6.1 mg/dL, 4.3 mg/dL, and 10.7 mg/dL for placebo-treated patients. For fasting HDL cholesterol, no clinically meaningful differences were observed between olanzapine-treated patients and placebo-treated patients. Mean increases in fasting lipid values (total cholesterol, LDL cholesterol, and triglycerides) were greater in patients without evidence of lipid dysregulation at baseline, where lipid dysregulation was defined as patients diagnosed with dyslipidemia or related adverse reactions, patients treated with lipid lowering agents, patients with high baseline lipid levels.
In long-term olanzapine studies (at least 48 weeks), patients had increases from baseline in mean fasting total cholesterol, LDL cholesterol, and triglycerides of 5.6 mg/dL, 2.5 mg/dL, and 18.7 mg/dL, respectively, and a mean decrease in fasting HDL cholesterol of 0.16 mg/dL. In an analysis of patients who completed 12 months of therapy, the mean nonfasting total cholesterol did not increase further after approximately 4-6 months.
The proportion of olanzapine-treated patients who had changes (at least once) in total cholesterol, LDL cholesterol or triglycerides from normal or borderline to high, or changes in HDL cholesterol from normal or borderline to low, was greater in long-term studies (at least 48 weeks) as compared with short-term studies. Table 8 shows categorical changes in fasting lipids values.
Table 8. Changes in Fasting Lipids Values from Adult Olanzapine Monotherapy Studies:
Up to 12 weeks exposure | At least 48 weeks exposure | |||||
---|---|---|---|---|---|---|
Laboratory Analyte | Category Change (at least once) from Baseline | Treatment Arm | N | Patients | N | Patients |
Fasting Triglycerides | Increase by ≥50 mg/dL | Olanzapine | 745 | 39.6% | 487 | 61.4% |
Placebo | 402 | 26.1% | NAa | NAa | ||
Normal to High (<150 mg/dL to ≥200 mg/dL) | Olanzapine | 457 | 9.2% | 293 | 32.4% | |
Placebo | 251 | 4.4% | NAa | NAa | ||
Borderline to High (≥150 mg/dL and <200 mg/dL to ≥200 mg/dL) | Olanzapine | 135 | 39.3% | 75 | 70.7% | |
Placebo | 65 | 20.0% | NAa | NAa | ||
Fasting Total Cholesterol | Increase by ≥40 mg/dL | Olanzapine | 745 | 21.6% | 489 | 32.9% |
Placebo | 402 | 9.5% | NAa | NAa | ||
Normal to High (<200 mg/dL to ≥240 mg/dL) | Olanzapine | 392 | 2.8% | 283 | 14.8% | |
Placebo | 207 | 2.4% | NAa | NAa | ||
Borderline to High (≥200 mg/dL and <240 mg/dL to ≥240 mg/dL) | Olanzapine | 222 | 23.0% | 125 | 55.2% | |
Placebo | 112 | 12.5% | NAa | NAa | ||
Fasting LDL Cholesterol | Increase by ≥30 mg/dL | Olanzapine | 536 | 23.7% | 483 | 39.8% |
Placebo | 304 | 14.1% | NAa | NAa | ||
Normal to High (<100 mg/dL to ≥160 mg/dL) | Olanzapine | 154 | 0% | 123 | 7.3% | |
Placebo | 82 | 1.2% | NAa | NAa | ||
Borderline to High (≥100 mg/dL and <160 mg/dL to ≥160 mg/dL) | Olanzapine | 302 | 10.6% | 284 | 31.0% | |
Placebo | 173 | 8.1% | NAa | NAa |
a Not Applicable.
In phase 1 of the Clinical Antipsychotic Trials of Intervention Effectiveness (CATIE), over a median exposure of 9.2 months, the mean increase in triglycerides in patients taking olanzapine was 40.5 mg/dL. In phase 1 of CATIE, the median increase in total cholesterol was 9.4 mg/dL.
Children and Adolescents:
In a single, 8-week, randomized, placebo-controlled clinical trial investigating SYMBYAX for treatment of bipolar I depression in patients 10 to 17 years of age, there were clinically meaningful and statistically significant differences observed between SYMBYAX and placebo for mean change in fasting total cholesterol (+16.3 mg/dL vs. -4.3 mg/dL, respectively), LDL cholesterol (+9.7 mg/dL vs -3.5 mg/dL, respectively), and triglycerides (+35.4 mg/dL vs. -3.5 mg/dL, respectively).
The magnitude and frequency of changes in lipids were greater in children and adolescents than previously observed in adults. Table 9 shows categorical changes in fasting lipids values from the pediatric SYMBYAX study.
Table 9. Changes in Fasting Lipids Values from a Single Pediatric SYMBYAX Study in Bipolar Depression:
Laboratory Analyte | Category Change (at least once) from Baseline | Treatment Arm | Up to 8 weeks exposure | |
---|---|---|---|---|
N | Patients | |||
Fasting Triglycerides | Increase by ≥50 mg/dL | SYMBYAX | 158 | 70.3% |
Placebo | 81 | 38.3% | ||
Normal to High (<90 mg/dL to ≥130 mg/dL) | SYMBYAX | 71 | 39.4% | |
Placebo | 31 | 19.4% | ||
Borderline to High (≥90 mg/dL and <130 mg/dL to ≥130 mg/dL) | SYMBYAX | 13 | 84.6% | |
Placebo | 12 | 33.3% | ||
Normal/borderline to High (<130 mg/dL to ≥130 mg/dL) | SYMBYAX | 106 | 52.8% | |
Placebo | 56 | 25.0% | ||
Normal to borderline/high (<90 mg/dL to ≥90 mg/dL) | SYMBYAX | 71 | 73.2% | |
Placebo | 31 | 41.9% | ||
Normal/borderline/high to very high (<500 mg/dL to ≥500 mg/dL) | SYMBYAX | 158 | 2.5% | |
Placebo | 81 | 1.2% | ||
Fasting Total Cholesterol | Increase by ≥40 mg/dL | SYMBYAX | 158 | 52.5% |
Placebo | 81 | 8.6% | ||
Normal to High (<170 mg/dL to ≥200 mg/dL) | SYMBYAX | 81 | 12.3% | |
Placebo | 44 | 4.5% | ||
Borderline to High (≥170 mg/dL and <200 mg/dL to ≥200 mg/dL) | SYMBYAX | 22 | 72.7% | |
Placebo | 11 | 24.3% | ||
Normal/borderline to High (<200 mg/dL to ≥200 mg/dL) | SYMBYAX | 126 | 32.5% | |
Placebo | 67 | 10.4% | ||
Normal to borderline/high (<170 mg/dL to ≥170 mg/dL) | SYMBYAX | 81 | 58.0% | |
Placebo | 44 | 31.8% | ||
Fasting LDL Cholesterol | Increase by ≥30 mg/dL | SYMBYAX | 158 | 53.8% |
Placebo | 81 | 23.5% | ||
Normal to High (<110 mg/dL to ≥130 mg/dL) | SYMBYAX | 112 | 13.4% | |
Placebo | 62 | 6.5% | ||
Borderline to High (≥110 mg/dL and <130 mg/dL to ≥130 mg/dL) | SYMBYAX | 12 | 75.0% | |
Placebo | 3 | 0.0% | ||
Normal/borderline to High (<130 mg/dL to ≥130 mg/dL) | SYMBYAX | 138 | 21.7% | |
Placebo | 77 | 7.8% | ||
Normal to borderline/high (<110 mg/dL to ≥110 mg/dL) | SYMBYAX | 112 | 30.4% | |
Placebo | 62 | 14.5% |
Olanzapine Monotherapy in Adolescents:
In an analysis of 3 placebo-controlled olanzapine monotherapy studies of adolescents, including those with Schizophrenia (6 weeks) or Bipolar I Disorder (manic or mixed episodes) (3 weeks), olanzapine-treated adolescents had increases from baseline in mean fasting total cholesterol, LDL cholesterol, and triglycerides of 12.9 mg/dL, 6.5 mg/dL, and 28.4 mg/dL, respectively, compared to increases from baseline in mean fasting total cholesterol and LDL cholesterol of 1.3 mg/dL and 1.0 mg/dL, and a decrease in triglycerides of 1.1 mg/dL for placebo-treated adolescents. For fasting HDL cholesterol, no clinically meaningful differences were observed between olanzapine-treated adolescents and placebo-treated adolescents.
In long-term olanzapine studies (at least 24 weeks), adolescents had increases from baseline in mean fasting total cholesterol, LDL cholesterol, and triglycerides of 5.5 mg/dL, 5.4 mg/dL, and 20.5 mg/dL, respectively, and a mean decrease in fasting HDL cholesterol of 4.5 mg/dL. Table 10 shows categorical changes in fasting lipids values in adolescents.
Table 10. Changes in Fasting Lipids Values from Adolescent Olanzapine Monotherapy Studies:
Laboratory Analyte | Category Change (at least once) from Baseline | Treatment Arm | Up to 6 weeks exposure | At least 24 weeks exposure | ||
---|---|---|---|---|---|---|
N | Patients | N | Patients | |||
Fasting Triglycerides | Increase by ≥50 mg/dL | Olanzapine | 138 | 37.0% | 122 | 45.9% |
Placebo | 66 | 15.2% | NAa | NAa | ||
Normal to High (<90 mg/dL to >130 mg/dL) | Olanzapine | 67 | 26.9% | 66 | 36.4% | |
Placebo | 28 | 10.7% | NAa | NAa | ||
Borderline to High (≥90 mg/dL and ≤130 mg/dL to >130 mg/dL) | Olanzapine | 37 | 59.5% | 31 | 64.5% | |
Placebo | 17 | 35.3% | NAa | NAa | ||
Fasting Total Cholesterol | Increase by ≥40 mg/dL | Olanzapine | 138 | 14.5% | 122 | 14.8% |
Placebo | 66 | 4.5% | NAa | NAa | ||
Normal to High (<170 mg/dL to ≥200 mg/dL) | Olanzapine | 87 | 6.9% | 78 | 7.7% | |
Placebo | 43 | 2.3% | NAa | NAa | ||
Borderline to High (≥170 mg/dL and <200 mg/dL to ≥200 mg/dL) | Olanzapine | 36 | 38.9% | 33 | 57.6% | |
Placebo | 13 | 7.7% | NAa | NAa | ||
Fasting LDL Cholesterol | Increase by ≥30 mg/dL | Olanzapine | 137 | 17.5% | 121 | 22.3% |
Placebo | 63 | 11.1% | NAa | NAa | ||
Normal to High (<110 mg/dL to ≥130 mg/dL) | Olanzapine | 98 | 5.1% | 92 | 10.9% | |
Placebo | 44 | 4.5% | NAa | NAa | ||
Borderline to High (≥110 mg/dL and <130 mg/dL to ≥130 mg/dL) | Olanzapine | 29 | 48.3% | 21 | 47.6% | |
Placebo | 9 | 0% | NAa | NAa |
a Not Applicable.
Potential consequences of weight gain should be considered prior to starting SYMBYAX. Patients receiving SYMBYAX should receive regular monitoring of weight.
Adults:
In an analysis of 7 controlled clinical studies, 2 of which were placebo-controlled, the mean weight increase for SYMBYAX-treated patients was greater than placebo-treated patients [4 kg (8.8 lb) vs -0.3 kg (-0.7 lb)]. Twenty-two percent of SYMBYAX-treated patients gained at least 7% of their baseline weight, with a median exposure to event of 6 weeks. This was greater than in placebo-treated patients (1.8%). Approximately 3% of SYMBYAX-treated patients gained at least 15% of their baseline weight, with a median exposure to event of 8 weeks. This was greater than in placebo-treated patients (0%). Clinically significant weight gain was observed across all baseline Body Mass Index (BMI) categories. Discontinuation due to weight gain occurred in 2.5% of SYMBYAX-treated patients and 0% of placebo-treated patients.
In long-term olanzapine and fluoxetine in combination studies (at least 48 weeks), the mean weight gain was 6.7 kg (14.7 lb) (median exposure of 448 days, N=431). The percentages of patients who gained at least 7%, 15% or 25% of their baseline body weight with long-term exposure were 66%, 33%, and 10%, respectively. Discontinuation due to weight gain occurred in 1.2% of patients treated with olanzapine and fluoxetine in combination following at least 48 weeks of exposure.
Table 11 presents the distribution of weight gain in a single long-term relapse prevention study of patients treated for up to 47 weeks with SYMBYAX [see Clinical Studies (14.2)].
Table 11. Weight Gain with SYMBYAX Use in a Single Relapse Prevention Study in Adults:
Amount Gained kg (lb) | Up to 8 Weeks N=881) (%) | Up to 20 Weeks (N=651) (%) | Up to 47 Weeks (N=220) (%) |
---|---|---|---|
≤0 | 19.8 | 14.9 | 19.1 |
0 to ≤5 (0-11 lb) | 64.1 | 47.2 | 37.7 |
>5 to ≤10 (11-22 lb) | 15.1 | 30.3 | 27.7 |
>10 to ≤15 (22-33 lb) | 0.9 | 5.8 | 10.0 |
>15 to ≤20 (33-44 lb) | 0.1 | 1.2 | 3.2 |
>20 to ≤25 (44-55 lb) | 0.0 | 0.6 | 1.4 |
>25 to ≤30 (55-66 lb) | 0.0 | 0.0 | 0.5 |
>30 (>66 lb) | 0.0 | 0.0 | 0.5 |
In long-term olanzapine studies (at least 48 weeks), the mean weight gain was 5.6 kg (12.3 lb) (median exposure of 573 days, N=2021). The percentages of patients who gained at least 7%, 15%, or 25% of their baseline body weight with long-term exposure were 64%, 32%, and 12%, respectively. Discontinuation due to weight gain occurred in 0.4% of olanzapine-treated patients following at least 48 weeks of exposure.
Table 12 includes data on adult weight gain with olanzapine pooled from 86 clinical trials. The data in each column represent data for those patients who completed treatment periods of the durations specified.
Table 12. Weight Gain with Olanzapine Use in Adults:
Amount Gained kg (lb) | 6 Weeks (N=7465) (%) | 6 Months (N=4162) (%) | 12 Months (N=1345) (%) | 24 Months (N=474) (%) | 36 Months (N=147) (%) |
---|---|---|---|---|---|
≤0 | 26.2 | 24.3 | 20.8 | 23.2 | 17.0 |
0 to ≤5 (0-11 lb) | 57.0 | 36.0 | 26.0 | 23.4 | 25.2 |
>5 to ≤10 (11-22 lb) | 14.9 | 24.6 | 24.2 | 24.1 | 18.4 |
>10 to ≤15 (22-33 lb) | 1.8 | 10.9 | 14.9 | 11.4 | 17.0 |
>15 to ≤20 (33-44 lb) | 0.1 | 3.1 | 8.6 | 9.3 | 11.6 |
>20 to ≤25 (44-55 lb) | 0 | 0.9 | 3.3 | 5.1 | 4.1 |
>25 to ≤30 (55-66 lb) | 0 | 0.2 | 1.4 | 2.3 | 4.8 |
>30 (>66 lb) | 0 | 0.1 | 0.8 | 1.2 | 2 |
Dose group differences with respect to weight gain have been observed. In a single 8-week randomized, double-blind, fixed-dose study comparing 10 (N=199), 20 (N=200) and 40 (N=200) mg/day of oral olanzapine in adult patients with schizophrenia or schizoaffective disorder, mean baseline to endpoint increase in weight (10 mg/day: 1.9 kg; 20 mg/day: 2.3 kg; 40 mg/day: 3 kg) was observed with significant differences between 10 vs 40 mg/day.
Children and Adolescents:
In a single, 8-week, randomized, placebo-controlled clinical trial investigating SYMBYAX for the treatment of bipolar I depression in patients 10 to 17 years of age, SYMBYAX was associated with greater mean change in weight compared to placebo (+4.4 kg vs +0.5 kg, respectively). The percentages of children and adolescents who gained at least 7%, 15%, or 25% of their baseline body weight with 8-week exposure were 52%, 14%, and 1%, respectively. The proportion of patients who had clinically significant weight gain was greater in children and adolescent patients compared to short-term data in adults. Discontinuation due to weight gain occurred in 2.9% of SYMBYAX-treated patients and 0% of placebo-treated patients. Table 13 depicts weight gain observed in the pediatric SYMBYAX study.
Table 13. Weight Gain with SYMBYAX Use Seen in a Single Pediatric Study in Bipolar Depression:
Amount Gained kg (lb) | Up to 8 Weeks (N=170) (%) |
---|---|
≤0 | 7.1 |
0 to ≤5 (0-11 lb) | 54.7 |
>5 to ≤10 (11-22 lb) | 31.2 |
>10 to ≤15 (22-33 lb) | 7.1 |
>15 to ≤20 (33-44 lb) | 0 |
>20 to ≤25 (44-55 lb) | 0 |
>25 to ≤30 (55-66 lb) | 0 |
>30 (>66 lb) | 0 |
Olanzapine Monotherapy in Adolescents:
Mean increase in weight in adolescents was greater than in adults. In 4 placebo-controlled trials, discontinuation due to weight gain occurred in 1% of olanzapine-treated patients, compared to 0% of placebo-treated patients.
Table 14. Weight Gain with Olanzapine Use in Adolescents from 4 Placebo-Controlled Trials:
Olanzapine-treated patients | Placebo-treated patients | |
---|---|---|
Mean change in body weight from baseline (median exposure = 3 weeks) | 4.6 kg (10.1 lb) | 0.3 kg (0.7 lb) |
Percentage of patients who gained at least 7% of baseline body weight | 40.6% (median exposure to 7% = 4 weeks) | 9.8% (median exposure to 7% = 8 weeks) |
Percentage of patients who gained at least 15% of baseline body weight | 7.1% (median exposure to 15% = 19 weeks) | 2.7% (median exposure to 15% = 8 weeks) |
In long-term olanzapine studies (at least 24 weeks), the mean weight gain was 11.2 kg (24.6 lb) (median exposure of 201 days, N=179). The percentages of adolescents who gained at least 7%, 15%, or 25% of their baseline body weight with long-term exposure were 89%, 55%, and 29%, respectively. Among adolescent patients, mean weight gain by baseline BMI category was 11.5 kg (25.3 lb), 12.1 kg (26.6 lb), and 12.7 kg (27.9 lb), respectively, for normal (N=106), overweight (N=26) and obese (N=17). Discontinuation due to weight gain occurred in 2.2% of olanzapine-treated patients following at least 24 weeks of exposure.
Table 15 shows data on adolescent weight gain with olanzapine pooled from 6 clinical trials. The data in each column represent data for those patients who completed treatment periods of the durations specified. Little clinical trial data is available on weight gain in adolescents with olanzapine beyond 6 months of treatment.
Table 15. Weight Gain with Olanzapine Use in Adolescents:
Amount Gained kg (lb) | 6 Weeks (N=243) (%) | 6 Months (N=191) (%) |
---|---|---|
≤0 | 2.9 | 2.1 |
0 to ≤5 (0-11 lb) | 47.3 | 24.6 |
>5 to ≤10 (11-22 lb) | 42.4 | 26.7 |
>10 to ≤15 (22-33 lb) | 5.8 | 22.0 |
>15 to ≤20 (33-44 lb) | 0.8 | 12.6 |
>20 to ≤25 (44-55 lb) | 0.8 | 9.4 |
>25 to ≤30 (55-66 lb) | 0 | 2.1 |
>30 to ≤35 (66-77 lb) | 0 | 0 |
>35 to ≤40 (77-88 lb) | 0 | 0 |
>40 (>88 lb) | 0 | 0.5 |
The development of a potentially life-threatening serotonin syndrome has been reported with SNRIs and SSRIs, including SYMBYAX, alone but particularly with concomitant use of other serotonergic drugs (including triptans, tricyclic antidepressants, fentanyl, lithium, tramadol, tryptophan, buspirone, amphetamines, and St. John’s Wort) and with drugs that impair metabolism of serotonin (in particular, MAOIs, both those intended to treat psychiatric disorders and also others, such as linezolid and intravenous methylene blue).
Serotonin syndrome symptoms may include mental status changes (e.g., agitation, hallucinations, delirium, and coma), autonomic instability (e.g., tachycardia, labile blood pressure, dizziness, diaphoresis, flushing, hyperthermia), neuromuscular symptoms (e.g., tremor, rigidity, myoclonus, hyperreflexia, incoordination), seizures, and/or gastrointestinal symptoms (e.g., nausea, vomiting, diarrhea). Patients should be monitored for the emergence of serotonin syndrome.
The concomitant use of SYMBYAX with MAOIs intended to treat psychiatric disorders is contraindicated. SYMBYAX should also not be started in a patient who is being treated with MAOIs such as linezolid or intravenous methylene blue. All reports with methylene blue that provided information on the route of administration involved intravenous administration in the dose range of 1 mg/kg to 8 mg/kg. No reports involved the administration of methylene blue by other routes (such as oral tablets or local tissue injection) or at lower doses. There may be circumstances when it is necessary to initiate treatment with an MAOI such as linezolid or intravenous methylene blue in a patient taking SYMBYAX. SYMBYAX should be discontinued before initiating treatment with the MAOI [see Dosage and Administration (2.4, 2.5) and Contraindications (4.1)].
If concomitant use of SYMBYAX with other serotonergic drugs including triptans, tricyclic antidepressants, fentanyl, lithium, tramadol, buspirone, tryptophan, amphetamines, and St. John’s Wort is clinically warranted, patients should be made aware of a potential increased risk for serotonin syndrome, particularly during treatment initiation and dose increases.
Treatment with SYMBYAX and any concomitant serotonergic agents should be discontinued immediately if the above events occur and supportive symptomatic treatment should be initiated.
The pupillary dilation that occurs following use of many antidepressant drugs including SYMBYAX may trigger an angle-closure attack in a patient with anatomically narrow angles who does not have a patent iridectomy.
In SYMBYAX premarketing controlled clinical studies, the overall incidence of rash or allergic reactions in SYMBYAX-treated patients [4.6% (26/571)] was similar to that of placebo [5.2% (25/477)]. The majority of the cases of rash and/or urticaria were mild; however, 3 patients discontinued (1 due to rash, which was moderate in severity and 2 due to allergic reactions, 1 of which included face edema).
In fluoxetine US clinical studies, 7% of 10,782 fluoxetine-treated patients developed various types of rashes and/or urticaria. Among the cases of rash and/or urticaria reported in premarketing clinical studies, almost a third were withdrawn from treatment because of the rash and/or systemic signs or symptoms associated with the rash. Clinical findings reported in association with rash include fever, leukocytosis, arthralgias, edema, carpal tunnel syndrome, respiratory distress, lymphadenopathy, proteinuria, and mild transaminase elevation. Most patients improved promptly with discontinuation of fluoxetine and/or adjunctive treatment with antihistamines or steroids, and all patients experiencing these reactions were reported to recover completely.
In fluoxetine premarketing clinical studies, 2 patients are known to have developed a serious cutaneous systemic illness. In neither patient was there an unequivocal diagnosis, but 1 was considered to have a leukocytoclastic vasculitis, and the other, a severe desquamating syndrome that was considered variously to be a vasculitis or erythema multiforme. Other patients have had systemic syndromes suggestive of serum sickness.
Since the introduction of fluoxetine, systemic reactions, possibly related to vasculitis, have developed in patients with rash. Although these reactions are rare, they may be serious, involving the lung, kidney, or liver. Death has been reported to occur in association with these systemic reactions.
Anaphylactoid reactions, including bronchospasm, angioedema, and urticaria alone and in combination, have been reported.
Pulmonary reactions, including inflammatory processes of varying histopathology and/or fibrosis, have been reported rarely. These reactions have occurred with dyspnea as the only preceding symptom.
Whether these systemic reactions and rash have a common underlying cause or are due to different etiologies or pathogenic processes is not known. Furthermore, a specific underlying immunologic basis for these reactions has not been identified. Upon the appearance of rash or of other possible allergic phenomena for which an alternative etiology cannot be identified, SYMBYAX should be discontinued.
A major depressive episode may be the initial presentation of Bipolar Disorder. It is generally believed (though not established in controlled trials) that treating such an episode with an antidepressant alone may increase the likelihood of precipitation of a manic episode in patients at risk for Bipolar Disorder. Whether any of the symptoms described for clinical worsening and suicide risk represent such a conversion is unknown. However, prior to initiating treatment with an antidepressant, patients with depressive symptoms should be adequately screened to determine if they are at risk for Bipolar Disorder; such screening should include a detailed psychiatric history, including a family history of suicide, Bipolar Disorder, and depression. It should be noted that SYMBYAX is approved for the acute treatment of depressive episodes associated with Bipolar I Disorder.
In the 3 controlled bipolar depression studies (2 in adults and 1 in children and adolescents [10 to 17 years of age]) there was no statistically significant difference in the incidence of manic reactions (manic reaction or manic depressive reaction) between SYMBYAX- and placebo-treated patients. In 1 adult study, the incidence of manic reactions was (7% [3/43]) in SYMBYAX-treated patients compared to (3% [5/184]) in placebo-treated patients. In the other adult study, the incidence of manic reactions was (2% [1/43]) in SYMBYAX-treated patients compared to (8% [15/193]) in placebo-treated patients. In a single, 8-week, randomized, placebo-controlled clinical trial investigating SYMBYAX for the treatment of bipolar I depression in patients 10 to 17 years of age, the incidence of manic reactions was (1% [2/170]) in SYMBYAX-treated patients compared to (0% [0/84]) in placebo-treated patients. Because of the cyclical nature of Bipolar I Disorder, patients should be monitored closely for the development of symptoms of mania/hypomania during treatment with SYMBYAX.
A syndrome of potentially irreversible, involuntary, dyskinetic movements may develop in patients treated with antipsychotic drugs. Although the prevalence of the syndrome appears to be highest among the elderly, especially elderly women, it is impossible to rely upon prevalence estimates to predict, at the inception of antipsychotic treatment, which patients are likely to develop the syndrome. Whether antipsychotic drug products differ in their potential to cause tardive dyskinesia is unknown.
The risk of developing tardive dyskinesia and the likelihood that it will become irreversible are believed to increase as the duration of treatment and the total cumulative dose of antipsychotic drugs administered to the patient increase. However, the syndrome can develop, although much less commonly, after relatively brief treatment periods at low doses or may even arise after discontinuation of treatment.
Tardive dyskinesia may remit, partially or completely, if antipsychotic treatment is withdrawn. Antipsychotic treatment itself, however, may suppress (or partially suppress) the signs and symptoms of the syndrome and thereby may possibly mask the underlying process. The effect that symptomatic suppression has upon the long-term course of the syndrome is unknown.
The incidence of dyskinetic movement in SYMBYAX-treated patients was infrequent. The mean score on the Abnormal Involuntary Movement Scale (AIMS) in the SYMBYAX-controlled database across clinical studies involving SYMBYAX-treated patients decreased from baseline. Nonetheless, SYMBYAX should be prescribed in a manner that is most likely to minimize the risk of tardive dyskinesia. If signs and symptoms of tardive dyskinesia appear in a patient on SYMBYAX, drug discontinuation should be considered. However, some patients may require treatment with SYMBYAX despite the presence of the syndrome. The need for continued treatment should be reassessed periodically.
SYMBYAX may induce orthostatic hypotension associated with dizziness, tachycardia, bradycardia, and in some patients, syncope, especially during the initial dose-titration period.
In the SYMBYAX-controlled clinical trials across all indications, there were no significant differences between SYMBYAX-treated patients and olanzapine, fluoxetine- or placebo-treated patients in exposure-adjusted rates of orthostatic systolic blood pressure decreases of at least 30 mm Hg. Orthostatic systolic blood pressure decreases of at least 30 mm Hg occurred in 4.0% (28/705), 2.3% (19/831), 4.5% (18/399), and 1.8% (8/442) of the SYMBYAX, olanzapine, fluoxetine, and placebo groups, respectively. In this group of studies, the incidence of syncope-related adverse reactions (i.e., syncope and/or loss of consciousness) in SYMBYAX-treated patients was 0.4% (3/771) compared to placebo 0.2% (1/477).
In a clinical pharmacology study of SYMBYAX, 3 healthy subjects were discontinued from the trial after experiencing severe, but self-limited, hypotension and bradycardia that occurred 2 to 9 hours following a single 12 mg/50 mg dose of SYMBYAX. Reactions consisting of this combination of hypotension and bradycardia (and also accompanied by sinus pause) have been observed in at least 3 other healthy subjects treated with various formulations of olanzapine (1 oral, 2 intramuscular). In controlled clinical studies, the incidence of patients with a ≥20 bpm decrease in orthostatic pulse concomitantly with a ≥20 mm Hg decrease in orthostatic systolic blood pressure was 0.3% (2/706) in the SYMBYAX group, 0.2% (1/445) in the placebo group, 0.7% (6/837) in the olanzapine group, and 0% (0/404) in the fluoxetine group.
SYMBYAX should be used with particular caution in patients with known cardiovascular disease (history of myocardial infarction or ischemia, heart failure, or conduction abnormalities), cerebrovascular disease, or conditions that would predispose patients to hypotension (dehydration, hypovolemia, and treatment with antihypertensive medications).
SYMBYAX may cause somnolence, postural hypotension, motor and sensory instability, which may lead to falls and, consequently, fractures or other injuries. For patients with diseases, conditions, or medications that could exacerbate these effects, complete fall risk assessments when initiating antipsychotic treatment and recurrently for patients on long-term antipsychotic therapy.
In clinical trial and/or postmarketing experience, events of leukopenia/neutropenia have been reported temporally related to antipsychotic agents, including SYMBYAX. Agranulocytosis has also been reported.
Possible risk factors for leukopenia/neutropenia include preexisting low white blood cell count (WBC) and history of drug induced leukopenia/neutropenia. Patients with a history of a clinically significant low WBC or drug induced leukopenia/neutropenia should have their complete blood count (CBC) monitored frequently during the first few months of therapy and discontinuation of SYMBYAX should be considered at the first sign of a clinically significant decline in WBC in the absence of other causative factors.
Patients with clinically significant neutropenia should be carefully monitored for fever or other symptoms or signs of infection and treated promptly if such symptoms or signs occur. Patients with severe neutropenia (absolute neutrophil count <1000/mm³) should discontinue SYMBYAX and have their WBC followed until recovery.
Esophageal dysmotility and aspiration have been associated with antipsychotic drug use. Aspiration pneumonia is a common cause of morbidity and mortality in patients with advanced Alzheimer’s disease. SYMBYAX is not approved for the treatment of patients with Alzheimer’s disease.
Seizures occurred in 0.2% (4/2547) of SYMBYAX-treated patients during open-label clinical studies. No seizures occurred in the controlled SYMBYAX studies. Seizures have also been reported with both olanzapine and fluoxetine monotherapy. SYMBYAX should be used cautiously in patients with a history of seizures or with conditions that potentially lower the seizure threshold, e.g., Alzheimer’s dementia. SYMBYAX is not approved for the treatment of patients with Alzheimer’s disease. Conditions that lower the seizure threshold may be more prevalent in a population of ≥65 years of age.
SNRIs and SSRIs, including fluoxetine, may increase the risk of bleeding reactions. Concomitant use of aspirin, nonsteroidal anti-inflammatory drugs, warfarin, and other anti-coagulants may add to this risk. Case reports and epidemiological studies (case-control and cohort design) have demonstrated an association between use of drugs that interfere with serotonin reuptake and the occurrence of gastrointestinal bleeding. Bleeding reactions related to SNRIs and SSRIs use have ranged from ecchymoses, hematomas, epistaxis, and petechiae to life-threatening hemorrhages.
Patients should be cautioned about the risk of bleeding associated with the concomitant use of SYMBYAX and NSAIDs, aspirin, or other drugs that affect coagulation [see Drug Interactions (7.4)].
Hyponatremia has been reported during treatment with SNRIs and SSRIs, including fluoxetine and SYMBYAX. In many cases, this hyponatremia appears to be the result of the syndrome of inappropriate antidiuretic hormone secretion (SIADH). Cases with serum sodium lower than 110 mmol/L have been reported and appeared to be reversible when [see Use in Specific Populations (8.5)]. SYMBYAX was discontinued. Elderly patients may be at greater risk of developing hyponatremia with SNRIs and SSRIs. Also, patients taking diuretics or who are otherwise volume depleted may be at greater risk. Discontinuation of SYMBYAX should be considered in patients with symptomatic hyponatremia and appropriate medical intervention should be instituted.
Signs and symptoms of hyponatremia include headache, difficulty concentrating, memory impairment, confusion, weakness, and unsteadiness, which may lead to falls. More severe and/or acute cases have been associated with hallucination, syncope, seizure, coma, respiratory arrest, and death.
SYMBYAX has the potential to impair judgment, thinking, or motor skills. Patients should be cautioned about operating hazardous machinery, including automobiles, until they are reasonably certain that SYMBYAX therapy does not affect them adversely.
Sedation-related adverse reactions were commonly reported with SYMBYAX treatment occurring at an incidence of 26.6% in SYMBYAX-treated patients compared with 10.9% in placebo-treated patients. Sedation-related adverse reactions (sedation, somnolence, hypersomnia, and lethargy) led to discontinuation in 2% (15/771) of patients in the controlled clinical studies.
In a single, 8-week, randomized, placebo-controlled clinical trial investigating SYMBYAX for the treatment of bipolar I depression in patients 10 to 17 years of age, somnolence-related adverse events were commonly reported with SYMBYAX treatment occurring at an incidence of 23.5% in SYMBYAX-treated patients compared with 2.4% in placebo-treated patients. Somnolence-related adverse events led to discontinuation in 1.2% (2/170) of patients.
Disruption of the body’s ability to reduce core body temperature has been attributed to antipsychotic drugs. Appropriate care is advised when prescribing SYMBYAX for patients who will be experiencing conditions which may contribute to an elevation in core body temperature (e.g., exercising strenuously, exposure to extreme heat, receiving concomitant medication with anticholinergic activity, or being subject to dehydration).
Post-marketing cases of QT interval prolongation and ventricular arrhythmia including Torsade de Pointes have been reported in patients treated with fluoxetine. SYMBYAX should be used with caution in patients with congenital long QT syndrome; a previous history of QT prolongation; a family history of long QT syndrome or sudden cardiac death; and other conditions that predispose to QT prolongation and ventricular arrhythmia. Such conditions include concomitant use of drugs that prolong the QT interval; hypokalemia or hypomagnesemia; recent myocardial infarction, uncompensated heart failure, bradyarrhythmias, and other significant arrhythmias; and conditions that predispose to increased fluoxetine exposure (overdose, hepatic impairment, use of CYP2D6 inhibitors, CYP2D6 poor metabolizer status, or use of other highly protein-bound drugs). Fluoxetine is primarily metabolized by CYP2D6 [see Contraindications (4.2), Adverse Reactions (6), Drug Interactions (7.7, 7.8), Overdosage (10.1), and Clinical Pharmacology (12.3)].
Pimozide and thioridazine are contraindicated for use with SYMBYAX. Avoid the concomitant use of drugs known to prolong the QT interval. These include specific antipsychotics (e.g., ziprasidone, iloperidone, chlorpromazine, mesoridazine, droperidol); specific antibiotics (e.g., erythromycin, gatifloxacin, moxifloxacin, sparfloxacin); Class 1A antiarrhythmic medications (e.g., quinidine, procainamide); Class III antiarrhythmics (e.g., amiodarone, sotalol); and others (e.g., pentamidine, levomethadyl acetate, methadone, halofantrine, mefloquine, dolasetron mesylate, probucol or tacrolimus) [see Drug Interactions (7.7, 7.8) and Clinical Pharmacology (12.3)].
Consider ECG assessment and periodic ECG monitoring if initiating treatment with SYMBYAX in patients with risk factors for QT prolongation and ventricular arrhythmia. Consider discontinuing SYMBYAX and obtaining a cardiac evaluation if patients develop signs or symptoms consistent with ventricular arrhythmia.
In a single, 8-week, randomized, placebo-controlled clinical trial investigating SYMBYAX for the treatment of bipolar I depression in patients 10 to 17 years of age, there was a statistically significant difference in QTc interval for patients treated with SYMBYAX compared with patients on placebo: mean change in QTcF (Fridericia correction factor) from baseline to endpoint in patients treated with SYMBYAX was 8.2 msec (95% CI 6.2, 10.2). No patient developed QTc increases ≥60 msec or QTc ≥480 msec. Clinicians should use SYMBYAX with caution in those children or adolescents who are known to be particularly at risk for QT prolongation [see Adverse Reactions (6.1)].
The following precautions for the individual components may be applicable to SYMBYAX.
Olanzapine exhibits in vitro muscarinic receptor affinity. In premarketing clinical studies, SYMBYAX was associated with constipation, dry mouth, and tachycardia, all adverse reactions possibly related to cholinergic antagonism. Such adverse reactions were not often the basis for study discontinuations; SYMBYAX should be used with caution in patients with a current diagnosis or prior history of urinary retention, clinically significant prostatic hypertrophy, constipation, a history of paralytic ileus, or related conditions.
As with other drugs that antagonize dopamine D2 receptors, SYMBYAX elevates prolactin levels, and the elevation persists during administration. Hyperprolactinemia may suppress hypothalamic GnRH, resulting in reduced pituitary gonadotropin secretion. This, in turn, may inhibit reproductive function by impairing gonadal steroidogenesis in both female and male patients. Galactorrhea, amenorrhea, gynecomastia, and erectile dysfunction have been reported in patients receiving prolactin-elevating compounds. Long-standing hyperprolactinemia when associated with hypogonadism may lead to decreased bone density in both female and male subjects.
Tissue culture experiments indicate that approximately one-third of human breast cancers are prolactin dependent in vitro, a factor of potential importance if the prescription of these drugs is contemplated in a patient with previously detected breast cancer. As is common with compounds that increase prolactin release, an increase in mammary gland neoplasia was observed in the olanzapine carcinogenicity studies conducted in mice and rats [see Nonclinical Toxicology (13.1)]. Neither clinical studies nor epidemiologic studies conducted to date have shown an association between chronic administration of this class of drugs and tumorigenesis in humans; the available evidence is considered too limited to be conclusive at this time.
In controlled clinical studies of SYMBYAX (up to 12 weeks), changes from normal to high in prolactin concentrations were observed in 28% of adults treated with SYMBYAX as compared to 5% of placebo-treated patients. The elevations persisted throughout administration of SYMBYAX. In a pooled analysis from clinical studies including 2929 adults treated with SYMBYAX, potentially associated clinical manifestations included menstrual-related events1 (1% [20/1946] of females), sexual function-related events2 (7% [192/2929] of females and males), and breast-related events3 (0.8% [16/1946] of females, 0.2% [2/983] of males).
In a single, 8-week, randomized, placebo-controlled clinical trial investigating SYMBYAX for the treatment of bipolar I depression in patients 10 to 17 years of age, SYMBYAX was associated with a statistically significant greater mean change from baseline in prolactin levels compared to placebo (8.7 mcg/L vs 0.7 mcg/L, respectively). Although prolactin concentrations were very commonly (>10%) elevated above normal in both the SYMBYAX and placebo groups, more than twice as many SYMBYAX-treated patients were seen with these elevations compared to placebo-treated patients. Five patients experienced an adverse event potentially associated with elevated prolactin; these events included dysmenorrhea, galactorrhea, and ovulation disorder.
The magnitude and frequency of change in prolactin in children and adolescents was larger than observed in adult patients treated with SYMBYAX, but was similar to that observed in adolescents treated with olanzapine monotherapy.
In placebo-controlled olanzapine clinical studies (up to 12 weeks), changes from normal to high in prolactin concentrations were observed in 30% of adults treated with olanzapine as compared to 10.5% of adults treated with placebo. In a pooled analysis from clinical studies including 8136 adults treated with olanzapine, potentially associated clinical manifestations included menstrual-related events1 (2% [49/3240] of females), sexual function-related events2 (2% [150/8136] of females and males), and breast-related events3 (0.7% [23/3240] of females, 0.2% [9/4896] of males).
In placebo-controlled olanzapine monotherapy studies in adolescent patients (up to 6 weeks) with schizophrenia or bipolar I disorder (manic or mixed episodes), changes from normal to high in prolactin concentrations were observed in 47% of olanzapine-treated patients compared to 7% of placebo-treated patients. In a pooled analysis from clinical trials including 454 adolescents treated with olanzapine, potentially associated clinical manifestations included menstrual-related events1 (1% [2/168] of females), sexual function-related events2 (0.7% [3/454] of females and males), and breast-related events3 (2% [3/168] of females, 2% [7/286] of males), [see Use in Specific Populations (8.4)].
1 Based on a search of the following terms: amenorrhea, hypomenorrhea, menstruation delayed, and oligomenorrhea.
2 Based on a search of the following terms: anorgasmia, delayed ejaculation, erectile dysfunction, decreased libido, loss of libido, abnormal orgasm, and sexual dysfunction.
3 Based on a search of the following terms: breast discharge, enlargement or swelling, galactorrhea, gynecomastia, and lactation disorder.
Dose group differences with respect to prolactin elevation have been observed. In a single 8-week randomized, double-blind, fixed-dose study comparing 10 (n=199), 20 (n=200) and 40 (n=200) mg/day of oral olanzapine in adult patients with schizophrenia or schizoaffective disorder, incidence of prolactin elevation >24.2 ng/mL (female) or >18.77 ng/mL (male) at any time during the trial (10 mg/day: 31.2%; 20 mg/day: 42.7%; 40 mg/day: 61.1%) indicated significant differences between 10 vs 40 mg/day and 20 vs 40 mg/day.
SYMBYAX contains the same active ingredients that are in Zyprexa, Zyprexa Zydis, Zyprexa Relprevv (olanzapine), and in Prozac, and Sarafem (fluoxetine HCl). Caution should be exercised when prescribing these medications concomitantly with SYMBYAX [see Overdosage (10)].
Because of the long elimination half-lives of fluoxetine and its major active metabolite, changes in dose will not be fully reflected in plasma for several weeks, affecting both strategies for titration to final dose and withdrawal from treatment. This is of potential consequence when drug discontinuation is required or when drugs are prescribed that might interact with fluoxetine and norfluoxetine following the discontinuation of fluoxetine [see Clinical Pharmacology (12.3)].
During marketing of fluoxetine, a component of SYMBYAX, SNRIs, and SSRIs, there have been spontaneous reports of adverse reactions occurring upon discontinuation of these drugs, particularly when abrupt, including the following: dysphoric mood, irritability, agitation, dizziness, sensory disturbances (e.g., paresthesias such as electric shock sensations), anxiety, confusion, headache, lethargy, emotional lability, insomnia, and hypomania. While these reactions are generally self-limiting, there have been reports of serious discontinuation symptoms. Patients should be monitored for these symptoms when discontinuing treatment with fluoxetine. A gradual reduction in the dose rather than abrupt cessation is recommended whenever possible. If intolerable symptoms occur following a decrease in the dose or upon discontinuation of treatment, then resuming the previously prescribed dose may be considered. Subsequently, the healthcare provider may continue decreasing the dose but at a more gradual rate. Plasma fluoxetine and norfluoxetine concentration decrease gradually at the conclusion of therapy, which may minimize the risk of discontinuation symptoms with this drug [see Dosage and Administration (2.4)].
Use of SSRIs, including fluoxetine a component of SYMBYAX, may cause symptoms of sexual dysfunction [see Adverse Reactions (6.1)]. In male patients, SYMBYAX use may result in ejaculatory delay or failure, decreased libido, and erectile dysfunction. In female patients, SYMBYAX use may result in decreased libido and delayed or absent orgasm.
It is important for prescribers to inquire about sexual function prior to initiation of SYMBYAX and to inquire specifically about changes in sexual function during treatment, because sexual function may not be spontaneously reported. When evaluating changes in sexual function, obtaining a detailed history (including timing of symptom onset) is important because sexual symptoms may have other causes, including the underlying psychiatric disorder. Discuss potential management strategies to support patients in making informed decisions about treatment.
The following adverse reactions are discussed in more detail in other sections of the labeling:
Because clinical trials are conducted under widely varying conditions, adverse reaction rates observed in the clinical trials of a drug cannot be directly compared to rates in the clinical trials of another drug and may not reflect or predict the rates observed in practice.
The data in the tables represent the proportion of individuals who experienced, at least once, a treatment-emergent adverse reaction of the type listed. A reaction was considered treatment-emergent if it occurred for the first time or worsened while receiving therapy following baseline evaluation.
The information below is derived from a clinical study database for SYMBYAX consisting of 2547 patients with treatment resistant depression, depressive episodes associated with Bipolar I Disorder, Major Depressive Disorder with psychosis, or sexual dysfunction with approximately 1085 patient-years of exposure. The conditions and duration of treatment with SYMBYAX varied greatly and included (in overlapping categories) open-label and double-blind phases of studies, inpatients and outpatients, fixed-dose and dose-titration studies, and short-term or long-term exposure.
Overall, 11.3% of the 771 patients in the SYMBYAX group discontinued due to adverse reactions compared with 4.4% of the 477 patients for placebo. Adverse reactions leading to discontinuation associated with the use of SYMBYAX (incidence of at least 1% for SYMBYAX and greater than that for placebo) using MedDRA Dictionary coding were weight increased (2%) and sedation (1%) versus placebo patients which had 0% incidence of weight increased and sedation.
In short-term studies, the most commonly observed adverse reactions associated with the use of SYMBYAX (incidence ≥5% and at least twice that for placebo in the SYMBYAX-controlled database) using MedDRA Dictionary coding were: disturbance in attention, dry mouth, fatigue, hypersomnia, increased appetite, peripheral edema, sedation, somnolence, tremor, vision blurred, and weight increased. Adverse reactions reported in clinical trials of olanzapine and fluoxetine in combination are generally consistent with treatment-emergent adverse reactions during olanzapine or fluoxetine monotherapy.
In a 47-week maintenance study in adults with treatment resistant depression, adverse reactions associated with SYMBYAX use were generally similar to those seen in short-term studies. Weight gain, hyperlipidemia, and hyperglycemia were observed in SYMBYAX-treated patients throughout the study.
Table 16 enumerates the treatment-emergent adverse reactions associated with the use of SYMBYAX (incidence of at least 2% for SYMBYAX and twice or more than for placebo). The SYMBYAX-controlled column includes patients with various diagnoses while the placebo column includes only patients with bipolar depression and major depression with psychotic features.
Table 16. Adverse Reactions: Incidence in the Short-Term Controlled Clinical Studies in Adults:
System Organ Class | Adverse Reaction | Percentage of Patients Reporting Event | |
---|---|---|---|
SYMBYAX- Controlled (N=771) | Placebo (N=477) | ||
Eye disorders | Vision blurred | 5 | 2 |
Gastrointestinal disorders | Dry mouth | 15 | 6 |
Flatulence | 3 | 1 | |
Abdominal distension | 2 | 0 | |
General disorders and administration site conditions | Fatigue | 12 | 2 |
Edemaa | 15 | 2 | |
Asthenia | 3 | 1 | |
Pain | 2 | 1 | |
Pyrexia | 2 | 1 | |
Infections and infestations | Sinusitis | 2 | 1 |
Investigations | Weight increased | 25 | 3 |
Metabolism and nutrition disorders | Increased appetite | 20 | 4 |
Musculoskeletal and connective tissue disorders | Arthralgia | 4 | 1 |
Pain in extremity | 3 | 1 | |
Musculoskeletal stiffness | 2 | 1 | |
Nervous system disorders | Somnolenceb | 27 | 11 |
Tremor | 9 | 3 | |
Disturbance in attention | 5 | 1 | |
Psychiatric disorders | Restlessness | 4 | 1 |
Thinking abnormal | 2 | 1 | |
Nervousness | 2 | 1 | |
Reproductive system and breast disorders | Erectile dysfunction | 2 | 1 |
a Includes edema, edema peripheral, pitting edema, generalized edema, eyelid edema, face edema, gravitational edema, localized edema, periorbital edema, swelling, joint swelling, swelling face, and eye swelling.
b Includes somnolence, sedation, hypersomnia, and lethargy.
Symptoms of dystonia, prolonged abnormal contractions of muscle groups, may occur in susceptible individuals during the first few days of treatment. Dystonic symptoms include: spasm of the neck muscles, sometimes progressing to tightness of the throat, swallowing difficulty, difficulty breathing, and/or protrusion of the tongue. While these symptoms can occur at low doses, the frequency and severity are greater with high potency and at higher doses of first generation antipsychotic drugs. In general, an elevated risk of acute dystonia may be observed in males and younger age groups receiving antipsychotics; however, events of dystonia have been reported infrequently (<1%) with the olanzapine and fluoxetine combination.
In the pool of controlled SYMBYAX studies in patients with bipolar depression, there were higher rates of the treatment-emergent adverse reactions decreased libido, anorgasmia, erectile dysfunction and abnormal ejaculation in the SYMBYAX group than in the placebo group. One case of decreased libido led to discontinuation in the SYMBYAX group. In the controlled studies that contained a fluoxetine arm, the rates of decreased libido and abnormal ejaculation in the SYMBYAX group were less than the rates in the fluoxetine group. None of the differences were statistically significant.
Sexual dysfunction, including priapism, has been reported with all SSRIs. While it is difficult to know the precise risk of sexual dysfunction associated with the use of SSRIs, healthcare providers should routinely inquire about such possible side effects.
There are no adequate and well-controlled studies examining sexual dysfunction with SYMBYAX or fluoxetine treatment. Symptoms of sexual dysfunction occasionally persist after discontinuation of fluoxetine treatment.
In a single 8-week randomized, double-blind, fixed-dose study comparing 10 (N=199), 20 (N=200), and 40 (N=200) mg/day of olanzapine in patients with Schizophrenia or Schizoaffective Disorder, statistically significant differences among 3 dose groups were observed for the following safety outcomes: weight gain, prolactin elevation, fatigue, and dizziness. Mean baseline to endpoint increase in weight (10 mg/day: 1.9 kg; 20 mg/day: 2.3 kg; 40 mg/day: 3 kg) was observed with significant differences between 10 vs 40 mg/day. Incidence of treatment-emergent prolactin elevation >24.2 ng/mL (female) or >18.77 ng/mL (male) at any time during the trial (10 mg/day: 31.2%; 20 mg/day: 42.7%; 40 mg/day: 61.1%) with significant differences between 10 vs 40 mg/day and 20 vs 40 mg/day; fatigue (10 mg/day: 1.5%; 20 mg/day: 2.1%; 40 mg/day: 6.6%) with significant differences between 10 vs 40 and 20 vs 40 mg/day; and dizziness (10 mg/day: 2.6%; 20 mg/day: 1.6%; 40 mg/day: 6.6%) with significant differences between 20 vs 40 mg, was observed.
Following is a list of treatment-emergent adverse reactions reported by patients treated with SYMBYAX in clinical trials. This listing is not intended to include reactions (1) already listed in previous tables or elsewhere in labeling, (2) for which a drug cause was remote, (3) which were so general as to be uninformative, (4) which were not considered to have significant clinical implications, or (5) which occurred at a rate equal to or less than placebo.
Reactions are classified by body system using the following definitions: frequent adverse reactions are those occurring in at least 1/100 patients; infrequent adverse reactions are those occurring in 1/100 to 1/1000 patients; and rare reactions are those occurring in fewer than 1/1000 patients.
Frequent: chills, neck rigidity, photosensitivity reaction
Rare: death1
Frequent: vasodilatation.
Frequent: diarrhea
Infrequent: gastritis, gastroenteritis, nausea and vomiting, peptic ulcer
Rare: gastrointestinal hemorrhage, intestinal obstruction, liver fatty deposit, pancreatitis
Frequent: ecchymosis
Infrequent: anemia, thrombocytopenia
Rare: leukopenia, purpura
Frequent: generalized edema, weight loss
Rare: bilirubinemia, creatinine increased, gout
Rare: osteoporosis.
Frequent: amnesia
Infrequent: ataxia, buccoglossal syndrome, coma, depersonalization, dysarthria, emotional lability, euphoria, hypokinesia, movement disorder, myoclonus
Rare: hyperkinesia, libido increased, withdrawal syndrome.
Infrequent: epistaxis, yawn
Rare: laryngismus
Infrequent: alopecia, dry skin, pruritus
Rare: exfoliative dermatitis
Frequent: taste perversion
Infrequent: abnormality of accommodation, dry eyes
Frequent: breast pain, menorrhagia2, urinary frequency, urinary incontinence
Infrequent: amenorrhea2, female lactation2, hypomenorrhea2, metrorrhagia2, urinary retention, urinary urgency, urination impaired
Rare: breast engorgement2
1 This term represents a serious adverse event but does not meet the definition for adverse drug reactions. It is included here because of its seriousness.
2 Adjusted for gender.
The following adverse reactions were not observed in SYMBYAX-treated patients during premarketing clinical studies but have been reported with olanzapine or fluoxetine monotherapy: Bruxism, dysuria, esophageal ulcer, gynecological bleeding, headache, hypotension, neutropenia, sudden unexpected death3 and sweating.
3 These terms represent serious adverse events but do not meet the definition for adverse drug reactions. They are included here because of their seriousness.
The information below is derived from a single, 8-week, randomized, placebo-controlled clinical trial investigating SYMBYAX for the treatment of bipolar I depression in patients 10 to 17 years of age.
Adverse Reactions Associated with Discontinuation of Treatment in the single pediatric study — Overall, 14.1% of the 170 patients in the SYMBYAX group discontinued due to adverse reactions compared with 5.9% of the 85 patients for placebo. Adverse reactions leading to discontinuation associated with the use of SYMBYAX (incidence of at least 1% for SYMBYAX and greater than that for placebo) using MedDRA Dictionary coding were weight increased (2.9%), suicidal ideation (1.8%), bipolar disorder (1.2%), and somnolence (1.2%) versus placebo patients which had 0% incidence of weight increased, bipolar disorder, and somnolence, and a 1.2% incidence of suicidal ideation.
Adverse Reactions Occurring at an Incidence of 2% or more and greater than placebo — Table 17 enumerates the treatment-emergent adverse reactions associated with the use of SYMBYAX (incidence of at least 2% for SYMBYAX and twice or more than for placebo).
Table 17. Treatment-Emergent Adverse Reactions: Incidence in a 8-week randomized, double-blind, placebo-controlled clinical trial in pediatric bipolar I depression:
System Organ Class | Adverse Reaction | Percentage of Patients Reporting Event | |
---|---|---|---|
SYMBYAX (N=170) | Placebo (N=85) | ||
Nervous system disorders | Somnolencea | 24 | 2 |
Tremor | 9 | 1 | |
Investigations | Weight increased | 20 | 1 |
Blood triglycerides increased | 7 | 2 | |
Blood cholesterol increased | 4 | 0 | |
Hepatic enzyme increased b | 9 | 1 | |
Gastrointestinal disorders | Dyspepsia | 3 | 1 |
Metabolism and nutrition disorders | Increased appetite | 17 | 1 |
Psychiatric disorders | Anxiety | 3 | 1 |
Restlessness | 3 | 1 | |
Suicidal ideation | 2 | 1 | |
Musculoskeletal and connective tissue disorders | Back pain | 2 | 1 |
Injury, poisoning and procedural complications | Accidental overdose | 3 | 1 |
Reproductive system and breast disorders | Dysmenorrhea | 2 | 0 |
a Includes somnolence, sedation, and hypersomnia. No lethargy was reported. |
b Includes alanine aminotransferase increased, aspartate aminotransferase increased, hepatic enzyme increased, liver function test abnormal, gamma-glutamyltransferase increased, and transaminases increased.
Tachycardia, bradycardia, and orthostatic hypotension have occurred in SYMBYAX-treated patients [see Warnings and Precautions (5.11)]. The mean standing pulse rate of SYMBYAX-treated patients was reduced by 0.7 beats/min.
In SYMBYAX clinical studies (including treatment resistant depression, depressive episodes associated with Bipolar I Disorder, Major Depressive Disorder with psychosis, or sexual dysfunction), SYMBYAX was associated with statistically significantly greater frequencies for the following treatment-emergent findings in laboratory analytes (normal at baseline to abnormal at any time during the trial) compared to placebo: elevated prolactin (28% vs 5%); elevated urea nitrogen (3% vs 0.8%); elevated uric acid (3% vs 0.5%); low albumin (3% vs 0.3%); low bicarbonate (14% vs 9%); low hemoglobin (3% vs 0%); low inorganic phosphorus (2% vs 0.3%); low lymphocytes (2% vs 0%); and low total bilirubin (15% vs 4%).
As with olanzapine, asymptomatic elevations of hepatic aminotransferases [ALT, AST, and GGT] and alkaline phosphatase have been observed with SYMBYAX. In the SYMBYAX-controlled database, clinically significant ALT elevations (change from <3 times the upper limit of normal [ULN] at baseline to ≥3 times ULN) were observed in 5% (38/698) of patients exposed to SYMBYAX compared with 0.5% (2/378) of placebo-treated patients and 4% (33/751) of olanzapine-treated patients. ALT elevations ≥5 times ULN were observed in 2% (11/701) of SYMBYAX-treated patients, compared to 0.3% (1/379) of placebo-treated patients and 1% (11/760) of olanzapine-treated patients. No patient with elevated ALT values experienced jaundice or liver failure, or met the criteria for Hy’s Rule. ALT values returned to normal, or were decreasing, at last follow-up in the majority of patients who either continued treatment with SYMBYAX or discontinued SYMBYAX.
Rare postmarketing reports of hepatitis have been received in patients treated with olanzapine. Very rare cases of cholestatic or mixed liver injury have also been reported in the postmarketing period in patients treated with olanzapine.
Caution should be exercised in patients with signs and symptoms of hepatic impairment, in patients with pre-existing conditions associated with limited hepatic functional reserve, and in patients who are being treated with potentially hepatotoxic drugs.
An increase in creatine phosphokinase has been reported very rarely in SYMBYAX-treated patients and infrequently in clinical trials of olanzapine-treated patients.
In patients treated with SYMBYAX QTcF≥450 msec for males and QTcF≥470 msec for females has been reported frequently (≥1%). The incidence of QTcF>500 msec associated with SYMBYAX treatment in clinical trials has been rare and was not significantly different from the incidence associated with placebo. The mean increase in QTc interval for SYMBYAX-treated patients (5.17 msec) in the one clinical study directly comparing SYMBYAX to placebo in adult patients was significantly greater than that for placebo-treated patients (-1.66 msec).
In a single 8-week randomized, placebo-controlled clinical trial investigating SYMBYAX for treatment of bipolar I depression in patients 10 to 17 years of age, the following was observed:
In the SYMBYAX-treated patients compared with placebo-treated patients, the mean orthostatic blood pressure and standing pulse rate were not significantly different between treatment groups.
Body Weight: An increase in weight greater than or equal to 7% occurred in 52.4% of the SYMBYAX group and 3.6% of the placebo group. Weight gain greater than or equal to 15% occurred in 14.1% of the SYMBYAX group and none of the placebo group.
SYMBYAX was associated with statistically significantly greater frequencies for the following treatment-emergent findings in laboratory analytes (normal or low at baseline to abnormal at any time during the trial) compared to placebo: elevated ALT (45.9% vs 2.5%); elevated AST (33.7% vs 7.6%); high fasting total cholesterol (28.9% vs 8.2%); high fasting LDL cholesterol (19.7% vs 6.5%); high fasting triglycerides (52.3% vs 27.3%), and elevated prolactin (85% vs 36%). No patient with elevated hepatic enzyme values experienced jaundice or liver failure, or met the criteria for Hy’s Rule. Five patients experienced an adverse event potentially associated with elevated prolactin; these events included dysmenorrhea, galactorrhea, and ovulation disorder.
SYMBYAX was associated with a statistically significantly greater mean increase in QTcF interval (8.2 msec [95% CI 6.2, 10.2]) compared with placebo. No patients developed QTc increases ≥60 msec or QTc ≥480 msec [see Warnings and Precautions (5.20)].
The following adverse reactions have been identified during post-approval use of SYMBYAX, Fluoxetine, or Olanzapine monotherapy. Because these reactions are reported voluntarily from a population of uncertain size, it is difficult to reliably estimate their frequency or evaluate a causal relationship to drug exposure.
Adverse reactions reported since market introduction that were temporally (but not necessarily causally) related to SYMBYAX, fluoxetine, or olanzapine therapy include the following:
SYMBYAX: rhabdomyolysis and venous thromboembolic events (including pulmonary embolism and deep venous thrombosis)
Fluoxetine: aplastic anemia, cholestatic jaundice, eosinophilic pneumonia3, erythema multiforme, violent behavior3, atrial fibrillation3, cataract, cerebrovascular accident3, epidermal necrolysis, erythema nodosum, heart arrest3, hepatic failure/necrosis, hypoglycemia, kidney failure, memory impairment, optic neuritis, pulmonary hypertension, Stevens-Johnson syndrome.
Olanzapine: diabetic coma, jaundice, random triglyceride levels of ≥1000 mg/dL, restless legs syndrome, stuttering4, salivary hypersecretion, allergic reaction (e.g., anaphylactoid reaction, angioedema, pruritus or urticaria), diabetic ketoacidosis, discontinuation reaction (diaphoresis, nausea or vomiting), Drug Reaction with Eosinophilia and Systemic Symptoms (DRESS).
3 These terms represent serious adverse events but do not meet the definition for adverse drug reactions. They are included here because of their seriousness.
4 Stuttering was only studied in oral and long acting injection (LAI) olanzapine formulations.
The risks of using SYMBYAX in combination with other drugs have not been extensively evaluated in systematic studies. The drug-drug interactions sections of fluoxetine and olanzapine are applicable to SYMBYAX. As with all drugs, the potential for interaction by a variety of mechanisms (e.g., pharmacodynamic, pharmacokinetic drug inhibition or enhancement, etc.) is a possibility. In evaluating individual cases, consideration should be given to using lower initial doses of the concomitantly administered drugs, using conservative titration schedules, and monitoring of clinical status [see Clinical Pharmacology (12.3)].
[See Dosage and Administration (2.4, 2.5), Contraindications (4.1), and Warnings and Precautions (5.6)].
Caution is advised if the concomitant administration of SYMBYAX and other CNS-active drugs is required. In evaluating individual cases, consideration should be given to using lower initial doses of the concomitantly administered drugs, using conservative titration schedules, and monitoring of clinical status [see Clinical Pharmacology (12.3)].
[See Dosage and Administration (2.4, 2.5), Contraindications (4.1), and Warnings and Precautions (5.6)].
Serotonin release by platelets plays an important role in hemostasis. Epidemiological studies of the case-control and cohort design that have demonstrated an association between use of psychotropic drugs that interfere with serotonin reuptake and the occurrence of upper gastrointestinal bleeding have also shown that concurrent use of an NSAID or aspirin may potentiate this risk of bleeding. Altered anticoagulant effects, including increased bleeding, have been reported when SNRIs or SSRIs are coadministered with warfarin [see Warnings and Precautions (5.16)]. Warfarin (20 mg single dose) did not affect olanzapine pharmacokinetics. Single doses of olanzapine did not affect the pharmacokinetics of warfarin. Patients receiving warfarin therapy should be carefully monitored when SYMBYAX is initiated or discontinued.
There are no clinical studies establishing the benefit of the combined use of ECT and fluoxetine. There have been rare reports of prolonged seizures in patients on fluoxetine receiving ECT treatment [see Warnings and Precautions (5.15)].
Co-administration of diazepam with olanzapine potentiated the orthostatic hypotension observed with olanzapine [see Drug Interactions (7.7)].
Carbamazepine therapy (200 mg BID) causes an approximate 50% increase in the clearance of olanzapine. This increase is likely due to the fact that carbamazepine is a potent inducer of CYP1A2 activity. Higher daily doses of carbamazepine may cause an even greater increase in olanzapine clearance [see Drug Interactions (7.7)].
Ethanol (45 mg/70 kg single dose) did not have an effect on olanzapine pharmacokinetics [see Drug Interactions (7.7)].
Fluvoxamine decreases the clearance of olanzapine. This results in a mean increase in olanzapine Cmax following fluvoxamine administration of 54% in female nonsmokers and 77% in male smokers. The mean increase in olanzapine AUC is 52% and 108%, respectively. Lower doses of the olanzapine component of SYMBYAX should be considered in patients receiving concomitant treatment with fluvoxamine.
Fluoxetine, an inhibitor of CYP2D6, decreases olanzapine clearance a small amount [see Clinical Pharmacology (12.3)]. Agents that induce CYP1A2 or glucuronyl transferase enzymes, such as omeprazole and rifampin, may cause an increase in olanzapine clearance. The effect of CYP1A2 inhibitors, such as fluvoxamine and some fluoroquinolone antibiotics, on SYMBYAX has not been evaluated. Although olanzapine is metabolized by multiple enzyme systems, induction or inhibition of a single enzyme may appreciably alter olanzapine clearance. Therefore, a dosage increase (for induction) or a dosage decrease (for inhibition) may need to be considered with specific drugs.
Concomitant use of SYMBYAX and pimozide is contraindicated. Pimozide can prolong the QT interval. SYMBYAX can increase the level of pimozide through inhibition of CYP2D6. SYMBYAX can also prolong the QT interval. Clinical studies of pimozide with other antidepressants demonstrate an increase in drug interaction or QTc prolongation. While a specific study with pimozide and SYMBYAX has not been conducted, the potential for drug interactions or QTc prolongation warrants restricting the concurrent use of pimozide and SYMBYAX [see Contraindications (4.2), Warnings and Precautions (5.20), and Drug Interactions (7.8)].
Patients on stable doses of carbamazepine have developed elevated plasma anticonvulsant concentrations and clinical anticonvulsant toxicity following initiation of concomitant fluoxetine treatment.
The coadministration of ethanol with SYMBYAX may potentiate sedation and orthostatic hypotension [see Drug Interactions (7.6)].
Thioridazine should not be administered with SYMBYAX or administered within a minimum of 5 weeks after discontinuation of SYMBYAX, because of the risk of QT prolongation [see Contraindications (4.2), Warnings and Precautions (5.20), and Drug Interactions (7.8)].
In a study of 19 healthy male subjects, which included 6 slow and 13 rapid hydroxylators of debrisoquin, a single 25 mg oral dose of thioridazine produced a 2.4-fold higher Cmax and a 4.5-fold higher AUC for thioridazine in the slow hydroxylators compared with the rapid hydroxylators. The rate of debrisoquin hydroxylation is felt to depend on the level of CYP2D6 isozyme activity. Thus, this study suggests that drugs that inhibit CYP2D6, such as certain SSRIs, including fluoxetine, will produce elevated plasma levels of thioridazine [see Contraindications (4.2)].
Thioridazine administration produces a dose-related prolongation of the QTc interval, which is associated with serious ventricular arrhythmias, such as torsades de pointes-type arrhythmias and sudden death. This risk is expected to increase with fluoxetine-induced inhibition of thioridazine metabolism [see Contraindications (4.2)].
Due to the risk of serious ventricular arrhythmias and sudden death potentially associated with elevated thioridazine plasma levels, thioridazine should not be administered with fluoxetine or within a minimum of 5 weeks after fluoxetine has been discontinued [see Contraindications (4.2)].
Single doses of olanzapine did not affect the pharmacokinetics of imipramine or its active metabolite desipramine.
In 2 fluoxetine studies, previously stable plasma levels of imipramine and desipramine have increased >2- to 10-fold when fluoxetine has been administered in combination. This influence may persist for 3 weeks or longer after fluoxetine is discontinued. Thus, the dose of TCA may need to be reduced and plasma TCA concentrations may need to be monitored temporarily when SYMBYAX is coadministered or has been recently discontinued [see Warnings and Precautions (5.6) and Clinical Pharmacology (12.3)].
Because of the potential for olanzapine to induce hypotension, SYMBYAX may enhance the effects of certain antihypertensive agents [see Warnings and Precautions (5.11)].
The olanzapine component of SYMBYAX may antagonize the effects of levodopa and dopamine agonists.
Multiple doses of olanzapine did not influence the pharmacokinetics of diazepam and its active metabolite N-desmethyldiazepam.
When concurrently administered with fluoxetine, the half-life of diazepam may be prolonged in some patients [see Clinical Pharmacology (12.3)]. Coadministration of alprazolam and fluoxetine has resulted in increased alprazolam plasma concentrations and in further psychomotor performance decrement due to increased alprazolam levels.
Elevation of blood levels of clozapine has been observed in patients receiving concomitant fluoxetine.
Elevation of blood levels of haloperidol has been observed in patients receiving concomitant fluoxetine.
Patients on stable doses of phenytoin have developed elevated plasma levels of phenytoin with clinical phenytoin toxicity following initiation of concomitant fluoxetine.
In vitro studies utilizing human liver microsomes suggest that olanzapine has little potential to inhibit CYP2D6. Thus, olanzapine is unlikely to cause clinically important drug interactions mediated by this enzyme.
Fluoxetine inhibits the activity of CYP2D6 and may make individuals with normal CYP2D6 metabolic activity resemble a poor metabolizer. Coadministration of fluoxetine with other drugs that are metabolized by CYP2D6, including certain antidepressants (e.g., TCAs), antipsychotics (e.g., phenothiazines and most atypicals), and antiarrhythmics (e.g., propafenone, flecainide, and others) should be approached with caution. Therapy with medications that are predominantly metabolized by the CYP2D6 system and that have a relatively narrow therapeutic index should be initiated at the low end of the dose range if a patient is receiving fluoxetine concurrently or has taken it in the previous 5 weeks. If fluoxetine is added to the treatment regimen of a patient already receiving a drug metabolized by CYP2D6, the need for a decreased dose of the original medication should be considered. Drugs with a narrow therapeutic index represent the greatest concern (including but not limited to, flecainide, propafenone, vinblastine, and TCAs).
In vitro studies utilizing human liver microsomes suggest that olanzapine has little potential to inhibit CYP3A. Thus, olanzapine is unlikely to cause clinically important drug interactions mediated by these enzymes.
In an in vivo interaction study involving the coadministration of fluoxetine with single doses of terfenadine (a CYP3A substrate), no increase in plasma terfenadine concentrations occurred with concomitant fluoxetine. In addition, in vitro studies have shown ketoconazole, a potent inhibitor of CYP3A activity, to be at least 100 times more potent than fluoxetine or norfluoxetine as an inhibitor of the metabolism of several substrates for this enzyme, including astemizole, cisapride, and midazolam. These data indicate that fluoxetine’s extent of inhibition of CYP3A activity is not likely to be of clinical significance.
In vitro studies utilizing human liver microsomes suggest that olanzapine has little potential to inhibit CYP1A2, CYP2C9, and CYP2C19. Thus, olanzapine is unlikely to cause clinically important drug interactions mediated by these enzymes.
Multiple doses of olanzapine did not influence the pharmacokinetics of lithium.
There have been reports of both increased and decreased lithium levels when lithium was used concomitantly with fluoxetine. Cases of lithium toxicity and increased serotonergic effects have been reported. Lithium levels should be monitored in patients taking SYMBYAX concomitantly with lithium [see Warnings and Precautions (5.5)].
The in vitro binding of SYMBYAX to human plasma proteins is similar to the individual components. The interaction between SYMBYAX and other highly protein-bound drugs has not been fully evaluated. Because fluoxetine is tightly bound to plasma protein, the administration of fluoxetine to a patient taking another drug that is tightly bound to protein (e.g., Coumadin, digitoxin) may cause a shift in plasma concentrations potentially resulting in an adverse effect. Conversely, adverse effects may result from displacement of protein-bound fluoxetine by other tightly bound drugs [see Clinical Pharmacology (12.3)].
In vitro studies using human liver microsomes determined that olanzapine has little potential to inhibit the major metabolic pathway, glucuronidation, of valproate. Further, valproate has little effect on the metabolism of olanzapine in vitro. Thus, a clinically significant pharmacokinetic interaction between olanzapine and valproate is unlikely.
Multiple doses of olanzapine did not influence the pharmacokinetics of biperiden.
Multiple doses of olanzapine did not affect the pharmacokinetics of theophylline or its metabolites.
Do not use SYMBYAX in combination with thioridazine or pimozide. Use SYMBYAX with caution in combination with other drugs that cause QT prolongation. These include: specific antipsychotics (e.g., ziprasidone, iloperidone, chlorpromazine, mesoridazine, droperidol); specific antibiotics (e.g., erythromycin, gatifloxacin, moxifloxacin, sparfloxacin); Class 1A antiarrhythmic medications (e.g., quinidine, procainamide); Class III antiarrhythmics (e.g., amiodarone, sotalol); and others (e.g., pentamidine, levomethadyl acetate, methadone, halofantrine, mefloquine, dolasetron mesylate, probucol or tacrolimus). Fluoxetine is primarily metabolized by CYP2D6. Concomitant treatment with CYP2D6 inhibitors can increase the concentration of fluoxetine. Concomitant use of other highly protein-bound drugs can increase the concentration of fluoxetine [see Contraindications (4.2), Warnings and Precautions (5.20), Drug Interactions (7.7), and Clinical Pharmacology (12.3)].
Neonates exposed to antipsychotic drugs, including the olanzapine component of SYMBYAX, during the third trimester are at risk for extrapyramidal and/or withdrawal symptoms following delivery (see Clinical Considerations). Overall available data from published epidemiologic studies and postmarketing reports of pregnant women exposed to olanzapine or fluoxetine have not established a drug-associated increased risk of major birth defects or miscarriage (see Data). Some studies in pregnant women exposed to fluoxetine have reported an increased incidence of cardiovascular malformations; however, these studies results do not establish a causal relationship (see Data). There are risks associated with untreated depression in pregnancy and risks of persistent pulmonary hypertension (PPHN) (see Data) and poor neonatal adaptation with exposure to selective serotonin reuptake inhibitors (SSRIs), including fluoxetine, during pregnancy (see Clinical Considerations). Neonates exposed to antipsychotic drugs, including the olanzapine component of SYMBYAX, during the third trimester are at risk for extrapyramidal and/or withdrawal symptoms following delivery (see Clinical Considerations).
In animal studies, administration of the combination of olanzapine and fluoxetine during the period of organogenesis resulted in adverse effects on development (decreased fetal body weights in rats and rabbits and retarded skeletal ossification in rabbits) at maternally toxic doses greater than those used clinically. When administered to rats throughout pregnancy and lactation, an increase in early postnatal mortality was observed at doses similar to those used clinically (see Data).
The estimated background risk of major birth defects and miscarriage for the indicated populations is unknown. All pregnancies have a background risk of birth defects, miscarriage, or another adverse outcomes. In the U.S. general population, the estimated background risk of major birth defects and miscarriage in clinically recognized pregnancies is 2% to 4% and 15% to 20%, respectively.
Women who discontinue antidepressants during pregnancy are more likely to experience a relapse of major depression than women who continue antidepressants. This finding is from a prospective, longitudinal study that followed 201 pregnant women with a history of major depressive disorder who were euthymic and taking antidepressants at the beginning of pregnancy. Consider the risk of untreated depression when discontinuing or changing treatment with antidepressant medication during pregnancy and the postpartum.
Extrapyramidal and/or withdrawal symptoms, including agitation, hypertonia, hypotonia, tremor, somnolence, respiratory distress and feeding disorder have been reported in neonates who were exposed to antipsychotic drugs, including olanzapine, during the third trimester of pregnancy. These symptoms have varied in severity. Monitor neonates for extrapyramidal and/or withdrawal symptoms and manage symptoms appropriately. Some neonates recovered within hours or days without specific treatment; others required prolonged hospitalization.
Neonates exposed to fluoxetine, and other SSRIs or SNRIs late in the third trimester have developed complications requiring prolonged hospitalization, respiratory support, and tube feeding. Such complications can arise immediately upon delivery. Reported clinical findings have included respiratory distress, cyanosis, apnea, seizures, temperature instability, feeding difficulty, vomiting, hypoglycemia, hypotonia, hypertonia, hyperreflexia, tremor, jitteriness, irritability, and constant crying. These findings are consistent with either a direct toxic effect of SSRIs and SNRIs or, possibly, a drug discontinuation syndrome. It should be noted that, in some cases, the clinical picture is consistent with serotonin syndrome [see Warnings and Precautions (5.6)].
Infants exposed to SSRIs, particularly later in pregnancy may have an increased risk for persistent pulmonary hypertension of the newborn (PPHN). PPHN occurs in 1–2 per 1,000 live births in the general population and is associated with substantial neonatal morbidity and mortality. Several recent epidemiologic studies suggest a positive statistical association between SSRI (including fluoxetine) use in pregnancy and PPHN. Other studies do not show a significant statistical association.
It has been shown that olanzapine and fluoxetine can cross the placenta. Placental passage of olanzapine has been reported in published study reports; however, the placental passage ratio was highly variable ranging between 7% to 167% at birth following exposure during pregnancy. The clinical relevance of this finding is unknown.
Published data from observational studies, birth registries, and case reports on the use of atypical antipsychotics during pregnancy do not establish an increased risk of major birth defects. A retrospective cohort study from a Medicaid database of 9258 women exposed to antipsychotics during pregnancy did not indicate an overall increased risk for major birth defects.
Several publications reported an increased incidence of cardiovascular malformations in children with in utero exposure to fluoxetine. However, these studies results do not establish a causal relationship. Methodologic limitations of these observational studies include possible exposure and outcome misclassification, lack of adequate controls, adjustment for confounders and confirmatory studies. However, these studies cannot definitely establish or exclude any drug-associated risk during pregnancy.
Exposure to SSRIs, particularly later in pregnancy, may have an increased risk for persistent pulmonary hypertension (PPHN). PPHN occurs in 1-2 per 1000 live births in the general population and is associated with substantial neonatal morbidity and mortality.
Embryo-fetal development studies were conducted in rats and rabbits with olanzapine and fluoxetine in low-dose and high-dose combinations. In rats, the doses were: 2 and 4 mg/kg/day (low-dose) [approximately 2 and 1 times the maximum recommended human dose (MRHD) for SYMBYAX: for olanzapine (12 mg) and fluoxetine (50 mg), respectively based on mg/m² body surface area], and 4 and 8 mg/kg/day (high-dose) [approximately 3 and 2 times the MRHD based on mg/m² body surface area, respectively]. In rabbits, the doses were 4 and 4 mg/kg/day (low-dose) [approximately 6 and 2 times the MRHD based on mg/m² body surface area, respectively], and 8 and 8 mg/kg/day (high-dose) [approximately 13 and 3 times the MRHD based on mg/m² body surface area, respectively]. In these studies, olanzapine and fluoxetine were also administered alone at the high-doses (4 and 8 mg/kg/day, respectively, in the rat; 8 and 8 mg/kg/day, respectively, in the rabbit). In the rabbit, there was no evidence of teratogenicity; however, the high-dose combination produced decreases in fetal weight and retarded skeletal ossification in conjunction with maternal toxicity. Similarly, in the rat there was no evidence of teratogenicity; however, a decrease in fetal weight was observed with the high-dose combination.
In a pre- and postnatal study conducted in rats, olanzapine and fluoxetine were orally administered during pregnancy and throughout lactation in combination at dose levels up to 2 (olanzapine) plus 4 (fluoxetine) mg/kg/day (2 and 1 times the MRHD based on mg/m² body surface area, respectively). An elevation of early postnatal mortality (survival through postnatal day 4 was 69% per litter) and reduced body weight (approximately 8% in female) occurred among offspring at the highest dose: the no-effect dose was 0.5 (olanzapine) plus 1 (fluoxetine) mg/kg/day ( less than the MRHD based on mg/m² body surface area). Among the surviving progeny, there were no adverse effects on physical or neurobehavioral development and reproductive performance at any dose.
In oral reproduction studies in rats at doses up to 18 mg/kg/day and in rabbits, at doses up to 30 mg/kg/day (15 and 49 times the daily oral MRHD of 12 mg based on mg/m² body surface area, respectively) no evidence of teratogenicity was observed. In an oral rat teratology study, early resorptions and increased numbers of nonviable fetuses were observed at a dose of 18 mg/kg/day (15 times the daily oral MRHD based on mg/m² body surface area). Gestation was prolonged at 10 mg/kg/day (8 times the daily oral MRHD based on mg/m² body surface area). In an oral rabbit teratology study, fetal toxicity manifested as increased resorptions and decreased fetal weight, occurred at a maternally toxic dose of 30 mg/kg/day (49 times the daily oral MRHD based on mg/m² body surface area).
In embryo-fetal development studies in rats and rabbits, there was no evidence of malformations or developmental variations following administration of fluoxetine at doses up to 12.5 and 15 mg/kg/day, respectively (2 and 6 times, respectively, the MRHD of 50 mg based on mg/m² body surface area) throughout organogenesis. However, in rat reproduction studies, an increase in stillborn pups, a decrease in pup weight, and an increase in pup deaths during the first 7 days postpartum occurred following maternal exposure to 12 mg/kg/day (approximately 2 times the MRHD based on mg/m² body surface area) during gestation or 7.5 mg/kg/day (approximately 1 times the MRHD based on mg/m² body surface area) during gestation and lactation. There was no evidence of developmental neurotoxicity in the surviving offspring of rats treated with 12 mg/kg/day during gestation. The no-effect dose for rat pup mortality was 5 mg/kg/day (approximately equal to the MRHD based on mg/m² body surface area).
Data from published literature report the presence of olanzapine, fluoxetine, and norfluoxetine in human milk (see Data). There are reports of excess sedation, irritability, poor feeding and extrapyramidal symptoms (tremors and abnormal muscle movements) in infants exposed to olanzapine through breast milk and reports of agitation, irritability, poor feeding and poor weight gain in infants exposed to fluoxetine through breast milk (see Clinical Considerations). There is no information on the effects of olanzapine or fluoxetine and their metabolites on milk production.
The developmental and health benefits of breastfeeding should be considered along with the mother’s clinical need for SYMBYAX and any potential adverse effects on the breastfed child from SYMBYAX or the underlying maternal condition.
Infants exposed to SYMBYAX should be monitored for agitation, irritability, poor feeding, poor weight gain, excess sedation, and extrapyramidal symptoms (tremors and abnormal muscle movements).
A study of nineteen nursing mothers on fluoxetine with daily doses of 10-60 mg showed that fluoxetine was detectable in 30% of nursing infant sera (range: 1 to 84 ng/mL), whereas norfluoxetine was found in 85% (range: <1 to 265 ng/mL).
Based on the pharmacologic action of olanzapine (dopamine D2 receptor blockade), treatment with SYMBYAX may result in an increase in serum prolactin levels, which may lead to a reversible reduction in fertility in females of reproductive potential [see Warnings and Precautions (5.22)].
The safety and efficacy of SYMBYAX in patients 10 to 17 years of age has been established for the acute treatment of Depressive Episodes Associated with Bipolar I Disorder in a single 8-week randomized, placebo-controlled clinical trial (N = 255) [see Clinical Studies (14.1)]. Patients were initiated at a dose of 3/25 mg/day and force-titrated to the maximum dose of 12/50 mg/day over two weeks. After Week 2, there was flexible dosing of SYMBYAX in the range of 6/25, 6/50, or 12/50 mg/day. The average dose was olanzapine 7.7 mg and fluoxetine 37.6 mg. The recommended starting dose for children and adolescents is 3/25 mg per day (lower than that for adults). Flexible dosing is recommended, rather than the forced titration used in the study [see Dosage and Administration (2.1)].
The types of adverse events observed with SYMBYAX in children and adolescents were generally similar to those observed in adults. However, the magnitude and frequency of some changes were greater in children and adolescents than adults. These included increases in lipids, hepatic enzymes, and prolactin, as well as increases in the QT interval [see Warnings and Precautions (5.5, 5.20, 5.22), and Vital Signs and Laboratory Studies (6.1)]. The frequency of weight gain ≥7%, and the magnitude and frequency of increases in lipids, hepatic analytes, and prolactin in children and adolescents treated with SYMBYAX were similar to those observed in adolescents treated with olanzapine monotherapy.
The safety and efficacy of olanzapine and fluoxetine in combination for the treatment of bipolar I depression in patients under the age of 10 years have not been established. The safety and effectiveness of olanzapine and fluoxetine in combination for treatment resistant depression in patients less than 18 years of age have not been established.
Anyone considering the use of SYMBYAX in a child or adolescent must balance the potential risks with the clinical need [see Boxed Warning and Warnings and Precautions (5.1)].
Safety and effectiveness of olanzapine in children <13 years of age have not been established.
Compared to patients from adult clinical trials, adolescents treated with oral olanzapine were likely to gain more weight, experience increased sedation, and have greater increases in total cholesterol, triglycerides, LDL cholesterol, prolactin and hepatic aminotransferase levels.
Juvenile animal toxicity studies were performed for fluoxetine alone. Significant toxicity on muscle tissue, neurobehavior, reproductive organs, and bone development has been observed following exposure of juvenile rats to fluoxetine from weaning through maturity. Oral administration of fluoxetine to rats from weaning postnatal day 21 through adulthood day 90 at 3, 10, or 30 mg/kg/day was associated with testicular degeneration and necrosis, epididymal vacuolation and hypospermia (at 30 mg/kg/day corresponding to plasma exposures [AUC] approximately 5-10 times the average AUC in pediatric patients at the MRHD of 20 mg/day), increased serum levels of creatine kinase (at AUC as low as 1-2 times the average AUC in pediatric patients at the MRHD of 20 mg/day), skeletal muscle degeneration and necrosis, decreased femur length/growth and body weight gain (at AUC 5-10 times the average AUC in pediatric patients at the MRHD of 20 mg/day). The high dose of 30 mg/kg/day exceeded a maximum tolerated dose. When animals were evaluated after a drug-free period (up to 11 weeks after cessation of dosing), fluoxetine was associated with neurobehavioral abnormalities (decreased reactivity at AUC as low as approximately 0.1-0.2 times the average AUC in pediatric patients at the MRHD and learning deficit at the high dose), and reproductive functional impairment (decreased mating at all doses and impaired fertility at the high dose). In addition, the testicular and epididymal microscopic lesions and decreased sperm concentrations found in high dose group were also observed, indicating that the drug effects on reproductive organs are irreversible. The reversibility of fluoxetine-induced muscle damage was not assessed.
These fluoxetine toxicities in juvenile rats have not been observed in adult animals. Plasma exposures (AUC) to fluoxetine in juvenile rats receiving 3, 10, or 30 mg/kg/day doses in this study are approximately 0.1-0.2, 1-2, and 5-10 times, respectively, the average exposure in pediatric patients receiving the MRHD of 20 mg/day. Rat exposures to the major metabolite, norfluoxetine, are approximately 0.3-0.8, 1-8, and 3-20 times, respectively, the pediatric exposure at the MRHD.
A specific effect on bone development was reported in juvenile mice administered fluoxetine by the intraperitoneal route to 4 week old mice for 4 weeks at doses 0.5 and 2 times the oral MRHD of 20 mg/day on mg/m² basis. There was a decrease in bone mineralization and density at both doses, but the overall growth (body weight gain or femur length) was not affected.
Clinical studies of SYMBYAX did not include sufficient numbers of patients ≥65 years of age to determine whether they respond differently from younger patients. Other reported clinical experience has not identified differences in responses between the elderly and younger patients. In general, dose selection for an elderly patient should be cautious, usually starting at the low end of the dosing range, reflecting the greater frequency of decreased hepatic, renal, or cardiac function, and of concomitant disease or other drug therapy [see Dosage and Administration (2.3)].
Of the 2500 patients in premarketing clinical studies with olanzapine, 11% (263 patients) were ≥65 years of age. In patients with Schizophrenia, there was no indication of any different tolerability of olanzapine in the elderly compared with younger patients. Studies in elderly patients with dementia-related psychosis have suggested that there may be a different tolerability profile in this population compared with younger patients with Schizophrenia. In placebo-controlled studies of olanzapine in elderly patients with dementia-related psychosis, there was a higher incidence of cerebrovascular adverse reactions (e.g., stroke, transient ischemic attack) in patients treated with olanzapine compared to patients treated with placebo. In 5 placebo-controlled studies of olanzapine in elderly patients with dementia-related psychosis (n=1184), the following adverse reactions were reported in olanzapine-treated patients at an incidence of at least 2% and significantly greater than placebo-treated patients: falls, somnolence, peripheral edema, abnormal gait, urinary incontinence, lethargy, increased weight, asthenia, pyrexia, pneumonia, dry mouth, and visual hallucinations. The rate of discontinuation due to adverse reactions was significantly greater with olanzapine than placebo (13% vs 7%). Elderly patients with dementia-related psychosis treated with olanzapine are at an increased risk of death compared to placebo. Olanzapine is not approved for the treatment of patients with dementia-related psychosis [see Boxed Warning and Warnings and Precautions (5.2)].
Also, the presence of factors that might decrease pharmacokinetic clearance or increase the pharmacodynamic response to olanzapine should lead to consideration of a lower starting dose for any geriatric patient.
US fluoxetine clinical studies included 687 patients ≥65 years of age and 93 patients ≥75 years of age. No overall differences in safety or effectiveness were observed between these subjects and younger subjects, and other reported clinical experience has not identified differences in responses between the elderly and younger patients, but greater sensitivity of some older individuals cannot be ruled out. SNRIs and SSRIs, including SYMBYAX, have been associated with cases of clinically significant hyponatremia in elderly patients, who may be at greater risk for this adverse reaction [see Warnings and Precautions (5.17)].
In subjects with cirrhosis of the liver, the clearances of fluoxetine and its active metabolite, norfluoxetine, were decreased, thus increasing the elimination half-lives of these substances. A lower or less frequent dose of the fluoxetine-component of SYMBYAX should be used in patients with cirrhosis. Caution is advised when using SYMBYAX in patients with diseases or conditions that could affect its metabolism [see Dosage and Administration (2.3) and Clinical Pharmacology (12.4)].
SYMBYAX, as with fluoxetine and olanzapine, has not been systematically studied in humans for its potential for abuse, tolerance, or physical dependence. While the clinical studies did not reveal any tendency for any drug-seeking behavior, these observations were not systematic, and it is not possible to predict on the basis of this limited experience the extent to which a CNS-active drug will be misused, diverted, and/or abused once marketed. Consequently, healthcare providers should carefully evaluate patients for history of drug abuse and follow such patients closely, observing them for signs of misuse or abuse of SYMBYAX (e.g., development of tolerance, incrementation of dose, drug-seeking behavior).
In studies in rats and rhesus monkeys designed to assess abuse and dependence potential, olanzapine alone was shown to have acute depressive CNS effects but little or no potential of abuse or physical dependence at oral doses up to 15 (rat) and 8 (monkey) times the MRHD (20 mg) on a mg/m² basis.
© All content on this website, including data entry, data processing, decision support tools, "RxReasoner" logo and graphics, is the intellectual property of RxReasoner and is protected by copyright laws. Unauthorized reproduction or distribution of any part of this content without explicit written permission from RxReasoner is strictly prohibited. Any third-party content used on this site is acknowledged and utilized under fair use principles.