The chronicity and pattern of theophylline overdosage significantly influences clinical manifestations of toxicity, management and outcome. There are two common presentations: (1) acute overdose, i.e., ingestion of a single large excessive dose ( > 10 mg/kg) as occurs in the context of an attempted suicide or isolated medication error, and (2) chronic overdosage, i.e., ingestion of repeated doses that are excessive for the patient's rate of theophylline clearance. The most common causes of chronic theophylline overdosage include patient or care giver error in dosing, clinician prescribing of an excessive dose or a normal dose in the presence of factors known to decrease the rate of theophylline clearance, and increasing the dose in response to an exacerbation of symptoms without first measuring the serum theophylline concentration to determine whether a dose increase is safe.
Severe toxicity from theophylline overdose is a relatively rare event. In one health maintenance organization, the frequency of hospital admissions for chronic overdosage of theophylline was about 1 per 1000 person-years exposure. In another study, among 6000 blood samples obtained for measurement of serum theophylline concentration, for any reason, from patients treated in an emergency department, 7% were in the 20-30 mcg/mL range and 3% were > 30 mcg/mL. Approximately two-thirds of the patients with serum theophylline concentrations in the 20-30 mcg/mL range had one or more manifestations of toxicity while > 90% of patients with serum theophylline concentrations > 30mcg/mL were clinically intoxicated. Similarly, in other reports, serious toxicity from theophylline is seen principally at serum concentrations > 30 mcg/mL.
Several studies have described the clinical manifestations of theophylline overdose and attempted to determine the factors that predict life-threatening toxicity. In general, patients who experience an acute overdose are less likely to experience seizures than patients who have experienced a chronic overdosage, unless the peak serum theophylline concentration is > 100 mcg/mL. After a chronic overdosage, generalized seizures, life-threatening cardiac arrhythmias, and death may occur at serum theophylline concentrations > 30 mcg/mL. The severity of toxicity after chronic overdosage is more strongly correlated with the patient's age than the peak serum theophylline concentration; patients > 60 years are at the greatest risk for severe toxicity and mortality after a chronic overdosage. Pre-existing or concurrent disease may also significantly increase the susceptibility of a patient to a particular toxic manifestation, e.g., patients with neurologic disorders have an increased risk of seizures and patients with cardiac disease have an increased risk of cardiac arrhythmias for a given serum theophylline concentration compared to patients without the underlying disease.
The frequency of various reported manifestations of theophylline overdose according to the mode of overdose are listed in Table IV.
Other manifestations of theophylline toxicity include increases in serum calcium, creatine kinase, myoglobin and leukocyte count, decreases in serum phosphate and magnesium, acute myocardial infarction, and urinary retention in men with obstructive uropathy.
Seizures associated with serum theophylline concentrations > 30 mcg/mL are often resistant to anticonvulsant therapy and may result in irreversible brain injury if not rapidly controlled. Death from theophylline toxicity is most often secondary to cardiorespiratory arrest and/or hypoxic encephalopathy following prolonged generalized seizures or intractable cardiac arrhythmias causing hemodynamic compromise.
Overdose Management General Recommendations for Patients with Symptoms of Theophylline Overdose or SerumTheophylline Concentrations > 30 mcg/mL (Note: Serum theophylline concentrations may continue to increase after presentation of the patient for medical care.)
Acute Overdose
Increasing the rate of theophylline clearance by extracorporeal methods may rapidly decrease serum concentrations, but the risks of the procedure must be weighed against the potential benefit. Charcoal hemoperfusion is the most effective method of extracorporeal removal, increasing theophylline clearance up to six fold, but serious complications, including hypotension, hypocalcemia, platelet consumption and bleeding diatheses may occur. Hemodialysis is about as efficient as multiple-dose oral activated charcoal and has a lower risk of serious complications than charcoal hemoperfusion. Hemodialysis should be considered as an alternative when charcoal hemoperfusion is not feasible and multiple-dose oral charcoal is ineffective because of intractable emesis. Serum theophylline concentrations may rebound 5-10 mcg/mL after discontinuation of charcoal hemoperfusion or hemodialysis due to redistribution of theophylline from the tissue compartment. Peritoneal dialysis is ineffective for theophylline removal; exchange transfusions in neonates have been minimally effective.
GeneralThe chronicity and pattern of Ventax overdosage significantly influences clinical manifestations of toxicity, management and outcome. There are two common presentations: (1) acute overdose, i.e., infusion of an excessive loading dose or excessive maintenance infusion rate for less than 24 hours, and (2) chronic overdosage, i.e., excessive maintenance infusion rate for greater than 24 hours. The most common causes of chronic Ventax overdosage include clinician prescribing of an excessive dose or a normal dose in the presence of factors known to decrease the rate of Ventax clearance and increasing the dose in response to an exacerbation of symptoms without first measuring the serum Ventax concentration to determine whether a dose increase is safe.
Several studies have described the clinical manifestations of Ventax overdose following oral administration and attempted to determine the factors that predict life-threatening toxicity. In general, patients who experience an acute overdose are less likely to experience seizures than patients who have experienced a chronic overdosage, unless the peak serum Ventax concentration is > 100 mcg/mL. After a chronic overdosage, generalized seizures, life-threatening cardiac arrhythmias, and death may occur at serum Ventax concentrations > 30 mcg/mL. The severity of toxicity after chronic overdosage is more strongly correlated with the patient's age than the peak serum Ventax concentration; patients > 60 years are at the greatest risk for severe toxicity and mortality after a chronic overdosage. Pre-existing or concurrent disease may also significantly increase the susceptibility of a patient to a particular toxic manifestation, e.g., patients with neurologic disorders have an increased risk of seizures and patients with cardiac disease have an increased risk of cardiac arrhythmias for a given serum Ventaxconcentration compared to patients without the underlying disease.
The frequency of various reported manifestations of oral Ventax overdose according to the mode of overdose are listed in Table IV.
Other manifestations of Ventax toxicity include increases in serum calcium, creatine kinase, myoglobin and leukocyte count, decreases in serum phosphate and magnesium, acute myocardial infarction, and urinary retention in men with obstructive uropathy. Hypercalcemia has been reported in a patient with hyperthyroid disease at therapeutic Ventax concentrations.
Seizures associated with serum Ventax concentrations > 30 mcg/mL are often resistant to anticonvulsant therapy and may result in irreversible brain injury if not rapidly controlled. Death from Ventax toxicity is most often secondary to cardiorespiratory arrest and/or hypoxic encephalopathy following prolonged generalized seizures or intractable cardiac arrhythmias causing hemodynamic compromise.
Overdose ManagementGeneral Recommendations for Patients with Symptoms of Ventax Overdose or Serum Ventax Concentrations > 30 mcg/mL while receiving intravenous Ventax.
Increasing the rate of Ventax clearance by extracorporeal methods may rapidly decrease serum concentrations, but the risks of the procedure must be weighed against the potential benefit. Charcoal hemoperfusion is the most effective method of extracorporeal removal, increasing Ventax clearance up to six fold, but serious complications, including hypotension, hypocalcemia, platelet consumption and bleeding diatheses may occur. Hemodialysis is about as efficient as multiple-dose oral activated charcoal and has a lower risk of serious complications than charcoal hemoperfusion. Hemodialysis should be considered as an alternative when charcoal hemoperfusion is not feasible and multiple-dose oral charcoal is ineffective because of intractable emesis. Serum Ventax concentrations may rebound 5-10 mcg/mL after discontinuation of charcoal hemoperfusion or hemodialysis due to redistribution of Ventax from the tissue compartment. Peritoneal dialysis is ineffective for Ventax removal; exchange transfusions in neonates have been minimally effective.
GeneralThe chronicity and pattern of theophylline overdosage significantly influences clinical manifestations of toxicity, management and outcome. There are two common presentations: (1) acute overdose, i.e., ingestion of a single large excessive dose ( > 10 mg/kg) as occurs in the context of an attempted suicide or isolated medication error, and (2) chronic overdosage, i.e., ingestion of repeated doses that are excessive for the patient's rate of theophylline clearance. The most common causes of chronic theophylline overdosage include patient or care giver error in dosing, healthcare professional prescribing of an excessive dose or a normal dose in the presence of factors known to decrease the rate of theophylline clearance, and increasing the dose in response to an exacerbation of symptoms without first measuring the serum theophylline concentration to determine whether a dose increase is safe.
Severe toxicity from theophylline overdose is a relatively rare event. In one health maintenance organization, the frequency of hospital admissions for chronic overdosage of theophylline was about 1 per 1000 person-years exposure. In another study, among 6000 blood samples obtained for measurement of serum theophylline concentration, for any reason, from patients treated in an emergency department, 7% were in the 20-30 mcg/mL range and 3% were > 30 mcg/mL. Approximately two-thirds of the patients with serum theophylline concentrations in the 20-30 mcg/mL range had one or more manifestations of toxicity while > 90% of patients with serum theophylline concentrations > 30 mcg/mL were clinically intoxicated. Similarly, in other reports, serious toxicity from theophylline is seen principally at serum concentrations > 30 mcg/mL.
Several studies have described the clinical manifestations of theophylline overdose and attempted to determine the factors that predict life-threatening toxicity. In general, patients who experience an acute overdose are less likely to experience seizures than patients who have experienced a chronic overdosage, unless the peak serum theophylline concentration is > 100 mcg/mL. After a chronic overdosage, generalized seizures, life-threatening cardiac arrhythmias, and death may occur at serum theophylline concentrations > 30 mcg/mL. The severity of toxicity after chronic overdosage is more strongly correlated with the patient's age than the peak serum theophylline concentration; patients > 60 years are at the greatest risk for severe toxicity and mortality after a chronic overdosage. Pre-existing or concurrent disease may also significantly increase the susceptibility of a patient to a particular toxic manifestation, e.g., patients with neurologic disorders have an increased risk of seizures and patients with cardiac disease have an increased risk of cardiac arrhythmias for a given serum theophylline concentration compared to patients without the underlying disease.
The frequency of various reported manifestations of theophylline overdose according to the mode of overdose are listed in Table IV.
Other manifestations of theophylline toxicity include increases in serum calcium, creatine kinase, myoglobin and leukocyte count, decreases in serum phosphate and magnesium, acute myocardial infarction, and urinary retention in men with obstructive uropathy. Seizures associated with serum theophylline concentrations > 30 mcg/mL are often resistant to anticonvulsant therapy and may result in irreversible brain injury if not rapidly controlled. Death from theophylline toxicity is most often secondary to cardiorespiratory arrest and/or hypoxic encephalopathy following prolonged generalized seizures or intractable cardiac arrhythmias causing hemodynamic compromise.
Overdose ManagementGeneral Recommendations for Patients with Symptoms of Theophylline Overdose or Serum Theophylline Concentrations > 30 mcg/mL (Note: Serum theophylline concentrations may continue to increase after presentation of the patient for medical care.)
Increasing the rate of theophylline clearance by extracorporeal methods may rapidly decrease serum concentrations, but the risks of the procedure must be weighed against the potential benefit. Charcoal hemoperfusion is the most effective method of extracorporeal removal, increasing theophylline clearance up to six fold, but serious complications, including hypotension, hypocalcemia, platelet consumption and bleeding diatheses may occur. Hemodialysis is about as efficient as multiple-dose oral activated charcoal and has a lower risk of serious complications than charcoal hemoperfusion. Hemodialysis should be considered as an alternative when charcoal hemoperfusion is not feasible and multiple-dose oral charcoal is ineffective because of intractable emesis. Serum theophylline concentrations may rebound 5-10 mcg/mL after discontinuation of charcoal hemoperfusion or hemodialysis due to redistribution of theophylline from the tissue compartment. Peritoneal dialysis is ineffective for theophylline removal; exchange transfusions in neonates have been minimally effective.
Ventax Elixir is contraindicated in patients with a history of hypersensitivity to theophylline or other components in the product.
Ventax in 5% Dextrose Injections USP are contraindicated in patients with a history of hypersensitivity to Ventax or other components in the product.
Solutions containing dextrose may be contraindicated in patients with known allergy to corn or corn products.
Ventax (theophylline anhydrous capsule) ® is contraindicated in patients with a history of hypersensitivity to theophylline or other components in the product.
Adverse reactions associated with theophylline are generally mild when peak serum theophylline concentrations are < 20 mcg/mL and mainly consist of transient caffeine-like adverse effects such as nausea, vomiting, headache, and insomnia. When peak serum theophylline concentrations exceed 20 mcg/mL, however, theophylline produces a wide range of adverse reactions including persistent vomiting, cardiac arrhythmias, and intractable seizures which can be lethal (see OVERDOSAGE). The transient caffeine-like adverse reactions occur in about 50% of patients when theophylline therapy is initiated at doses higher than recommended initial doses (e.g., > 300 mg/day in adults and > 12 mg/kg/day in children beyond > 1 year of age). During the initiation of theophylline therapy, caffeine-like adverse effects may transiently alter patient behavior, especially in school age children, but this response rarely persists.
Initiation of theophylline therapy at a low dose with subsequent slow titration to a predetermined agerelated maximum dose will significantly reduce the frequency of these transient adverse effects (see In a small percentage of patients ( < 3% of children and < 10% of adults) the caffeine-like adverse effects persist during maintenance therapy, even at peak serum theophylline concentrations within the therapeutic range (i.e., 10-20 mcg/mL). Dosage reduction may alleviate the caffeine-like adverse effects in these patients, however, persistent adverse effects should result in a reevaluation of the need for continued theophylline therapy and the potential therapeutic benefit of alternative treatment.
Other adverse reactions that have been reported at serum theophylline concentrations < 20 mcg/mL include diarrhea, irritability, restlessness, fine skeletal muscle tremors, and transient diuresis. In patients with hypoxia secondary to COPD, multifocal atrial tachycardia and flutter have been reported at serum theophylline concentrations ≥ 15 mcg/mL. There have been a few isolated reports of seizures at serum theophylline concentrations < 20 mcg/mL in patients with an underlying neurological disease or in elderly patients. The occurrence of seizures in elderly patients with serum theophylline concentrations < 20 mcg/mL may be secondary to decreased protein binding resulting in a larger proportion of the total serum theophylline concentration in the pharmacologically active unbound form. The clinical characteristics of the seizures reported in patients with serum theophylline concentrations < 20 mcg/mL have generally been milder than seizures associated with excessive serum theophylline concentrations resulting from an overdose (i.e., they have generally been transient, often stopped without anticonvulsant therapy, and did not result in neurological residua).
Table IV: Manifestations of theophylline toxicity.*
Sign/Symptom | Percentage of patients reported with sign or symptom | |||
Acute Overdose (Large Single Inges tion) | Chronic Overdos age (Multiple Exces sive Doses ) | |||
Study 1 (n=157) | Study 2 (n=14) | Study 1 (n=92) | Study 2 (n=102) | |
Asymptomatic | NR** | 0 | NR** | 6 |
Gastrointestinal | ||||
Vomiting | 73 | 93 | 30 | 61 |
Abdominal Pain | NR** | 21 | NR** | 12 |
Diarrhea | NR** | 0 | NR** | 14 |
Hematemesis | NR** | 0 | NR** | 2 |
Metabolic/Other | ||||
Hypokalemia | 85 | 79 | 44 | 43 |
Hyperglycemia | 98 | NR** | 18 | NR** |
Acid/base disturbance | 34 | 21 | 9 | 5 |
Rhabdomyolysis | NR** | 7 | NR** | 0 |
Cardiovascular | ||||
Sinus tachycardia | 100 | 86 | 100 | 62 |
Other supraventricular tachycardias | 2 | 21 | 12 | 14 |
Ventricular premature beats | 3 | 21 | 10 | 19 |
Atrial fibrillation or flutter | 1 | NR** | 12 | NR** |
Multifocal atrial tachycardia | 0 | NR** | 2 | NR** |
Ventricular arrhythmias with hemodynamic instability | 7 | 14 | 40 | 0 |
Hypotension/shock | NR** | 21 | NR** | 8 |
Neurologic | ||||
Nervousness | NR** | 64 | NR** | 21 |
Tremors | 38 | 29 | 16 | 14 |
Disorientation | NR** | 7 | NR** | 11 |
Seizures | 5 | 14 | 14 | 5 |
Death | 3 | 21 | 10 | 4 |
*These data are derived from two studies in patients with serum theophylline concentrations > 30 mcg/mL. In the first study (Study #1 - Shanon, Ann Intern Med 1993;119:1161-67), data were prospectively collected from 249 consecutive cases of theophylline toxicity referred to a regional poison center for consultation. In the second study (Study #2 - Sessler, Am J Med 1990;88:567-76), data were retrospectively collected from 116 cases with serum theophylline concentrations > 30 three emergency departments. Differences in the incidence of manifestations of theophylline toxicity between the two studies may reflect sample selection as a result of study design (e.g., in Study #1, 48% of the patients had acute intoxications versus only 10% in Study #2) and different methods of reporting results. **NR = Not reported in a comparable manner. |
Adverse reactions associated with Ventax are generally mild when serum Ventax concentrations are < 20 mcg/mL and mainly consist of transient caffeine-like adverse effects such as nausea, vomiting, headache, and insomnia. When serum Ventax concentrations exceed 20 mcg/mL, however, Ventax produces a wide range of adverse reactions including persistent vomiting, cardiac arrhythmias, and intractable seizures which can be lethal (see OVERDOSAGE).
Other adverse reactions that have been reported at serum Ventax concentrations < 20 mcg/mL include diarrhea, irritability, restlessness, fine skeletal muscle tremors, and transient diuresis. In patients with hypoxia secondary to COPD, multifocal atrial tachycardia and flutter have been reported at serum Ventax concentrations ¡Ý15 mcg/mL. There have been a few isolated reports of seizures at serum Ventax concentrations < 20 mcg/mL in patients with an underlying neurological disease or in elderly patients. The occurrence of seizures in elderly patients with serum Ventax concentrations < 20 mcg/mL may be secondary to decreased protein binding resulting in a larger proportion of the total serum Ventax concentration in the pharmacologically active unbound form. The clinical characteristics of the seizures reported in patients with serum Ventax concentrations < 20 mcg/mL have generally been milder than seizures associated with excessive serum Ventax concentrations resulting from an overdose (i.e., they have generally been transient, often stopped without anticonvulsant therapy, and did not result in neurological residua). Hypercalcemia has been reported in a patient with hyperthyroid disease at therapeutic Ventax concentrations (see OVERDOSAGE).
Table IV. Manifestations of Ventax toxicity.*
Sign/Symptom | Percentage of patients reported with sign or symptom | |||
Acute Overdose (Large Single Ingestion) | Chronic Overdosage (Multiple Excessive Doses) | |||
Study 1 (n=157) | Study 2 (n=14) | Study 1 (n=92) | Study 2 (n=102) | |
Asymptomatic | NR** | 0 | NR** | 6 |
Gastrointestinal | ||||
Vomiting | 73 | 93 | 30 | 61 |
Abdominal Pain | NR** | 21 | NR** | 12 |
Diarrhea | NR** | 0 | NR** | 14 |
Hematemesis | NR** | 0 | NR** | 2 |
Metabolic/Other | ||||
Hypokalemia | 85 | 79 | 44 | 43 |
Hyperglycemia | 98 | NR** | 18 | NR** |
Acid/base disturbance | 34 | 21 | 9 | 5 |
Rhabdomyolysis | NR** | 7 | NR** | 0 |
Cardiovascular | ||||
Sinus tachycardia | 100 | 86 | 100 | 62 |
Other supraventricular tachycardias | 2 | 21 | 12 | 14 |
Ventricular premature beats | 3 | 21 | 10 | 19 |
Atrial fibrillation or flutter | 1 | NR** | 12 | NR** |
Multifocal atrial tachycardia | 0 | NR** | 2 | NR** |
Ventricular arrhythmias with hemodynamic instability | 7 | 14 | 40 | 0 |
Hypotension/shock | NR** | 21 | NR** | 8 |
Neurologic | ||||
Nervousness | NR** | 64 | NR** | 21 |
Tremors | 38 | 29 | 16 | 14 |
Disorientation | NR** | 7 | NR** | 11 |
Seizures | 5 | 14 | 14 | 5 |
Death | 3 | 21 | 10 | 4 |
* These data are derived from two studies in patients with serum Ventax concentrations > 30 mcg/mL. In the first study (Study #1 - Shanon, Ann lntern Med 1993;119:1161-67), data were prospectively collected from 249 consecutive cases of Ventax toxicity referred to a regional poison center for consultation. In the second study (Study #2 - Sessler, Am J Med 1990;88:567-76), data were retrospectively collected from 116 cases with serum Ventax concentrations > 30 mcg/mL among 6000 blood samples obtained for measurement of serum Ventax concentrations in three emergency departments. Differences in the incidence of manifestations of Ventax toxicity between the two studies may reflect sample selection as a result of study design (e.g., in Study #1, 48% of the patients had acute intoxications versus only 10% in Study #2) and different methods of reporting results. ** NR = Not reported in a comparable manner. |
Reactions which may occur because of the solution or the technique of administration include febrile response, infection at the site of injection, venous thrombosis or phlebitis extending from the site of injection, extravasation and hypervolemia.
Adverse reactions associated with theophylline are generally mild when peak serum theophylline concentrations are < 20 mcg/ mL and mainly consist of transient caffeine-like adverse effects such as nausea, vomiting, headache, and insomnia. When peak serum theophylline concentrations exceed 20 mcg/mL, however, theophylline produces a wide range of adverse reactions including persistent vomiting, cardiac arrhythmias, and intractable seizures which can be lethal (see OVERDOSAGE). The transient caffeine-like adverse reactions occur in about 50% of patients when theophylline therapy is initiated at doses higher than recommended initial doses (e.g., > 300 mg/day in adults and > 12 mg/kg/day in children beyond 1 year of age). During the initiation of theophylline therapy, caffeine-like adverse effects may transiently alter patient behavior, especially in school age children, but this response rarely persists. Initiation of theophylline therapy at a low dose with subsequent slow titration to a predetermined age-related maximum dose will significantly reduce the frequency of these transient adverse effects (see DOSAGE AND ADMINISTRATION, Table V). In a small percentage of patients ( < 3% of children and < 10% of adults) the caffeine-like adverse effects persist during maintenance therapy, even at peak serum theophylline concentrations within the therapeutic range (i.e., 10-20 mcg/mL). Dosage reduction may alleviate the caffeine-like adverse effects in these patients, however, persistent adverse effects should result in a reevaluation of the need for continued theophylline therapy and the potential therapeutic benefit of alternative treatment.
Other adverse reactions that have been reported at serum theophylline concentrations < 20 mcg/mL include diarrhea, irritability, restlessness, fine skeletal muscle tremors, and transient diuresis. In patients with hypoxia secondary to COPD, multifocal atrial tachycardia and flutter have been reported at serum theophylline concentrations ≥ 15 mcg/mL. There have been a few isolated reports of seizures at serum theophylline concentrations < 20 mcg/mL in patients with an underlying neurological disease or in elderly patients. The occurrence of seizures in elderly patients with serum theophylline concentrations < 20 mcg/mL may be secondary to decreased protein binding resulting in a larger proportion of the total serum theophylline concentration in the pharmacologically active unbound form. The clinical characteristics of the seizures reported in patients with serum theophylline concentrations < 20 mcg/mL have generally been milder than seizures associated with excessive serum theophylline concentrations resulting from an overdose (i.e., they have generally been transient, often stopped without anticonvulsant therapy, and did not result in neurological residua).
Table IV. Manifestations of theophylline toxicity.*
Percentage of patients reported with sign or symptom | ||||
Acute Overdose (Large Single Ingestion) | Chronic Overdosage (Multiple Excessive Doses) | |||
Sign/Symptom | Study 1 (n=157) | Study 2 (n=14) | Study 1 (n=92) | Study 2 (n=102) |
Asymptomatic | NR** | 0 | NR** | 6 |
Gastrointestinal | ||||
Vomiting | 73 | 93 | 30 | 61 |
Abdominal pain | NR** | 21 | NR** | 12 |
Diarrhea | NR** | 0 | NR** | 14 |
Hematemesis | NR** | 0 | NR** | 2 |
Metabolic/Other | ||||
Hypokalemia | 85 | 79 | 44 | 43 |
Hyperglycemia | 98 | NR** | 18 | NR** |
Acid/base disturbance | 34 | 21 | 9 | 5 |
Rhabdomyolysis | NR** | 7 | NR** | 0 |
Cardiovascular | ||||
Sinus tachycardia | 100 | 86 | 100 | 62 |
Other supraventricular tachycardias | 2 | 21 | 12 | 14 |
Ventricular premature beats | 3 | 21 | 10 | 19 |
Atrial fibrillation or flutter | 1 | NR** | 12 | NR** |
Multifocal atrial tachycardia | 0 | NR** | 2 | NR** |
Ventricular arrhythmias with | ||||
hemodynamic instability | 7 | 14 | 40 | 0 |
Hypotension/shock | NR** | 21 | NR** | 8 |
Neurologic | ||||
Nervousness | NR** | 64 | NR** | 21 |
Tremors | 38 | 29 | 16 | 14 |
Disorientation | NR** | 7 | NR** | 11 |
Seizures | 5 | 14 | 14 | 5 |
Death | 3 | 21 | 10 | 4 |
* These data are derived from two studies in patients with serum theophylline concentrations > 30 mcg/mL. In the first study (Study #1—Shanon, Ann Intern Med 1993;119:1161-67), data were prospectively collected from 249 consecutive cases of theophylline toxicity referred to a regional poison center for consultation. In the second study (Study #2—Sessler, Am J Med 1990;88:567-76), data were retrospectively collected from 116 cases with serum theophylline concentrations > 30 mcg/mL among 6000 blood samples obtained for measurement of serum theophylline concentrations in three emergency departments. Differences in the incidence of manifestations of theophylline toxicity between the two studies may reflect sample selection as a result of study design (e.g., in Study #1, 48% of the patients had acute intoxications versus only 10% in Study #2) and different methods of reporting results. ** NR =Not reported in a comparable manner. |
Ventax in 5% Dextrose Injections USP are indicated as an adjunct to inhaled beta-2 selective agonists and systemically administered corticosteroids for the treatment of acute exacerbations of the symptoms and reversible airflow obstruction associated with asthma and other chronic lung diseases, e.g., emphysema and chronic bronchitis.
Theophylline is rapidly and completely absorbed after oral administration in solution or immediaterelease solid oral dosage form. Theophylline does not undergo any appreciable pre-systemic elimination, distributes freely into fat-free tissues and is extensively metabolized in the liver.
The pharmacokinetics of theophylline vary widely among similar patients and cannot be predicted by age, sex, body weight or other demographic characteristics. In addition, certain concurrent illnesses and alterations in normal physiology (see Table I) and co-administration of other drugs (see Table II) can significantly alter the pharmacokinetic characteristics of theophylline. Within-subject variability in metabolism has also been reported in some studies, especially in acutely ill patients. It is, therefore, recommended that serum theophylline concentrations be measured frequently in acutely ill patients (e.g., at 24-hour intervals) and periodically in patients receiving long-term therapy, e.g., at 6-12 month intervals. More frequent measurements should be made in the presence of any condition that may significantly alter theophylline clearance (see PRECAUTIONS, Laboratory tests).
Table I: Mean and range of total body clearance and half-life of theophylline related to age and altered physiological states¶
Population characteristics | Total body clearance* mean (range)†† (mL/kg/min) | Half-life mean (range)†† (hr) |
Age | ||
Premature neonates postnatal age 3-15 days | 0.29 (0.09-0.49) | 30 (17-43) |
postnatal age 25-57 days | 0.64 (0.04-1.2) | 20 (9.4-30.6) |
T erm infants | ||
postnatal age 1-2 days | NR† | 25.7 (25-26.5) |
postnatal age 3-30 weeks | NR† | 11 (6-29) |
Children | ||
1-4 years | 1.7 (0.5-2.9) | 3.4 (1.2-5.6) |
4-12 years | 1.6 (0.8-2.4) | NR† |
13-15 years | 0.9 (0.48-1.3) | NR† |
16-17 years | 1.4 (0.2-2.6) | 3.7 (1.5-5.9) |
Adults (16-60 years)otherwise healthy | ||
non-smoking asthmatics | 0.65 (0.27-1.03) | 8.7 (6.1-12.8) |
Elderly ( > 60 years) | ||
non-smokers with normal cardiac, liver, and renal function | 0.41 (0.21-0.61) | 9.8 (1.6-18) |
Concurrent illness or altered physiological state | ||
Acute pulmonary edema | 0.33** (0.07-2.45) | 19** (3.1-82) |
C0PD- > 60 years, stable | 0.54 (0.44-0.64) | 11 (9.4-12.6) |
non-smoker > 1 year | ||
COPD with cor pulmonale | 0.48 (0.08-0.88) | NR† |
Cystic fibrosis (14-28 years) | 1.25 (0.31-2.2) | 6.0 (1.8-10.2) |
Fever associated with acute viral respiratory illness (children 9-15 years) | NR† | 7.0 (1.0-13) |
Liver disease - cirrhosis | 0.31** (0.1-0.7) | 32** (10-56) |
acute hepatitis | 0.35 (0.25-0.45) | 19.2 (16.6-21.8) |
cholestasis | 0.65 (0.25-1.45) | 14.4 (5.7-31.8) |
Pregnancy - 1st trimester | NR† | 8.5 (3.1-13.9) |
2nd trimester | NR† | 8.8 (3.8-13.8) |
3rd trimester | NR† | 13.0 (8.4-17.6) |
Sepsis with multi-organ failure | 0.47 (0.19-1.9) | 18.8 (6.3-24.1) |
Thyroid disease - hypothyroid | 0.38 (0.13-0.57) | 11.6 (8.2-25) |
hyperthyroid | 0.8 (0.68-0.97) | 4.5 (3.7-5.6) |
¶For various North American patient populations from literature reports. Different rates of elimination and consequent dosage requirements have been observed among other peoples. *Clearance represents the volume of blood completely cleared of theophylline by the liver in one minute. Values listed were generally determined at serum theophylline concentrations < 20 mcg/mL; clearance may decrease and half-life may increase at higher serum concentrations due to non-linear pharmacokinetics. ††Reported range or estimated range (mean ± 2 SD) where actual range not reported. †NR = not reported or not reported in a comparable format. **Median |
Note: In addition to the factors listed above, theophylline clearance is increased and half-life decreased by low carbohydrate/high protein diets, parenteral nutrition, and daily consumption of charcoal-broiled beef. A high carbohydrate/low protein diet can decrease the clearance and prolong the half-life of theophylline.
AbsorptionTheophylline is rapidly and completely absorbed after oral administration in solution or immediaterelease solid oral dosage form. After a single dose of 5 mg/kg in adults, a mean peak serum concentration of about 10 mcg/mL (range 5-15 mcg/mL) can be expected 1-2 hr after the dose. Coadministration of theophylline with food or antacids does not cause clinically significant changes in the absorption of theophylline from immediate-release dosage forms.
DistributionOnce theophylline enters the systemic circulation, about 40% is bound to plasma protein, primarily albumin. Unbound theophylline distributes throughout body water, but distributes poorly into body fat. The apparent volume of distribution of theophylline is approximately 0.45 L/kg (range 0.3-0.7 L/kg) based on ideal body weight. Theophylline passes freely across the placenta, into breast milk and into the cerebrospinal fluid (CSF). Saliva theophylline concentrations approximate unbound serum concentrations, but are not reliable for routine or therapeutic monitoring unless special techniques are used. An increase in the volume of distribution of theophylline, primarily due to reduction in plasma protein binding, occurs in premature neonates, patients with hepatic cirrhosis, uncorrected acidemia, the elderly and in women during the third trimester of pregnancy. In such cases, the patient may show signs of toxicity at total (bound +unbound) serum concentrations of theophylline in the therapeutic range (10- 20 mcg/mL) due to elevated concentrations of the pharmacologically active unbound drug. Similarly, a patient with decreased theophylline binding may have a subtherapeutic total drug concentration while the pharmacologically active unbound concentration is in the therapeutic range. If only total serum theophylline concentration is measured, this may lead to an unnecessary and potentially dangerous dose increase. In patients with reduced protein binding, measurement of unbound serum theophylline concentration provides a more reliable means of dosage adjustment than measurement of total serum theophylline concentration. Generally, concentrations of unbound theophylline should be maintained in the range of 6-12 mcg/mL.
MetabolismFollowing oral dosing, theophylline does not undergo any measurable first-pass elimination. In adults and children beyond one year of age, approximately 90% of the dose is metabolized in the liver. Biotransformation takes place through demethylation to 1-methylxanthine and 3-methylxanthine and hydroxylation to 1,3-dimethyluric acid. 1-methylxanthine is further hydroxylated, by xanthine oxidase, to 1-methyluric acid. About 6% of a theophylline dose is N-methylated to caffeine. Theophylline demethylation to 3-methylxanthine is catalyzed by cytochrome P-450 1A2, while cytochromes P-450 2E1 and P-450 3A3 catalyze the hydroxylation to 1,3-dimethyluric acid. Demethylation to 1- methylxanthine appears to be catalyzed either by cytochrome P-450 1A2 or a closely related cytochrome. In neonates, the N-demethylation pathway is absent while the function of the hydroxylation pathway is markedly deficient. The activity of these pathways slowly increases to maximal levels by one year of age.
Caffeine and 3-methylxanthine are the only theophylline metabolites with pharmacologic activity. 3- methylxanthine has approximately one tenth the pharmacologic activity of theophylline and serum concentrations in adults with normal renal function are < 1 mcg/mL. In patients with end-stage renal disease, 3-methylxanthine may accumulate to concentrations that approximate the unmetabolized theophylline concentration. Caffeine concentrations are usually undetectable in adults regardless of renal function. In neonates, caffeine may accumulate to concentrations that approximate the unmetabolized theophylline concentration and thus, exert a pharmacologic effect.
Both the N-demethylation and hydroxylation pathways of theophylline biotransformation are capacitylimited. Due to the wide intersubject variability of the rate of theophylline metabolism, non-linearity of elimination may begin in some patients at serum theophylline concentrations < 10 mcg/mL. Since this non-linearity results in more than proportional changes in serum theophylline concentrations with changes in dose, it is advisable to make increases or decreases in dose in small increments in order to achieve desired changes in serum theophylline concentrations (see DOSAGE AND ADMINISTRATION, Table VI). Accurate prediction of dose-dependency of theophylline metabolism in patients a priori is not possible, but patients with very high initial clearance rates (i.e., low steady state serum theophylline concentrations at above average doses) have the greatest likelihood of experiencing large changes in serum theophylline concentration in response to dosage changes.
ExcretionIn neonates, approximately 50% of the theophylline dose is excreted unchanged in the urine. Beyond the first three months of life, approximately 10% of the theophylline dose is excreted unchanged in the urine. The remainder is excreted in the urine mainly as 1,3-dimethyluric acid (35-40%), 1-methyluric acid (20-25%) and 3-methylxanthine (15-20%). Since little theophylline is excreted unchanged in the urine and since active metabolites of theophylline (i.e., caffeine, 3-methylxanthine) do not accumulate to clinically significant levels even in the face of end-stage renal disease, no dosage adjustment for renal insufficiency is necessary in adults and children > 3 months of age. In contrast, the large fraction of the theophylline dose excreted in the urine as unchanged theophylline and caffeine in neonates requires careful attention to dose reduction and frequent monitoring of serum theophylline concentrations in neonates with reduced renal function (See WARNINGS).
Serum Concentrations At Steady StateAfter multiple doses of theophylline, steady state is reached in 30-65 hours (average 40 hours) in adults. At steady state, on a dosage regimen with 6-hour intervals, the expected mean trough concentration is approximately 60% of the mean peak concentration, assuming a mean theophylline halflife of 8 hours. The difference between peak and trough concentrations is larger in patients with more rapid theophylline clearance. In patients with high theophylline clearance and half-lives of about 4-5 hours, such as children age 1 to 9 years, the trough serum theophylline concentration may be only 30% of peak with a 6-hour dosing interval. In these patients a slow release formulation would allow a longer dosing interval (8-12 hours) with a smaller peak/trough difference.
OverviewThe pharmacokinetics of Ventax vary widely among similar patients and cannot be predicted by age, sex, body weight or other demographic characteristics. In addition, certain concurrent illnesses and alterations in normal physiology (see Table I) and co-administration of other drugs (see Table II) can significantly alter the pharmacokinetic characteristics of Ventax. Within-subject variability in metabolism has also been reported in some studies, especially in acutely ill patients. It is, therefore, recommended that serum Ventax concentrations be measured frequently in acutely ill patients receiving intravenous Ventax (e.g., at 24-hr intervals). More frequent measurements should be made during the initiation of therapy and in the presence of any condition that may significantly alter Ventax clearance (see PRECAUTIONS, Laboratory tests).
Table l. Mean and range of total body clearance and half-life of Ventax related to age and altered physiological states.¶
Population characteristics | Total body clearance* mean (range)†† (mL/kg/min) | Half-life mean (range)†† (hr) |
Age | ||
Premature neonates | 0.29 (0.09-0.49) | 30 (17-43) |
postnatal age 3-15 days | 0.64 (0.04-1.2) | 20 (9.4-30.6) |
postnatal age 25-57 days | NR† | 25.7 (25-26.5) |
Term infants | ||
postnatal age 1-2 days | NR† | 11 (6-29) |
postnatal age 3-30 weeks | 1.7 (0.5-2.9) | 3.4 (1.2-5.6) |
Children | ||
1-4 years | 1.6 (0.8-2.4) | NR† |
4-12 years | 0.9 (0.48-1.3) | NR† |
13-15 years | 1.4 (0.2-2.6) | 3.7 (1.5-5.9) |
6-17 years | 0.65 (0.27-1.03) | 8.7 (6.1-12.8) |
Adults (16-60 years) otherwise healthy non-smoking asthmatics | 0.41 (0.21-0.61) | 9.8 (1.6-18) |
Elderly ( > 60 years) non-smokers with normal cardiac, liver, and renal function | 0.33** (0.07-2.45) | 19** (3.1-82) |
Concurrent illness or altered physiological state | ||
Acute pulmonary edema | 0.54 (0.44-0.64) | 11 (9.4-12.6) |
COPD- > 60 years, stable non-smoker > 1 year | 0.48 (0.08-0.88) | NR† |
COPD with cor pulmonale Cystic fibrosis (14-28 years) | 1.25 (0.31-2.2) | 6.0 (1.8-10.2) |
Fever associated with-acute viral respiratory illness (children 9-15 years) | NR† | 7.0 (1.0-13) |
Liver disease - cirrhosis | 0.31** (0.1-0.7) | 32** (10-56) |
acute hepatitis | 0.35 (0.25-0.45) | 19.2 (16.6-21.8) |
cholestasis | 0.65 (0.25-1.45) | 14.4 (5.7-31.8) |
Pregnancy - 1st trimester | NR† | 8.5 (3.1-13.9) |
2nd trimester | NR† | 8.8 (3.8-13.8) |
3rd trimester | NR† | 13.0 (8.4-17.6) |
Sepsis with multi-organ failure | 0.47 (0.19-1.9) | 18.8 (6.3-24.1) |
Thyroid disease - hypothyroid | 0.38 (0.13-0.57) | 11.6 (8.2-25) |
hyperthyroid | 0.8 (0.68-0.97) | 4.5 (3.7-5.6) |
¶ For various North American patient populations from literature reports. Different rates of elimination and consequent dosage requirements have been observed among other peoples. * Clearance represents the volume of blood completely cleared of Ventax by the liver in one minute. Values listed were generally determined at serum Ventax concentrations < 20 mcg/mL; clearance may decrease and half-life may increase at higher serum concentrations due to non-linear pharmacokinetics. † † Reported range or estimated range (mean ± 2 SD) where actual range not reported. † NR = not reported or not reported in a comparable format. ** Median |
Note: In addition to the factors listed above, Ventax clearance is increased and half-life decreased by low carbohydrate/high protein diets, parenteral nutrition, and daily consumption of charcoal-broiled beef. A high carbohydrate/low protein diet can decrease the clearance and prolong the half-life of Ventax.
DistributionOnce Ventax enters the systemic circulation, about 40% is bound to plasma protein, primarily albumin. Unbound Ventax distributes throughout body water, but distributes poorly into body fat. The apparent volume of distribution of Ventax is approximately 0.45 L/kg (range 0.3-0.7 L/kg) based on ideal body weight. Ventax passes freely across the placenta, into breast milk and into the cerebrospinal fluid (CSF). Saliva Ventax concentrations approximate unbound serum concentrations, but are not reliable for routine or therapeutic monitoring unless special techniques are used. An increase in the volume of distribution of Ventax, primarily due to reduction in plasma protein binding, occurs in premature neonates, patients with hepatic cirrhosis, uncorrected acidemia, the elderly and in women during the third trimester of pregnancy. In such cases, the patient may show signs of toxicity at total (bound + unbound) serum concentrations of Ventax in the therapeutic range (10-20 mcg/mL) due to elevated concentrations of the pharmacologically active unbound drug. Similarly, a patient with decreased Ventax binding may have a sub-therapeutic total drug concentration while the pharmacologically active unbound concentration is in the therapeutic range. If only total serum Ventax concentration is measured, this may lead to an unnecessary and potentially dangerous dose increase. In patients with reduced protein binding, measurement of unbound serum Ventax concentration provides a more reliable means of dosage adjustment than measurement of total serum Ventax concentration. Generally, concentrations of unbound Ventax should be maintained in the range of 6-12 mcg/mL.
MetabolismIn adults and children beyond one year of age, approximately 90% of the dose is metabolized in the liver. Biotransformation takes place through demethylation to 1-methylxanthine and 3-methylxanthine and hydroxylation to 1,3-dimethyluric acid. 1-methylxanthine is further hydroxylated, by xanthine oxidase, to 1-methyluric acid. About 6% of a Ventax dose is N-methylated to caffeine. Ventax demethylation to 3-methylxanthine is catalyzed by cytochrome P-450 1A2, while cytochromes P-450 2E1 and P-450 3A3 catalyze the hydroxylation to 1,3-dimethyluric acid. Demethylation to 1-methylxanthine appears to be catalyzed either by cytochrome P-450 1A2 or a closely related cytochrome. In neonates, the N-demethylation pathway is absent while the function of the hydroxylation pathway is markedly deficient. The activity of these pathways slowly increases to maximal levels by one year of age.
Caffeine and 3-methylxanthine are the only Ventax metabolites with pharmacologic activity. 3-methylxanthine has approximately one tenth the pharmacologic activity of Ventax and serum concentrations in adults with normal renal function are < 1 mcg/mL. In patients with endstage renal disease, 3-methylxanthine may accumulate to concentrations that approximate the unmetabolized Ventax concentration. Caffeine concentrations are usually undetectable in adults regardless of renal function. In neonates, caffeine may accumulate to concentrations that approximate the unmetabolized Ventax concentration and thus, exert a pharmacologic effect.
Both the N-demethylation and hydroxylation pathways of Ventax biotransformation are capacity-limited. Due to the wide intersubject variability of the rate of Ventax metabolism, non-linearity of elimination may begin in some patients at serum Ventax concentrations < 10 mcg/mL. Since this non-linearity results in more than proportional changes in serum Ventax concentrations with changes in dose, it is advisable to make increases or decreases in dose in small increments in order to achieve desired changes in serum Ventax concentrations (see DOSAGE AND ADMINISTRATION, Table VI). Accurate prediction of dosedependency of Ventax metabolism in patients a priori is not possible, but patients with very high initial clearance rates (i.e., low steady state serum Ventax concentrations at above average doses) have the greatest likelihood of experiencing large changes in serum Ventax concentration in response to dosage changes.
ExcretionIn neonates, approximately 50% of the Ventax dose is excreted unchanged in the urine. Beyond the first three months of life, approximately 10% of the Ventax dose is excreted unchanged in the urine. The remainder is excreted in the urine mainly as 1,3-dimethyluric acid (35-40%), 1-methyluric acid (20-25%) and 3-methylxanthine (15-20%). Since little Ventax is excreted unchanged in the urine and since active metabolites of Ventax (i.e., caffeine, 3-methylxanthine) do not accumulate to clinically significant levels even in the face of end-stage renal disease, no dosage adjustment for renal insufficiency is necessary in adults and children > 3 months of age. In contrast, the large fraction of the Ventax dose excreted in the urine as unchanged Ventax and caffeine in neonates requires careful attention to dose reduction and frequent monitoring of serum Ventax concentrations in neonates with reduced renal function (see WARNINGS).
Serum Concentrations at Steady StateIn a patient who has received no Ventax in the previous 24 hours, a loading dose of intravenous Ventax of 4.6 mg/kg, calculated on the basis of ideal body weight and administered over 30 minutes, on average, will produce a maximum postdistribution serum concentration of 10 mcg/mL with a range of 6-16 mcg/mL. In non-smoking adults, initiation of a constant intravenous Ventax infusion of 0.4 mg/kg/hr at the completion of the loading dose, on average, will result in a steady-state concentration of 10 mcg/mL with a range of 7-26 mcg/mL. The mean and range of steady-state serum concentrations are similar when the average child (age 1 to 9 years) is given a loading dose of 4.6 mg/kg Ventax followed by a constant intravenous infusion of 0.8 mg/kg/hr. (See DOSAGE AND ADMINISTRATION.)
OverviewTheophylline is rapidly and completely absorbed after oral administration in solution or immediate-release solid oral dosage form. Theophylline does not undergo any appreciable pre-systemic elimination, distributes freely into fat-free tissues and is extensively metabolized in the liver.
The pharmacokinetics of theophylline vary widely among similar patients and cannot be predicted by age, sex, body weight or other demographic characteristics. In addition, certain concurrent illnesses and alterations in normal physiology (see Table I) and co-administration of other drugs (see Table II) can significantly alter the pharmacokinetic characteristics of theophylline. Within-subject variability in metabolism has also been reported in some studies, especially in acutely ill patients. It is, therefore, recommended that serum theophylline concentrations be measured frequently in acutely ill patients (e.g., at 24-hr intervals) and periodically in patients receiving long-term therapy, e.g., at 6-12 month intervals. More frequent measurements should be made in the presence of any condition that may significantly alter theophylline clearance (see PRECAUTIONS, Laboratory Tests).
Table I. Mean and range of total body clearance and half-life of theophylline related to age and altered physiological states.¶
Population Characteristics | Total body clearance* mean (range)†† (mL/kg/min) | Half-life Mean (range)†† (hr) |
Age | ||
Premature neonates | ||
postnatal age 3-15 days | 0.29 (0.09-0.49) | 30 (17-43) |
postnatal age 25-57 days | 0.64 (0.04-1.2) | 20 (9.4-30.6) |
Term infants | ||
postnatal age 1-2 days | NR† | 25.7 (25-26.5) |
postnatal age 3-30 weeks | NR† | 11 (6-29) |
Children | ||
1-4 years | 1.7 (0.5-2.9) | 3.4 (1.2-5.6) |
4-12 years | 1.6 (0.8-2.4) | NR† |
13-15 years | 0.9 (0.48-1.3) | NR† |
6-17 years | 1.4 (0.2-2.6) | 3.7 (1.5-5.9) |
Adults (16-60 years) | ||
otherwise healthy non-smoking asthmatics | 0.65 (0.27-1.03) | 8.7 (6.1-12.8) |
Elderly ( > 60 years) | ||
non-smokers with normal cardiac, liver, and renal function | 0.41 (0.21-0.61) | 9.8 (1.6-18) |
Concurrent illness or altered physiological state | ||
Acute pulmonary edema | 0.33**(0.07-2.45) | 19**(3.1-82) |
COPD > 60 years, stable non-smoker > 1 year | 0.54 (0.44-0.64) | 11 (9.4-12.6) |
COPD with cor-pulmonale | 0.48 (0.08-0.88) | NR† |
Cystic fibrosis (14-28 years) | 1.25 (0.31-2.2) | 6.0 (1.8-10.2) |
Fever associated with acute viral respiratory illness (children 9-15 years) | NR† | 7.0 (1.0-13) |
Liver disease – cirrhosis | 0.31**(0.1-0.7) | 32**(10-56) |
acute hepatitis | 0.35 (0.25-0.45) | 19.2 (16.6-21.8) |
cholestasis | 0.65 (0.25-1.45) | 14.4 (5.7-31.8) |
Pregnancy – 1st trimester | NR† | 8.5 (3.1-13.9) |
2nd trimester | NR† | 8.8 (3.8-13.8) |
3rd trimester | NR† | 13.0 (8.4-17.6) |
Sepsis with multi-organ failure | 0.47 (0.19-1.9) | 18.8 (6.3-24.1) |
Thyroid disease – hypothyroid | 0.38 (0.13-0.57) | 11.6 (8.2-25) |
hyperthyroid | 0.8 (0.68-0.97) | 4.5 (3.7-5.6) |
¶ For various North American patient populations from literature reports. Different rates of elimination and consequent dosage requirements have been observed among other peoples. * Clearance represents the volume of blood completely cleared of theophylline by the liver in one minute. Values listed were generally determined at serum theophylline concentrations < 20 mcg/mL; clearance may decrease and half-life may increase at higher serum concentrations due to non-linear pharmacokinetics. †† Reported range or estimated range (mean ± 2 SD) where actual range not reported. † NR =not reported or not reported in a comparable format. ** Median Note: In addition to the factors listed above, theophylline clearance is increased and half-life decreased by low carbohydrate/high protein diets, parenteral nutrition, and daily consumption of charcoal-broiled beef. A high carbohydrate/low protein diet can decrease the clearance and prolong the half-life of theophylline. |
Theophylline is rapidly and completely absorbed after oral administration in solution or immediate-release solid oral dosage form. After a single immediate-release dose of 5 mg/kg in adults, a mean peak serum concentration of about 10 mcg/mL (range 5-15 mcg/ mL) can be expected 1-2 hr after dose. Co-administration of theophylline with food or antacids does not cause clinically significant changes in the absorption of theophylline from immediate-release dosage forms.
Ventax (theophylline anhydrous capsule) ® capsules contain hundreds of coated beads of theophylline. Each bead is an individual extended-release delivery system. After dissolution of the capsules these beads are released and distributed in the gastrointestinal tract, thus minimizing the probability of high local concentrations of theophylline at any particular site.
In a 6-day multiple-dose study involving 18 subjects (with theophylline clearance rates between 0.57 and 1.02 mL/kg/min) who had fasted overnight and 2 hours after morning dosing, Ventax (theophylline anhydrous capsule) ® given once daily in a dose of 1500 mg produced serum theophylline levels that ranged between 5.7 mcg/mL and 22 mcg/mL. The mean minimum and maximum values were 11.6 mcg/mL and 18.1 mcg/mL, respectively, with an average peak-trough difference of 6.5 mcg/mL. The mean percent fluctuation [(Cmax–Cmin /Cmin) x 100] equals 80%. A 24-hour single-dose study demonstrated an approximately proportional increase in serum levels as the dose was increased from 600 to 1500 mg.
Taking Ventax (theophylline anhydrous capsule) ® with a high-fat-content meal may result in a significant increase in the peak serum level and in the extent of absorption of theophylline as compared to administration in the fasted state (see PRECAUTIONS, Drug/Food Interactions).
Following the single-dose administration (8 mg/kg) of Ventax (theophylline anhydrous capsule) ® to 20 normal subjects who had fasted overnight and 2 hours after morning dosing, peak serum theophylline concentrations of 4.8 ± 1.5 (SD) mcg/mL were obtained at 13.3 ± 4.7 (SD) hours. The amount of the dose absorbed was approximately 13% at 3 hours, 31% at 6 hours, 55% at 12 hours, 70% at 16 hours, and 88% at 24 hours. The extent of theophylline bioavailability from Ventax (theophylline anhydrous capsule) ® was comparable to the most widely used 12-hour extended-release product when both products were administered every 12 hours.
DistributionOnce theophylline enters the systemic circulation, about 40% is bound to plasma protein, primarily albumin. Unbound theophylline distributes throughout body water, but distributes poorly into body fat. The apparent volume of distribution of theophylline is approximately 0.45 L/kg (range 0.3-0.7 L/kg) based on ideal body weight. Theophylline passes freely across the placenta, into breast milk and into the cerebrospinal fluid (CSF). Saliva theophylline concentrations approximate unbound serum concentrations, but are not reliable for routine or therapeutic monitoring unless special techniques are used. An increase in the volume of distribution of theophylline, primarily due to reduction in plasma protein binding, occurs in premature neonates, patients with hepatic cirrhosis, uncorrected acidemia, the elderly and in women during the third trimester of pregnancy. In such cases, the patient may show signs of toxicity at total (bound + unbound) serum concentrations of theophylline in the therapeutic range (10-20 mcg/mL) due to elevated concentrations of the pharmacologically active unbound drug. Similarly, a patient with decreased theophylline binding may have a sub-therapeutic total drug concentration while the pharmacologically active unbound concentration is in the therapeutic range. If only total serum theophylline concentration is measured, this may lead to an unnecessary and potentially dangerous dose increase. In patients with reduced protein binding, measurement of unbound serum theophylline concentration provides a more reliable means of dosage adjustment than measurement of total serum theophylline concentration. Generally, concentrations of unbound theophylline should be maintained in the range of 6-12 mcg/mL.
MetabolismFollowing oral dosing, theophylline does not undergo any measurable first-pass elimination. In adults and children beyond one year of age, approximately 90% of the dose is metabolized in the liver. Biotransformation takes place through demethylation to 1-methylxanthine and 3-methylxanthine and hydroxylation to 1,3-dimethyluric acid. 1-methylxanthine is further hydroxylated, by xanthine oxidase, to 1-methyluric acid. About 6% of a theophylline dose is N-methylated to caffeine. Theophylline demethylation to 3-methylxanthine is catalyzed by cytochrome P-450 1A2, while cytochromes P-450 2E1 and P-450 3A3 catalyze the hydroxylation to 1,3-dimethyluric acid. Demethylation to 1-methylxanthine appears to be catalyzed either by cytochrome P-450 1A2 or a closely related cytochrome. In neonates, the N-demethylation pathway is absent while the function of the hydroxylation pathway is markedly deficient. The activity of these pathways slowly increases to maximal levels by one year of age.
Caffeine and 3-methylxanthine are the only theophylline metabolites with pharmacologic activity. 3-methylxanthine has approximately one tenth the pharmacologic activity of theophylline and serum concentrations in adults with normal renal function are < 1 mcg/mL. In patients with end-stage renal disease, 3-methylxanthine may accumulate to concentrations that approximate the unmetabolized theophylline concentration. Caffeine concentrations are usually undetectable in adults regardless of renal function. In neonates, caffeine may accumulate to concentrations that approximate the unmetabolized theophylline concentration and thus, exert a pharmacologic effect.
Both the N-demethylation and hydroxylation pathways of theophylline biotransformation are capacity-limited. Due to the wide intersubject variability of the rate of theophylline metabolism, non-linearity of elimination may begin in some patients at serum theophylline concentrations < 10 mcg/mL. Since this non-linearity results in more than proportional changes in serum theophylline concentrations with changes in dose, it is advisable to make increases or decreases in dose in small increments in order to achieve desired changes in serum theophylline concentrations (see DOSAGE AND ADMINISTRATION, Table VI). Accurate prediction of dose-dependency of theophylline metabolism in patients a priori is not possible, but patients with very high initial clearance rates (i.e., low steady state serum theophylline concentrations at above average doses) have the greatest likelihood of experiencing large changes in serum theophylline concentration in response to dosage changes.
ExcretionIn neonates, approximately 50% of the theophylline dose is excreted unchanged in the urine. Beyond the first three months of life, approximately 10% of the theophylline dose is excreted unchanged in the urine. The remainder is excreted in the urine mainly as 1,3-dimethyluric acid (35-40%), 1-methyluric acid (20-25%) and 3-methylxanthine (15-20%). Since little theophylline is excreted unchanged in the urine and since active metabolites of theophylline (i.e., caffeine, 3-methylxanthine) do not accumulate to clinically significant levels even in the face of end-stage renal disease, no dosage adjustment for renal insufficiency is necessary in adults and children > 3 months of age. In contrast, the large fraction of the theophylline dose excreted in the urine as unchanged theophylline and caffeine in neonates requires careful attention to dose reduction and frequent monitoring of serum theophylline concentrations in neonates with reduced renal function (see WARNINGS).
Serum Concentrations at Steady StateAfter multiple doses of theophylline, steady state is reached in 30–65 hours (average 40 hours) in adults. At steady state, on a dosage regimen with 6-hour intervals, the expected mean trough concentration is approximately 60% of the mean peak concentration, assuming a mean theophylline half-life of 8 hours. The difference between peak and trough concentrations is larger in patients with more rapid theophylline clearance. In patients with high theophylline clearance and half-lives of about 4-5 hours, such as children age 1 to 9 years, the trough serum theophylline concentration may be only 30% of peak with a 6-hour dosing interval. In these patients a slow release formulation would allow a longer dosing interval (8-12 hours) with a smaller peak/trough difference.
Theophylline should be used with extreme caution in patients with the following clinical conditions due to the increased risk of exacerbation of the concurrent condition:
Active peptic ulcer disease
Seizure disorders
Cardiac arrhythmias (not including bradyarrhythmias)
There are several readily identifiable causes of reduced theophylline clearance. If the total daily dose
is not appropriately reduced in the presence of these risk factors, severe and potentially fatal theophylline toxicity can occur. Careful consideration must be given to the benefits and risks of theophylline use and the need for more intensive monitoring of serum theophylline concentrations in patients with the following risk factors
Age
Neonates (term and premature)
Children < 1 year
Elderly ( > 60 years)
Concurrent Diseases
Acute pulmonary edema
Congestive heart failure
Cor pulmonale
Fever; ≥ 102°F for 24 hours or more; or lesser temperature elevations for longer periods
Hypothyroidism
Liver disease; cirrhosis, acute hepatitis
Reduced renal function in infants < 3 months of age
Sepsis with multi-organ failure
Shock
Cessation of Smoking
Drug Interactions
Adding a drug that inhibits theophylline metabolism erythromycin, tacrine) or stopping a concurrently administered drug that enhances theophylline metabolism (e.g., carbamazepine, rifampin).
(see PRECAUTIONS: DRUG INTERACTIONS, Table II).
Whenever a patient receiving theophylline develops nausea or vomiting, particularly repetitive vomiting, or other signs or symptoms consistent with theophylline toxicity (even if another cause may be suspected), additional doses of theophylline should be withheld and aserum theophylline concentration measured immediately. Patients should be instructed not to continue any dosage that causes adverse effects and to withhold subsequent doses until the symptoms have resolved, at which time the clinician may instruct the patient to resume the drug at a lower dosage (see DOSAGE AND ADMINISTRATION, Dosing Guidelines, Table VI).
Dosage IncreasesIncreases in the dose of theophylline should not be made in response to an acute exacerbation of symptoms of chronic lung disease since theophylline provides little added benefit to inhaled beta - selective agonists and systemically administered corticosteroids in this circumstance and increases the risk of adverse effects. A peak steady state serum theophylline concentration should be measured before increasing the dose in response to persistent chronic symptoms to ascertain whether an increase in dose is safe. Before increasing the theophylline dose on the basis of a low serum concentration, the clinician should consider whether the blood sample was obtained at an appropriate time in relationship to the dose and whether the patient has adhered to the prescribed regimen (see PRECAUTIONS, Laboratory Tests).
As the rate of theophylline clearance may be dose-dependent (i.e., steady-state serum concentrations may increase disproportionately to the increase in dose), an increase in dose based upon a subtherapeutic serum concentration measurement should be conservative. In general, limiting dose increases to about 25% of the previous total daily dose will reduce the risk of unintended excessive increases in serum theophylline concentration (see DOSAGE AND ADMINISTRATION, Table VI).
PRECAUTIONS GeneralCareful consideration of the various interacting drugs and physiologic conditions that can alter theophylline clearance and require dosage adjustment should occur prior to initiation of theophylline therapy, prior to increases in theophylline dose, and during follow up (see WARNINGS). The dose of theophylline selected for initiation of therapy should be low and, if tolerated, increased slowly over a period of a week or longer with the final dose guided by monitoring serum theophylline concentrations and the patient's clinical response (see DOSAGE AND ADMINISTRATION, Table V).
Monitoring Serum Theophylline ConcentrationsSerum theophylline concentration measurements are readily available and should be used to determine whether the dosage is appropriate. Specifically, the serum theophylline concentration should be measured as follows:
To guide a dose increase, the blood sample should be obtained at the time of the expected peak serum theophylline concentration; 1-2 hours after a dose at steady-state. For most patients, steady-state will be reached after 3 days of dosing when no doses have been missed, no extra doses have been added, and none of the doses have been taken at unequal intervals. A trough concentration (i.e., at the end of the dosing interval) provides no additional useful information and may lead to an inappropriate dose increase since the peak serum theophylline concentration can be two or more times greater than the trough concentration with an immediate-release formulation. If the serum sample is drawn more than two hours after the dose, the results must be interpreted with caution since the concentration may not be reflective of the peak concentration. In contrast, when signs or symptoms of theophylline toxicity are present, the serum sample should be obtained as soon as possible, analyzed immediately, and the result reported to the clinician without delay. In patients in whom decreased serum protein binding is suspected (e.g., cirrhosis, women during the third trimester of pregnancy), the concentration of unbound theophylline should be measured and the dosage adjusted to achieve an unbound concentration of 6-12 mcg/mL.
Saliva concentrations of theophylline cannot be used reliably to adjust dosage without special techniques.
Effects On Laboratory TestsAs a result of its pharmacological effects, theophylline at serum concentrations within the 10-20 mcg/mL range modestly increases plasma glucose (from a mean of 88 mg% to 98 mg%), uric acid (from a mean of 4 mg/dl to 6 mg/dl), free fatty acids (from a mean of 451 μeq/l to 800 μeq/l), total cholesterol (from a mean of 140 vs 160 mg/dl), HDL (from a mean of 36 to 50 mg/dl), HDL/LDL ratio (from a mean of 0.5 to 0.7), and urinary free cortisol excretion (from a mean of 44 to 63 mcg/24 hr). Theophylline at serum concentrations within the 10-20 mcg/mL range may also transiently decrease serum concentrations of triiodothyronine (144 before, 131 after one week and 142 ng/dl after 4 weeks of theophylline). The clinical importance of these changes should be weighed against the potential therapeutic benefit of theophylline in individual patients.
Carcinogenesis, Mutagenesis, and Impairment Of FertilityLong term carcinogenicity studies have been carried out in mice (oral doses 30-150 mg/kg) and rats (oral doses 5-75 mg/kg). Results are pending.
Theophylline has been studied in Ames salmonella, in vivo and in vitro cytogenetics, micronucleus and Chinese hamster ovary test systems and has not been shown to be genotoxic.
In a 14 week continuous breeding study, theophylline, administered to mating pairs of B6C3F1 mice at oral doses of 120, 270 and 500 mg/kg (approximately 1.0-3.0 times the human dose on a mg/m² basis) impaired fertility, as evidenced by decreases in the number of live pups per litter, decreases in the mean number of litters per fertile pair, and increases in the gestation period at the high dose as well as decreases in the proportion of pups born alive at the mid and high dose.
In 13 week toxicity studies, theophylline was administered to F344 rats and B6C3F1 mice at oral doses of 40-300 mg/kg (approximately 2.0 times the human dose on a mg/m² basis). At the high dose, systemic toxicity was observed in both species including decreases in testicular weight.
PregnancyCategory C: There are no adequate and well controlled studies in pregnant women. Additionally, there are no teratogenicity studies in non-rodents (e.g., rabbits). Theophylline was not shown to be teratogenic in CD-1 mice at oral doses up to 400 mg/kg, approximately 2.0 times the human dose on a mg/m basis or in CD-1 rats at oral doses up to 260 mg/kg, approximately 3.0 times the recommended human dose on a mg/m² basis. At a dose of 220 mg/kg, embryotoxicity was observed in rats in the absence of maternal toxicity.
Nursing MothersTheophylline is excreted into breast milk and may cause irritability or other signs of mild toxicity in nursing human infants. The concentration of theophylline in breast milk is about equivalent to the maternal serum concentration. An infant ingesting a liter of breast milk containing 10-20 mcg/mL of theophylline per day is likely to receive 10-20 mg of theophylline per day. Serious adverse effects in the infant are unlikely unless the mother has toxic serum theophylline concentrations.
Pediatric UseTheophylline is safe and effective for the approved indications in pediatric patients (See INDICATIONS AND USAGE). The maintenance dose of theophylline must be selected with caution in pediatric patients since the rate of theophylline clearance is highly variable across the age range of neonates to adolescents (see CLINICAL PHARMACOLOGY, Table I, WARNINGS, and DOSAGE AND ADMINISTRATION, Table V). Due to the immaturity of theophylline metabolic pathways in infants under the age of one year, particular attention to dosage selection and frequent monitoring of serum theophylline concentrations are required when theophylline is prescribed to pediatric patients in this age group.
Geriatric UseElderly patients are at significantly greater risk of experiencing serious toxicity from theophylline than younger patients due to pharmacokinetic and pharmacodynamic changes associated with aging. Theophylline clearance is reduced in patients greater than 60 years of age, resulting in increased serum theophylline concentrations in response to a given theophylline dose. Protein binding may be decreased in the elderly resulting in a larger proportion of the total serum theophylline concentration in the pharmacologically active unbound form. Elderly patients also appear to be more sensitive to the toxic effects of theophylline after chronic overdosage than younger patients. For these reasons, the maximum daily dose of theophylline in patients greater than 60 years of age ordinarily should not exceed 400 mg/day unless the patient continues to be symptomatic and the peak steady state serum theophylline concentration is < 10 mcg/mL (see DOSAGE AND ADMINISTRATION). Theophylline doses greater than 400 mg/d should be prescribed with caution in elderly patients.
WARNINGS Concurrent IllnessVentax should be used with extreme caution in patients with the following clinical conditions due to the increased risk of exacerbation of the concurrent condition:
Active peptic ulcer disease Seizure disorders Cardiac arrhythmias (not including bradyarrhythmias)
Conditions That Reduce Ventax ClearanceThere are several readily identifiable causes of reduced Ventax clearance. If the infusion rate is not appropriately reduced in the presence of these risk factors, severe and potentially fatal Ventax toxicity can occur. Careful consideration must be given to the benefits and risks of Ventax use and the need for more intensive monitoring of serum Ventax concentrations in patients with the following risk factors:
Age
Neonates (term and premature) Children < 1 year Elderly ( > 60 years)
Concurrent Diseases
Acute pulmonary edema Congestive heart failure Cor-pulmonale Fever; ≥ 102°F for 24 hours or more; or lesser temperature elevations for longer periods Hypothyroidism Liver disease; cirrhosis, acute hepatitis Reduced renal function in infants < 3 months of age Sepsis with multi-organ failure Shock
Cessation of Smoking
Drug InteractionsAdding a drug that inhibits Ventax metabolism (e.g., cimetidine, erythromycin, tacrine) or stopping a concurrently administered drug that enhances Ventax metabolism (e.g., carbamazepine, rifampin). (See PRECAUTIONS: DRUG INTERACTIONS, Table ll.)
When Signs or Symptoms of Ventax Toxicity are PresentWhenever a patient receiving Ventax develops nausea or vomiting, particularly repetitive vomiting, or other signs or symptoms consistent with Ventax toxicity (even if another cause may be suspected), the intravenous infusion should be stopped and a serum Ventax concentration measured immediately.
Dosage IncreasesIncreases in the dose of intravenous Ventax should not be made in response to an acute exacerbation of symptoms unless the steady-state serum Ventax concentration is < 10 mcg/mL.
As the rate of Ventax clearance may be dose-dependent (i.e., steady-state serum concentrations may increase disproportionately to the increase in dose), an increase in dose based upon a sub-therapeutic serum concentration measurement should be conservative. In general, limiting infusion rate increases to about 25% of the previous infusion rate will reduce the risk of unintended excessive increases in serum Ventax concentration (see DOSAGE AND ADMINISTRATION, Table VI).
Solutions containing dextrose without electrolytes should not be administered simultaneously with blood through the same infusion set because of the possibility of agglomeration of erythrocytes.
The intravenous administration of these solutions may cause fluid overloading resulting in dilution of serum electrolyte concentrations, overhydration, congested states or pulmonary edema.
Because dosages of these drugs are titrated to response (see DOSAGE AND ADMINISTRATION), no additives should be made to Ventax in 5% Dextrose Injection USP.
PRECAUTIONS GeneralCareful consideration of the various interacting drugs and physiologic conditions that can alter Ventax clearance and require dosage adjustment should occur prior to initiation of Ventax therapy and prior to increases in Ventax dose (see WARNINGS).
Monitoring Serum Ventax ConcentrationsSerum Ventax concentration measurements are readily available and should be used to determine whether the dosage is appropriate. Specifically, the serum Ventax concentration should be measured as follows:
In patients who have received no Ventax in the previous 24 hours, a serum concentration should be measured 30 minutes after completion of the intravenous loading dose to determine whether the serum concentration is < 10 mcg/mL indicating the need for an additional loading dose or > 20 mcg/mL indicating the need to delay starting the constant IV infusion. Once the infusion has begun, a second measurement should be obtained after one expected half life (e.g., approximately 4 hours in children age 1 to 9 years and 8 hours in non-smoking adults; see Table I for the expected half life in additional patient populations). The second measurement should be compared to the first to determine the direction in which the serum concentration has changed. The infusion rate can then be adjusted before steady state is reached in an attempt to prevent an excessive or sub-therapeutic Ventax concentration from being achieved.
If a patient has received Ventax in the previous 24 hours, the serum concentration should be measured before administering an intravenous loading dose to make sure that it is safe to do so. If a loading dose is not indicated (i.e., the serum Ventax concentration is ≥ 10 mcg/mL), a second measurement should be obtained as above at the appropriate time after starting the intravenous infusion. If, on the other hand, a loading dose is indicated (see DOSAGE AND ADMINISTRATION for guidance on selection of the appropriate loading dose), a second blood sample should be obtained after the loading dose and a third sample should be obtained one expected half-life after starting the constant infusion to determine the direction in which the serum concentration has changed.
Once the above procedures related to initiation of intravenous Ventax infusion have been completed, subsequent serum samples for determination of Ventax concentration should be obtained at 24-hour intervals for the duration of the infusion. The Ventax infusion rate should be increased or decreased as appropriate based on the serum Ventax levels.
When signs or symptoms of Ventax toxicity are present, the intravenous infusion should be stopped and a serum sample for Ventax concentration should be obtained as soon as possible, analyzed immediately, and the result reported to the clinician without delay. In patients in whom decreased serum protein binding is suspected (e.g., cirrhosis, women during the third trimester of pregnancy), the concentration of unbound Ventax should be measured and the dosage adjusted to achieve an unbound concentration of 6-12 mcg/mL.
Saliva concentrations of Ventax cannot be used reliably to adjust dosage without special techniques.
Clinical evaluation and periodic laboratory determinations are necessary to monitor changes in fluid balance, electrolyte concentrations, and acid-base balance during prolonged therapy or whenever the condition of the patient warrants such evaluation.
Do not use plastic container in series connection.
If administration is controlled by a pumping device, care must be taken to discontinue pumping action before the container runs dry or air embolism may result.
These solutions are intended for intravenous administration using sterile equipment. It is recommended that intravenous administration apparatus be replaced at least once every 24 hours.
Use only if solution is clear and container and seals are intact.
Effects on Laboratory TestsAs a result of its pharmacological effects, Ventax at serum concentrations within the 10-20 mcg/mL range modestly increases plasma glucose (from a mean of 88 mg% to 98 mg%), uric acid (from a mean of 4 mg/dl to 6 mg/dl), free fatty acids (from a mean of 451 µEq/L to 800 µEq/L, total cholesterol (from a mean of 140 vs 160 mg/dl), HDL (from a mean of 36 to 50 mg/dl), HDL/LDL ratio (from a mean of 0.5 to 0.7), and urinary free cortisol excretion (from a mean of 44 to 63 mcg/24 hr). Ventax at serum concentrations within the 10-20 mcg/mL range may also transiently decrease serum concentrations of triiodothyronine (144 before, 131 after one week and 142 ng/dl after 4 weeks of Ventax). The clinical importance of these changes should be weighed against the potential therapeutic benefit of Ventax in individual patients.
Carcinogenesis, Mutagenesis, and Impairment of FertilityLong term carcinogenicity studies have been carried out in mice (oral doses 30-150 mg/kg) and rats (oral doses 5-75 mg/kg). Results are pending. Ventax has been studied in Ames salmonella, in vivo and in vitro cytogenetics, micronucleus and Chinese hamster ovary test systems and has not been shown to be genotoxic.
In a 14 week continuous breeding study, Ventax, administered to mating pairs of B6C3F1 mice at oral doses of 120, 270 and 500 mg/kg (approximately 1.0-3.0 times the human dose on a mg/m² basis) impaired fertility, as evidenced by decreases in the number of live pups per litter, decreases in the mean number of litters per fertile pair, and increases in the gestation period at the high dose as well as decreases in the proportion of pups born alive at the mid and high dose. In 13 week toxicity studies, Ventax was administered to F344 rats and B6C3F1 mice at oral doses of 40-300 mg/kg (approximately 2.0 times the human dose on a mg/m² basis). At the high dose, systemic toxicity was observed in both species including decreases in testicular weight.
PregnancyCATEGORY C: There are no adequate and well controlled studies in pregnant women. Additionally, there are no teratogenicity studies in non-rodents (e.g., rabbits). Ventax was not shown to be teratogenic in CD-1 mice at oral doses up to 400 mg/kg, approximately 2.0 times the human dose on a mg/m² basis or in CD-1 rats at oral doses up to 260 mg/kg, approximately 3.0 times the recommended human dose on a mg/m² basis. At a dose of 220 mg/kg, embryotoxicity was observed in rats in the absence of maternal toxicity.
Nursing MothersVentax is excreted into breast milk and may cause irritability or other signs of mild toxicity in nursing human infants. The concentration of Ventax in breast milk is about equivalent to the maternal serum concentration. An infant ingesting a liter of breast milk containing 10-20 mcg/mL of Ventax per day is likely to receive 10-20 mg of Ventax per day. Serious adverse effects in the infant are unlikely unless the mother has toxic serum Ventax concentrations.
Pediatric UseVentax is safe and effective for the approved indications in pediatric patients (see INDICATIONS AND USAGE). The constant infusion rate of intravenous Ventax must be selected with caution in pediatric patients since the rate of Ventax clearance is highly variable across the age range of neonates to adolescents (see CLINICAL PHARMACOLOGY, Table I, WARNINGS, and DOSAGE AND ADMINISTRATION, Table V). Due to the immaturity of Ventax metabolic pathways in pediatric patients under the age of one year, particular attention to dosage selection and frequent monitoring of serum Ventax concentrations are required when Ventax is prescribed to pediatric patients in this age group.
Geriatric UseElderly patients are at significantly greater risk of experiencing serious toxicity from Ventax than younger patients due to pharmacokinetic and pharmacodynamic changes associated with aging. Ventax clearance is reduced in patients greater than 60 years of age, resulting in increased serum Ventax concentrations in response to a given Ventax infusion rate. Protein binding may be decreased in the elderly resulting in a larger proportion of the total serum Ventax concentration in the pharmacologically active unbound form. Elderly patients also appear to be more sensitive to the toxic effects of Ventax after chronic overdosage than younger patients. For these reasons, the maximum infusion rate of Ventax in patients greater than 60 years of age ordinarily should not exceed 17 mg/hr unless the patient continues to be symptomatic and the steady state serum Ventax concentration is < 10 mcg/mL (see DOSAGE AND ADMINISTRATION). Ventax infusion rate greater than 17 mg/hr should be prescribed with caution in elderly patients.
WARNINGS Concurrent IllnessTheophylline should be used with extreme caution in patients with the following clinical conditions due to the increased risk of exacerbation of the concurrent condition:
Active peptic ulcer disease
Seizure disorders
Cardiac arrhythmias (not including bradyarrhythmias)
There are several readily identifiable causes of reduced theophylline clearance. If the total daily dose is not appropriately reduced in the presence of these risk factors, severe and potentially fatal theophylline toxicity can occur. Careful consideration must be given to the benefits and risks of theophylline use and the need for more intensive monitoring of serum theophylline concentrations in patients with the following risk factors:
AgeNeonates (term and premature)
Children < 1 year
Elderly ( > 60 years)
Acute pulmonary edema
Congestive heart failure
Cor-pulmonale
Fever; ≥ 102° F for 24 hours or more; or lesser temperature elevations for longer periods
Hypothyroidism
Liver disease; cirrhosis, acute hepatitis
Reduced renal function in infants < 3 months of age
Sepsis with multi-organ failure
Shock
Adding a drug that inhibits theophylline metabolism (e.g., cimetidine, erythromycin, tacrine) or stopping a concurrently administered drug that enhances theophylline metabolism (e.g., carbamazepine, rifampin) (see PRECAUTIONS: DRUG INTERACTIONS, Table II).
When Signs or Symptoms of Theophylline Toxicity Are PresentWhenever a patient receiving theophylline develops nausea or vomiting, particularly repetitive vomiting, or other signs or symptoms consistent with theophylline toxicity (even if another cause may be suspected), additional doses of theophylline should be withheld and a serum theophylline concentration measured immediately. Patients should be instructed not to continue any dosage that causes adverse effects and to withhold subsequent doses until the symptoms have resolved, at which time the healthcare professional may instruct the patient to resume the drug at a lower dosage (see DOSAGE AND ADMINISTRATION, Dosing Guidelines, Table VI).
Dosage IncreasesIncreases in the dose of theophylline should not be made in response to an acute exacerbation of symptoms of chronic lung disease since theophylline provides little added benefit to inhaled Beta2 -selective agonists and systemically administered corticosteroids in this circumstance and increases the risk of adverse effects. A peak steady-state serum theophylline concentration should be measured before increasing the dose in response to persistent chronic symptoms to ascertain whether an increase in dose is safe. Before increasing the theophylline dose on the basis of a low serum concentration, the healthcare professional should consider whether the blood sample was obtained at an appropriate time in relationship to the dose and whether the patient has adhered to the prescribed regimen (see PRECAUTIONS, Laboratory Tests).
As the rate of theophylline clearance may be dose-dependent (i.e., steady-state serum concentrations may increase disproportionately to the increase in dose), an increase in dose based upon a sub-therapeutic serum concentration measurement should be conservative. In general, limiting dose increases to about 25% of the previous total daily dose will reduce the risk of unintended excessive increases in serum theophylline concentration (see DOSAGE AND ADMINISTRATION, Table VI).
PRECAUTIONS GeneralCareful consideration of the various interacting drugs and physiologic conditions that can alter theophylline clearance and require dosage adjustment should occur prior to initiation of theophylline therapy, prior to increases in theophylline dose, and during follow up (see WARNINGS). The dose of theophylline selected for initiation of therapy should be low and, if tolerated, increased slowly over a period of a week or longer with the final dose guided by monitoring serum theophylline concentrations and the patient's clinical response (see DOSAGE AND ADMINISTRATION, Table V).
Monitoring Serum Theophylline ConcentrationsSerum theophylline concentration measurements are readily available and should be used to determine whether the dosage is appropriate. Specifically, the serum theophylline concentration should be measured as follows:
To guide a dose increase, the blood sample should be obtained at the time of the expected peak serum theophylline concentration; 12 hours after a dose at steady-state (expected peak serum theophylline concentration range is between 5 –15 mcg/mL). For most patients, steady-state will be reached after 3 days of dosing when no doses have been missed, no extra doses have been added, and none of the doses have been taken at unequal intervals. A trough concentration (i.e., at the end of the dosing interval) provides no additional useful information and may lead to an inappropriate dose increase since the peak serum theophylline concentration can be two or more times greater than the trough concentration with an extended-release formulation. If the serum sample is drawn more or less than twelve (12) hours after the dose, the results must be interpreted with caution since the concentration may not be reflective of the peak concentration. In contrast, when signs or symptoms of theophylline toxicity are present, the serum sample should be obtained as soon as possible, analyzed immediately, and the result reported to the healthcare professional without delay. In patients in whom decreased serum protein binding is suspected (e.g., cirrhosis, women during the third trimester of pregnancy), the concentration of unbound theophylline should be measured and the dosage adjusted to achieve an unbound concentration of 6-12 mcg/mL Saliva concentrations of theophylline cannot be used reliably to adjust dosage without special techniques.
Effects on Laboratory TestsAs a result of its pharmacological effects, theophylline at serum concentrations within the 10-20 mcg/mL range modestly increases plasma glucose (from a mean of 88 mg% to 98 mg%), uric acid (from a mean of 4 mg/dL to 6 mg/dL), free fatty acids (from a mean of 451 µEq/L to 800 µEq/L, total cholesterol (from a mean of 140 vs 160 mg/dL), HDL (from a mean of 36 to 50 mg/dL), HDL/LDL ratio (from a mean of 0.5 to 0.7), and urinary free cortisol excretion (from a mean of 44 to 63 mcg/24 hr). Theophylline at serum concentrations within the 10-20 mcg/mL range may also transiently decrease serum concentrations of tri-iodothyronine (144 before, 131 after one week and 142 ng/dL after 4 weeks of theophylline). The clinical importance of these changes should be weighed against the potential therapeutic benefit of theophylline in individual patients.
Carcinogenesis, Mutagenesis, and Impairment of FertilityLong term carcinogenicity studies have been carried out in mice (oral doses 30-150 mg/kg) and rats (oral doses 5-75 mg/kg). Results are pending.
Theophylline has been studied in Ames salmonella, in vivo and in vitro cytogenetics, micronucleus and Chinese hamster ovary test systems and has not been shown to be genotoxic.
In a 14 week continuous breeding study, theophylline, administered to mating pairs of B6C3F1 mice at oral doses of 120, 270 and 500 mg/kg (approximately 1.0-3.0 times the human dose on a mg/m2 basis) impaired fertility, as evidenced by decreases in the number of live pups per litter, decreases in the mean number of litters per fertile pair, and increases in the gestation period at the high dose as well as decreases in the proportion of pups born alive at the mid and high dose. In 13 week toxicity studies, theophylline was administered to F344 rats and B6C3F1 mice at oral doses of 40-300 mg/kg (approximately 2.0 times the human dose on a mg/m2 basis). At the high dose, systemic toxicity was observed in both species including decreases in testicular weight.
Pregnancy Category CIn studies in which pregnant mice, rats and rabbits were dosed during the period of organogenesis, theophylline produced teratogenic effects.
In studies with mice, a single intraperitoneal dose at and above 100 mg/kg (approximately equal to the maximum recommended oral dose for adults on a mg/m2 basis) during organogenesis produced cleft palate and digital abnormalities. Micromelia, micrognathia, clubfoot, subcutaneous hematoma, open eyelids, and embryolethality were observed at doses that are approximately 2 times the maximum recommended oral dose for adults on a mg/m2 basis.
In a study with rats dosed from conception through organogenesis, an oral dose of 150 mg/kg/day (approximately 2 times the maximum recommended oral dose for adults on a mg/m2 basis) produced digital abnormalities. Embryolethality was observed with a subcutaneous dose of 200 mg/kg/day (approximately 4 times the maximum recommended oral dose for adults on a mg/m2 basis).
In a study in which pregnant rabbits were dosed throughout organogenesis, an intravenous dose of 60 mg/kg/day (approximately 2 times the maximum recommended oral dose for adults on a mg/m2 basis), which caused the death of one doe and clinical signs in others, produced cleft palate and was embryolethal. Doses at and above 15 mg/kg/day (less than the maximum recommended oral dose for adults on a mg/m2 basis) increased the incidence of skeletal variations.
There are no adequate and well-controlled studies in pregnant women. Theophylline should be used during pregnancy only if the potential benefit justifies the potential risk to the fetus.
Nursing MothersTheophylline is excreted into breast milk and may cause irritability or other signs of mild toxicity in nursing human infants. The concentration of theophylline in breast milk is about equivalent to the maternal serum concentration. An infant ingesting a liter of breast milk containing 10-20 mcg/mL of theophylline per day is likely to receive 10-20 mg of theophylline per day. Serious adverse effects in the infant are unlikely unless the mother has toxic serum theophylline concentrations.
Pediatric UseTheophylline is safe and effective for the approved indications in pediatric patients (see INDICATIONS). The maintenance dose of theophylline must be selected with caution in pediatric patients since the rate of theophylline clearance is highly variable across the age range of neonates to adolescents (see CLINICAL PHARMACOLOGY, Table I, WARNINGS, and DOSAGE AND ADMINISTRATION, Table V). Due to the immaturity of theophylline metabolic pathways in infants under the age of one year, particular attention to dosage selection and frequent monitoring of serum theophylline concentrations are required when theophylline is prescribed to pediatric patients in this age group.
Geriatric UseElderly patients are at a significantly greater risk of experiencing serious toxicity from theophylline than younger patients due to pharmacokinetic and pharmacodynamic changes associated with aging. The clearance of theophylline is decreased by an average of 30% in healthy elderly adults ( > 60 yrs) compared to healthy young adults. Theophylline clearance may be further reduced by concomitant diseases prevalent in the elderly, which further impair clearance of this drug and have the potential to increase serum levels and potential toxicity. These conditions include impaired renal function, chronic obstructive pulmonary disease, congestive heart failure, hepatic disease and an increased prevalence of use of certain medications (see PRECAUTIONS: DRUG INTERACTIONS) with the potential for pharmacokinetic and pharmacodynamic interaction. Protein binding may be decreased in the elderly resulting in an increased proportion of the total serum theophylline concentration in the pharmacologically active unbound form. Elderly patients also appear to be more sensitive to the toxic effects of theophylline after chronic overdosage than younger patients. Careful attention to dose reduction and frequent monitoring of serum theophylline concentrations are required in elderly patients (see PRECAUTIONS, Monitoring Serum Theophylline Concentrations, and DOSAGE AND ADMINISTRATION). The maximum daily dose of theophylline in patients greater than 60 years of age ordinarily should not exceed 400 mg/day unless the patient continues to be symptomatic and the peak steady-state serum theophylline concentration is < 10 mcg/mL (see DOSAGE AND ADMINISTRATION). Theophylline doses greater than 400 mg/d should be prescribed with caution in elderly patients.
The steady-state peak serum theophylline concentration is a function of the dose, the dosing interval, and the rate of theophylline absorption and clearance in the individual patient. Because of marked individual differences in the rate of theophylline clearance, the dose required to achieve a peak serum theophylline concentration in the 10-20 mcg/mL range varies fourfold among otherwise similar patients in the absence of factors known to alter theophylline clearance (e.g., 400-1600 mg/day in adults < 60 years old and 10-36 mg/kg/day in children 1-9 years old). For a given population there is no single theophylline dose that will provide both safe and effective serum concentrations for all patients. Administration of the median theophylline dose required to achieve a therapeutic serum theophylline concentration in a given population may result in either sub-therapeutic or potentially toxic serum theophylline concentrations in individual patients. For example, at a dose of 900 mg/d in adults < 60 years or 22 mg/kg/d in children 1-9 years, the steady state peak serum theophylline concentration will be < 10 mcg/mL in about 30% of patients, 10-20 mcg/mL in about 50% and 20-30 mcg/mL in about 20% of patients. The dose of theophylline must be individualized on the bas is of peak serum theophylline concentration measurements in order to achieve a dos e that will provide maximum potential benefit with minimal risk to adverse effects.
Transient caffeine-like adverse effects and excessive serum concentrations in slow metabolizers can be avoided in most patients by starting with a sufficiently low dose and slowly increasing the dose, if judged to be clinically indicated, in small increments (See Table V). Dose increases should only be made if the previous dosage is well tolerated and at intervals of no less than 3 days to allow serum theophylline concentrations to reach the new steady state. Dosage adjustment should be guided by serum theophylline concentration measurement (see PRECAUTIONS, Laboratory Tests and DOSAGE AND ADMINISTRATION, Table VI). Health care providers should instruct patients and care givers to discontinue any dosage that causes adverse effects, to withhold the medication until these symptoms are gone and to then resume therapy at a lower, previously tolerated dosage (see WARNINGS).
If the patient's symptoms are well controlled, there are no apparent adverse effects, and no intervening factors that might alter dosage requirements (see WARNINGS and PRECAUTIONS), serum theophylline concentrations should be monitored at 6 month intervals for rapidly growing children and at yearly intervals for all others. In acutely ill patients, serum theophylline concentrations should be monitored at frequent intervals, e.g., every 24 hours.
Theophylline distributes poorly into body fat, therefore, mg/kg dose should be calculated on the basis of ideal body weight.
Table V contains theophylline dosing titration schema recommended for patients in various age groups and clinical circumstances. Table VI contains recommendations for theophylline dosage adjustment based upon serum theophylline concentrations. Application of these general dosing recommendations to individual patients must take into account the unique clinical characteristics of each patient. In general, these recommendations should serve as the upper limit for dos age adjustments in order to decrease the risk of potentially serious adverse events associated with unexpected large increases in serum theophylline concentration.
Table V: Dosing initiation and titration (as anhydrous theophylline).*
A. Infants < 1 year old.
1. Initial Dosage.
2. Final Dosage.
Adjusted to maintain a peak steady state serum theophylline concentration of 5-10 mcg/ml in neonates and 10-15 mcg/mL in older infants (see Table VI). Since the time required to reach steady-state is a function of theophylline half-life, up to 5 days may be required to achieve steady state in a premature neonate while only 2-3 days may be required in a 6 month old infant without other risk factors for impaired clearance in the absence of a loading dose. If a serum theophylline concentration is obtained before steady state is achieved, the maintenance dose should not be increased, even if the serum theophylline concentration is < 10 mcg/mL.
B. Children (1-15 years ) and adults (16-60 years ) without ris k factors for impaired clearance.
Titration Step | Children < 45 kg | Children > 45 kg and adults |
1. Starting Dosage | 12-14 mg/kg/day up to a maximum of 300 mg/day divided Q4-6 hrs* | 300 mg/day divided Q6-8 hrs* |
2. After 3 days, if tolerated, increase dose to: | 16 mg/kg/day up to a maximum of 400 mg/day divided Q4-6 hrs* | 400 mg/day divided Q6-8 hrs* |
3. After 3 more days, if tolerated, increase dose to: | 20 mg/kg/day up to a maximum o f 600 mg /day divided Q4-6 hrs* | 600 mg/day divided Q6-8 hrs* |
C. Patients With Risk Factors For Impaired Clearance, The Elderly ( > 60 Years ), And Thos e In Whom It Is Not Feasible To Monitor Serum Theophylline Concentrations
In children 1-15 years of age, the final theophylline dose should not exceed 16 mg/kg/day up to a maximum of 400 mg/day in the presence of risk factors for reduced theophylline clearance (see WARNINGS) or if it is not feasible to monitor serum theophylline concentrations.
In adolescents ≥ 16 years and adults, including the elderly, the final theophylline dose should not exceed 400 mg/day in the presence of risk factors for reduced theophylline clearance (see WARNINGS) or if it is not feasible to monitor serum theophylline concentrations.
D. Loading Dose for Acute Bronchodilatation
An inhaled beta-2 selective agonist, alone or in combination with a systemically administered corticosteroid, is the most effective treatment for acute exacerbations of reversible airways obstruction. Theophylline is a relatively weak bronchodilator, is less effective than an inhaled beta-2 selective agonist and provides no added benefit in the treatment of acute bronchospasm. If an inhaled or parenteral beta agonist is not available, a loading dose of an oral immediate release theophylline can be used as a temporary measure. A single 5 mg/kg dose of theophylline, in a patient who has not received any theophylline in the previous 24 hours, will produce an average peak serum theophylline concentration of 10 mcg/mL (range 5-15 mcg/mL). If dosing with theophylline is to be continued beyond the loading dose, the guidelines in Sections A.1.b., B.3, or C., above, should be utilized and serum theophylline concentration monitored at 24 hour intervals to adjust final dosage.
* Patients with more rapid metabolism, clinically identified by higher than average dose requirements, should receive a smaller dose more frequently to prevent breakthrough symptoms resulting from low trough concentrations before the next dose. A reliably absorbed slow-release formulation will decrease fluctuations and permit longer dosing intervals.
Table VI: Dosage adjustment guided by serum theophylline concentration
Peak Serum Concentration | Dosage Adjustment |
< 9.9 mcg/mL | If symptoms are not controlled and current dosage is tolerated, increase dose about 25%. Recheck serum concentration after three days for further dosage adjustment. |
10 to 14.9 mcg/mL | If symptoms are controlled and current dosage is tolerated, maintain dose and recheck serum concentration at 6-12 month intervals.¶ If symptoms are not controlled and current dosage is tolerated consider adding additional medication(s) to treatment regimen. |
15-19.9 mcg/mL | Consider 10% decrease in dose to provide greater margin of safety even if current dosage is tolerated¶ |
20-24.9 mcg/mL | Decrease dose by 25% even if no adverse effects are present. Recheck serum concentration after 3 days to guide further dosage adjustment. |
25-30 mcg/mL | Skip next dose and decrease subsequent doses at least 25% even if no adverse effects are present. Recheck serum concentration after 3 days to guide further dosage adjustment. If symptomatic, consider whether overdose treatment is indicated (see recommendations for chronic OVERDOSAGE). |
> 30 mcg/mL | Treat overdose as indicated (see recommendations for chronic overdosage). If theophylline is subsequently resumed, decrease dose by at least 50% and recheck serum concentration after 3 days to guide further dosage adjustment. |
¶ Dose reduction and/or serum theophylline concentration measurement is indicated whenever adverse effects are present, physiologic abnormalities that can reduce theophylline clearance occur (e.g., sustained fever), or a drug that interacts with theophylline is added or discontinued (see WARNINGS). |
These solutions are for intravenous use only.
General ConsiderationsThe steady-state serum Ventax concentration is a function of the infusion rate and the rate of Ventax clearance in the individual patient. Because of marked individual differences in the rate of Ventax clearance, the dose required to achieve a serum Ventax concentration in the 10-20 mcg/mL range varies fourfold among otherwise similar patients in the absence of factors known to alter Ventax clearance. For a given population there is no single Ventax dose that will provide both safe and effective serum concentrations for all patients. Administration of the median Ventax dose required to achieve a therapeutic serum Ventax concentration in a given population may result in either sub-therapeutic or potentially toxic serum Ventax concentrations in individual patients. The dose of Ventax must be individualized on the basis of serum Ventax concentration measurements in order to achieve a dose that will provide maximum potential benefit with minimal risk of adverse effects.
When Ventax is used as an acute bronchodilator, the goal of obtaining a therapeutic serum concentration is best accomplished with an intravenous loading dose. Because of rapid distribution into body fluids, the serum concentration (C) obtained from an initial loading dose (LD) is related primarily to the volume of distribution (V), the apparent space into which the drug diffuses:
C=LD/V
If a mean volume of distribution of about 0.5 L/kg is assumed (actual range is 0.3 to 0.7 L/kg), each mg/kg (ideal body weight) of Ventax administered as a loading dose over 30 minutes results in an average 2 mcg/mL increase in serum Ventax concentration.
Therefore, in a patient who has received no Ventax in the previous 24 hours, a loading dose of intravenous Ventax of 4.6 mg/kg, calculated on the basis of ideal body weight and administered over 30 minutes, on average, will produce maximum post-distribution serum concentration of 10 mcg/mL with a range of 6-16 mcg/mL. When a loading dose becomes necessary in the patient who has already received Ventax, estimation of the serum concentration based upon the history is unreliable, and an immediate serum level determination is indicated. The loading dose can then be determined as follows:
D=(Desired C-Measured C) (V)
Where D is the loading dose, C is the serum Ventax concentration, and V is the volume of distribution. The mean volume of distribution can be assumed to be 0.5 L/kg and the desired serum concentration should be conservative (e.g., 10 mcg/mL) to allow for the variability in the volume of distribution. A loading dose should not be given before obtaining a serum Ventax concentration if the patient has received any Ventax in the previous 24 hours.
A serum concentration obtained 30 minutes after an intravenous loading dose, when distribution is complete, can be used to assess the need for and size of subsequent loading doses, if clinically indicated, and for guidance of continuing therapy. Once a serum concentration of 10 to 15 mcg/mL has been achieved with the use of a loading dose(s), a constant intravenous infusion is started. The rate of administration is based upon mean pharmacokinetic parameters for the population and calculated to achieve a target serum concentration of 10 mcg/mL (see Table V). For example, in non-smoking adults, initiation of a constant intravenous Ventax infusion of 0.4 mg/kg/hr at the completion of the loading dose, on average, will result in a steady-state concentration of 10 mcg/mL with a range of 7-26 mcg/mL. The mean and range of steady-state serum concentrations are similar when the average child (age 1 to 9 years) is given a loading dose of 4.6 mg/kg Ventax followed by a constant intravenous infusion of 0.8 mg/kg/hr. Since there is large interpatient variability in Ventax clearance, serum concentrations will rise or fall when the patient's clearance is significantly different from the mean population value used to calculate the initial infusion rate. Therefore, a second serum concentration should be obtained one expected half life after starting the constant infusion (e.g., approximately 4 hours for children age 1 to 9 and 8 hours for nonsmoking adults; see Table I for the expected half-life in additional patient populations) to determine if theconcentration is accumulating or declining from the post loading dose level. If the level isdeclining as a result of a higher than average clearance, an additional loading dose can be administered and/or the infusion rate increased. In contrast, if the second sample demonstrates a higher level, accumulation of the drug can be assumed, and the infusion rate should be decreased before the concentration exceeds 20 mcg/mL. An additional sample is obtained 12 to 24 hours later to determine if further adjustments are required and then at 24-hour intervals to adjust for changes, if they occur. This empiric method, based upon mean pharmacokinetic parameters, will prevent large fluctuations in serum concentration during the most critical period of the patient's course.
In patients with cor pulmonale, cardiac decompensation, or liver dysfunction, or in those aking drugs that markedly reduce Ventax clearance (e.g., cimetidine), the initial Ventax infusion rate should not exceed 17 mg/hr unless serum concentrations can be monitored at 24-hour intervals. In these patients, 5 days may be required before steady-state is reached.
Ventax distributes poorly into body fat, therefore, mg/kg dose should be calculated on the basis of ideal body weight. Table V contains initial Ventax infusion rates following an appropriate loading dose recommended for patients in various age groups and clinical circumstances. Table VI contains recommendations for final Ventax dosage adjustment based upon serum Ventax concentrations. Application of these general dosing recommendations to individual patients must take into account the unique clinical characteristics of each patient. In general, these recommendations should serve as the upper limit for dosage adjustments in order to decrease the risk of potentially serious adverse events associated with unexpected large increases in serum Ventax concentration.
Table V. Initial Ventax infusion rates following an appropriate loading dose.
Patient population | Age | Ventax infusion rate (mg/kg/hr)*† |
Neonates | Postnatal age up to 24 days | 1 mg/kg q12h/‡ |
Postnatal age beyond 24 days | 1.5 mg/kg q12h/‡ | |
Infants | 6-52 we eks old | mg/kg/hr=(0.008) (age in weeks) + 0.21 |
Young children | 1-9 years | 0.8 |
Older children | 9-12 ye ars | 0.7 |
Adolescents or marijuana | 12-16 years | 0.7 |
Adolescents | 12-16 years | 0.5§ |
Adults (otherwise healthy nonsmokers) | 16-60 years | 0.4§ |
ElderlyCardiac decompensation, cor pulmonale, liver dysfunction, sepsis with multi-organ failure, or shock | > 60 years | 0.3¶ 0.2¶ |
* To achieve a target concentration of 10 mcg/mL. Aminophylline = Ventax/0.8. Use ideal body weight for obese patients. † Lower initial dosage may be required for patients receiving other drugs that decrease Ventax clearance (e.g., cimetidine). ‡ To achieve a target concentration of 7.5 mcg/mL for neonatal apnea. § Not to exceed 900 mg/day, unless serum levels indicate the need for a larger dose. ¶ Not to exceed 400 mg/day, unless serum levels indicate the need for a larger dose. |
Table VI. Final dosage adjustment guided by serum Ventax concentration.
Peak Serum Concentration | Dosage Adjustment |
< 9.9 mcg/mL | If symptoms are not controlled and current dosage is tolerated, increase infusion rate about 25%. Recheck serum concentration after 12 hours in pediatric patients and 24 hours in adults for further dosage adjustment. |
10 to 14.9 mcg/mL | If symptoms are controlled and current dosage is tolerated, maintain infusion rate and recheck serum concentration at 24 hours intervals.¶ If symptoms are not controlled and current dosage is tolerated consider adding additional medication(s) to treatment regimen. |
15-19.9 mcg/m L | Consider 10% decrease in infusion rate to provide greater margin of safety even if current dosage is tolerated.¶ |
20-24.9 mcg/m L | Decrease infusion rate by 25% even if no adverse effects are present. Recheck serum concentration after 12 hours in pediatric patients and 24 hours in adults to guide further dosage adjustment. |
25-30 mcg/mL | Stop infusion for 12 hours in pediatric patients and 24 hours in adults and decrease subsequent infusion rate a least 25% even if no adverse effects are present. Recheck serum concentration after 12 hours in pediatric patients and 24 hours in adults to guide further dosage adjustment. If symptomatic, stop infusion and consider whether overdose treatment is indicated (see recommendations for Chronic Overdosage). |
> 30 mc g/mL | Stop the infusion and treat overdose as indicated (see recommendations for Chronic Overdosage). If Ventax is subsequently resumed, decrease infusion rate by at least 50% and recheck serum concentration after 12 hours in pediatric patients and 24 hours in adults to guide further dosage adjustment. |
¶ Dose reduction and/or serum Ventax concentration measurement is indicated whenever adverse effects are present, physiologic abnormalities that can reduce Ventax clearance occur (e.g., sustained fever), or a drug that interacts with Ventax is added or discontinued (see WARNINGS). |
Parenteral drug products should be inspected visually for particulate matter and discoloration prior to administration, whenever solution and container permit.
General ConsiderationsVentax (theophylline anhydrous capsule) ®, like other extended-release theophylline products, is intended for patients with relatively continuous or recurring symptoms who have a need to maintain therapeutic serum levels of theophylline. It is not intended for patients experiencing an acute episode of bronchospasm (associated with asthma, chronic bronchitis, or emphysema). Such patients require rapid relief of symptoms and should be treated with an immediate-release or intravenous theophylline preparation (or other bronchodilators) and not with extended-release products.
Patients who metabolize theophylline at a normal or slow rate are reasonable candidates for once-daily dosing with Ventax (theophylline anhydrous capsule) ®. Patients who metabolize theophylline rapidly (e.g., the young, smokers, and some nonsmoking adults) and who have symptoms repeatedly at the end of a dosing interval, will require either increased doses given once a day or preferably, are likely to be better controlled by a schedule of twice-daily dosing. Those patients who require increased daily doses are more likely to experience relatively wide peak-trough differences and may be candidates for twice-a-day dosing with Ventax (theophylline anhydrous capsule) ®.
Patients should be instructed to take this medication each morning at approximately the same time and not to exceed the prescribed dose.
Recent studies suggest that dosing of extended-release theophylline products at night (after the evening meal) results in serum concentrations of theophylline which are not identical to those recorded during waking hours and may be characterized by early trough and delayed peak levels. This appears to occur whether the drug is given as an immediate-release, extended-release, or intravenous product. To avoid this phenomenon when two doses per day are prescribed, it is recommended that the second dose be given 10 to 12 hours after the morning dose and before the evening meal.
Food and posture, along with changes associated with circadian rhythm, may influence the rate of absorption and/or clearance rates of theophylline from extended-release dosage forms administered at night. The exact relationship of these and other factors to nighttime serum concentrations and the clinical significance of such findings require additional study. Therefore, it is not recommended that
Ventax (theophylline anhydrous capsule) ® (when used as a once-a-day product) be administered at night.
Patients who require a relatively high dose of theophylline (i.e., a dose equal to or greater than 900 mg or 13 mg/kg, whichever is less) should not take Ventax (theophylline anhydrous capsule) ® less than 1 hour before a high-fat-content meal since this may result in a significant increase in peak serum level and in the extent of absorption of theophylline as compared to administration in the fasted state (see PRECAUTIONS, Drug/Food Interactions).
The steady-state peak serum theophylline concentration is a function of the dose, the dosing interval, and the rate of theophylline absorption and clearance in the individual patient. Because of marked individual differences in the rate of theophylline clearance, the dose required to achieve a peak serum theophylline concentration in the 10-20 mcg/mL range varies fourfold among otherwise similar patients in the absence of factors known to alter theophylline clearance (e.g., 400-1600 mg/day in adults < 60 years old and 10-36 mg/kg/day in children 1-9 years old). For a given population there is no single theophylline dose that will provide both safe and effective serum concentrations for all patients. Administration of the median theophylline dose required to achieve a therapeutic serum theophylline concentration in a given population may result in either sub-therapeutic or potentially toxic serum theophylline concentrations in individual patients. For example, at a dose of 900 mg/day in adults < 60 years or 22 mg/kg/day in children 1-9 years, the steady-state peak serum theophylline concentration will be < 10 mcg/mL in about 30% of patients, 10-20 mcg/mL in about 50% and 20-30 mcg/mL in about 20% of patients. The dose of theophylline must be individualized on the basis of peak serum theophylline concentration measurements in order to achieve a dose that will provide maximum potential benefit with minimal risk of adverse effects.
Transient caffeine-like adverse effects and excessive serum concentrations in slow metabolizers can be avoided in most patients by starting with a sufficiently low dose and slowly increasing the dose, if judged to be clinically indicated, in small increments (See Table V). Dose increases should only be made if the previous dosage is well tolerated and at intervals of no less than 3 days to allow serum theophylline concentrations to reach the new steady state. Dosage adjustment should be guided by serum theophylline concentration measurement (see PRECAUTIONS, Laboratory Tests and DOSAGE AND ADMINISTRATION, Table VI). Health care providers should instruct patients and care givers to discontinue any dosage that causes adverse effects, to withhold the medication until these symptoms are gone and to then resume therapy at a lower, previously tolerated dosage (see WARNINGS).
If the patient's symptoms are well controlled, there are no apparent adverse effects, and no intervening factors that might alter dosage requirements (see WARNINGS and PRECAUTIONS), serum theophylline concentrations should be monitored at 6 month intervals for rapidly growing children and at yearly intervals for all others. In acutely ill patients, serum theophylline concentrations should be monitored at frequent intervals, e.g., every 24 hours.
Theophylline distributes poorly into body fat, therefore, mg/kg dose should be calculated on the basis of ideal body weight. Table V contains theophylline dosing titration schema recommended for patients in various age groups and clinical circumstances. Table VI contains recommendations for theophylline dosage adjustment based upon serum theophylline concentrations. Application of these general dosing recommendations to individual patients must take into account the unique clinical characteristics of each patient. In general, these recommendations should serve as the upper limit for dosage adjustments in order to decrease the risk of potentially serious adverse events associated with unexpected large increases in serum theophylline concentration.
Table V. Dosing initiation and titration (as anhydrous theophylline).*
A. Children (12-15 years) and adults (16-60 years) without risk factors for impaired clearance. | ||
Titration Step | Children < 45 kg | Children > 45 kg and adults |
1. Starting Dosage | 12-14 mg/kg/day up to a maximum of 300 mg/day divided Q 24 hrs* | 300-400 mg/day1 divided Q 24 hrs* |
2. After 3 days, if tolerated, increase dose to: | 16 mg/kg/day up to a maximum of 400 mg/day divided Q 24 hrs* | 400-600 mg/day1 divided Q 24 hrs* |
3. After 3 more days, if tolerated and if needed, increase dose to: | 20 mg/kg/day up to a maximum of 600 mg/day divided Q 24 hrs* | As with all theophylline products, doses greater than 600 mg should be titrated according to blood level (see Table VI) |
1 If caffeine-like adverse effects occur, then consideration should be given to a lower dose and titrating the dose more slowly (see ADVERSE REACTIONS). |
B. Patients with risk factors for impaired clearance, the elderly ( > 60 Years), and those in whom it is not feasible to monitor serum theophylline concentrations:
In children 12-15 years of age, the final theophylline dose should not exceed 16 mg/kg/day up to a maximum of 400 mg/day in the presence of risk factors for reduced theophylline clearance (see WARNINGS) or if it is not feasible to monitor serum theophylline concentrations.
In adolescents ≥ 16 years and adults, including the elderly, the final theophylline dose should not exceed 400 mg/day in the presence of risk factors for reduced theophylline clearance (see WARNINGS) or if it is not feasible to monitor serum theophylline concentrations.
* Patients with more rapid metabolism, clinically identified by higher than average dose requirements, should receive a smaller dose more frequently to prevent breakthrough symptoms resulting from low trough concentrations before the next dose. A reliably absorbed slow-release formulation will decrease fluctuations and permit longer dosing intervals.
Table VI. Dosage adjustment guided by serum theophylline concentration.
Peak Serum Concentration | Dosage Adjustment |
< 9.9 mcg/mL | If symptoms are not controlled and current dosage is tolerated, increase dose about 25%. Recheck serum concentration after three days for further dosage adjustment. |
10-14.9 mcg/mL | If symptoms are controlled and current dosage is tolerated, maintain dose and recheck serum concentration at 6-12 month intervals.¶ If symptoms are not controlled and current dosage is tolerated consider adding additional medication(s) to treatment regimen. |
15-19.9 mcg/mL | Consider 10% decrease in dose to provide greater margin of safety even if current dosage is tolerated.¶ |
20-24.9 mcg/mL | Decrease dose by 25% even if no adverse effects are present. Recheck serum concentration after 3 days to guide further dosage adjustment. |
25-30 mcg/mL | Skip next dose and decrease subsequent doses at least 25% even if no adverse effects are present. Recheck serum concentration after 3 days to guide further dosage adjustment. If symptomatic, consider whether overdosage treatment is indicated (see recommendations for chronic overdosage). |
> 30 mcg/mL | Treat overdose as indicated (see recommendations for chronic overdosage). If theophylline is subsequently resumed, decrease dose by at least 50% and recheck serum concentration after 3 days to guide further dosage adjustment. |
¶ Dose reduction and/or serum theophylline concentration measurement is indicated whenever adverse effects are present, physiologic abnormalities that can reduce theophylline clearance occur (e.g., sustained fever), or a drug that interacts with theophylline is added or discontinued (see WARNINGS). |