Phenytoin Sodium Flynn 300 Mg Hard Capsules
SUMMARY OF PRODUCT CHARACTERISTICS
1 NAME OF THE MEDICINAL PRODUCT
Phenytoin Sodium Flynn 300 mg Hard Capsules
2 QUALITATIVE AND QUANTITATIVE COMPOSITION
Each capsules contains 300 mg phenytoin sodium Each capsule also contains 61.88 mg lactose monohydrate For full list of excipients, see Section 6.1
3 PHARMACEUTICAL FORM
Capsules, hard
A white powder in a No 1 hard gelatin capsule with a white opaque body and green cap, radially printed ‘EPANUTIN 300’.
4 CLINICAL PARTICULARS
4.1 Therapeutic indications
Control of tonic-clonic seizures (grand mal epilepsy), partial seizures (focal including temporal lobe) or a combination of these, and for the prevention and treatment of seizures occurring during or following neurosurgery and/or severe head injury. Phenytoin Sodium Flynn Hard Capsules has also been employed in the treatment of trigeminal neuralgia but it should only be used as second line therapy if carbamazepine is ineffective or patients are intolerant to carbamazepine.
4.2 Posology and method of administration
For oral administration only.
Dosage:
Dosage should be individualised as there may be wide interpatient variability in phenytoin serum levels with equivalent dosage. Phenytoin Sodium Flynn Hard Capsules should be introduced in small dosages with gradual increments until control is achieved or until toxic effects appear. In some cases serum level determinations may be necessary for optimal dosage adjustments - the clinically effective level is usually 10-20mg/l (40-80 micromoles/l) although some cases of tonic-clonic seizures may be controlled with lower serum levels of phenytoin. With recommended dosage a period of seven to ten days may be required to achieve steady state serum levels with Phenytoin Sodium Flynn Hard Capsules and changes in dosage should not be carried out at intervals shorter than seven to ten days. Maintenance of treatment should be the lowest dose of anticonvulsant consistent with control of seizures.
Phenytoin Sodium Flynn Hard Capsules:
Phenytoin Sodium Flynn Hard Capsules contain phenytoin sodium. Although 100mg of phenytoin sodium is equivalent to 92mg of phenytoin on a molecular weight basis, these molecular equivalents are not necessarily biologically equivalent. Physicians should therefore exercise care in those situations where it is necessary to change the dosage form and serum level monitoring is advised.
Adults:
Initially 3 to 4mg/kg/day with subsequent dosage adjustment if necessary. For most adults a satisfactory maintenance dose will be 200 to 500 mg daily in single or divided doses. Exceptionally, a daily dose outside this range may be indicated. Dosage should normally be adjusted according to serum levels where assay facilities exist.
Elderly:
Elderly (over 65 years): As with adults the dosage of Phenytoin Sodium Flynn Hard Capsules should be titrated to the patient's individual requirements using the same guidelines. As elderly patients tend to receive multiple drug therapies, the possibility of drug interactions should be borne in mind.
Infants and Children:
Initially, 5mg/kg/day in two divided doses, with subsequent dosage individualised to a maximum of 300mg daily. A recommended daily maintenance dosage is usually 4 mg/kg to 8 mg/kg.
Neonates:
The absorption of phenytoin following oral administration in neonates is unpredictable. Furthermore, the metabolism of phenytoin may be depressed. It is therefore especially important to monitor serum levels in the neonate.
4.3 Contraindications
Phenytoin is contraindicated in patients who are hypersensitive to phenytoin, or its excipients, or other hydantoins.
4.4 Special warnings and precautions for use
General
Phenytoin is not effective for absence (petit mal) seizures. If tonic-clonic (grand mal) and absence seizures are present together, combined drug therapy is needed.
Phenytoin may affect glucose metabolism and inhibit insulin release. Hyperglycaemia has been reported in association with toxic levels. Phenytoin is not indicated for seizures due to hypoglycaemia or other metabolic causes.
Abrupt withdrawal of phenytoin in epileptic patients may precipitate status epilepticus.
When, in the judgement of the clinician, the need for dosage reduction, discontinuation, or substitution of alternative anti-epileptic medication arises, this should be done gradually. However, in the event of an allergic or hypersensitivity reaction, rapid substitution of alternative therapy may be necessary. In this case, alternative therapy should be an antiepileptic drug not belonging to the hydantoin chemical class.
Phenytoin may precipitate or aggravate absence seizures and myoclonic seizures.
Herbal preparations containing St John’s wort (Hypericumperforatum) should not be used while taking phenytoin due to the risk of decreased plasma concentrations and reduced clinical effects of phenytoin (see Section 4.5).
Suicide
Suicidal ideation and behaviour have been reported in patients treated with anti-epileptic agents in several indications. A meta-analysis of randomised placebo controlled trials of antiepileptic drugs has also shown a small increased risk of suicidal ideation and behaviour. The mechanism of this risk is not known and the available data do not exclude the possibility of an increased risk for Phenytoin Sodium.
Therefore patients should be monitored for signs of suicidal ideation and behaviours and appropriate treatment should be considered. Patients (and caregivers of patients) should be advised to seek medical advice should signs of suicidal ideation or behaviour emerge.
Hypersensitivity Syndrome / Drug Reaction with Eosinophilia and Systemic Symptoms
Hypersensitivity syndrome (HSS) or drug reaction with eosinophilia and systemic symptoms (DRESS) has been reported in patients taking anticonvulsant drugs, including phenytoin.
Some of these events have been fatal or life threatening.
HSS/DRESS typically, although not exclusively, presents with fever, rash, and/or lymphadenopathy, in association with other organ system involvement, such as hepatitis, nephritis, hematological abnormalities, myocarditis, myositis or pneumonitis. Initial symptoms may resemble an acute viral infection. Other common manifestations include arthralgias, jaundice, hepatomegaly, leukocytosis, and eosinophilia. The interval between the first drug exposure and symptoms is usually 2 to 4 weeks but has been reported in individuals receiving anticonvulsants for 3 or more months. If such signs and symptoms occur, the patient should be evaluated immediately. Phenytoin should be discontinued if an alternative etiology for the signs and symptoms cannot be established.
Patients at higher risk for developing HSS/DRESS include black patients, patients who have experienced this syndrome in the past (with phenytoin or other anticonvulsant drugs), patients who have a family history of this syndrome, and immunosuppressed patients. The syndrome is more severe in previously sensitized individuals.
Serious Dermatologic Reactions
Phenytoin can cause rare, serious skin adverse events such as exfoliative dermatitis, Stevens -Johnson syndrome (SJS), and toxic epidermal necrolysis (TEN), which can be fatal. Although serious skin reactions may occur without warning, patients should be alert for the occurrence of rash and other symptoms of HSS/DRESS (see Section 4.4 Special warnings and precautions for use - Hypersensitivity Syndrome/Drug Reaction with Eosinophilia and Systemic Symptoms), and should seek medical advice from their physician immediately when observing any indicative signs or symptoms. The physician should advise the patient to discontinue treatment if the rash appears. If the rash is of a milder type (measles-like or scarlatiniform), therapy may be resumed after the rash has completely disappeared. If the rash recurs upon reinstitution of therapy, further phenytoin medication is contraindicated. The risk of serious skin reactions and other hypersensitivity reactions to phenytoin may be higher in black patients.
Studies in patients of Chinese ancestry have found a strong association between the risk of developing SJS/TEN and the presence of human leukocyte antigen HLA-B*1502, an inherited allelic variant of the HLA-B gene, in patients using carbamazepine. Limited evidence suggests that HLA-B* 1502 may be a risk factor for the development of SJS/TEN in patients of Asian ancestry taking drugs associated with SJS/TEN, including phenytoin. Consideration should be given to avoiding use of drugs associated with SJS/TEN, including phenytoin, in HLA-B*1502-positive patients when alternative therapies are otherwise equally available.
HLAB* 1502 may be associated with an increased risk of developing Stevens Johnson Syndrome (SJS) in individuals of Thai and Han Chinese Origin when treated with phenytoin. If these patients are known to be positive for HLAB*1502, the use of phenytoin should only be considered if the benefits are thought to exceed risks.
In the Caucasian and Japanese population, the frequency of HLAB*1502 allele is extremely low, and thus it is not possible at present to conclude on risk association. Adequate information about risk association in other ethnicities is currently not available.
Hepatic Injury
Phenytoin is highly protein bound and extensively metabolised by the liver. Reduced dosage to prevent accumulation and toxicity may therefore be required in patients with impaired liver function. Where protein binding is reduced, as in uraemia, total serum phenytoin levels will be reduced accordingly. However, the pharmacologically active free drug concentration is unlikely to be altered. Therefore, under these circumstances therapeutic control may be achieved with total phenytoin levels below the normal range of 10-20mg/l (40-80 micromoles/l). Patients with impaired liver function, elderly patients or those who are gravely ill may show early signs of toxicity.
The liver is the chief site of biotransformation of phenytoin.
Toxic hepatitis and liver damage have been reported and may, in rare cases, be fatal.
Cases of acute hepatotoxicity, including infrequent cases of acute hepatic failure, have been reported with phenytoin. These incidents usually occur within the first 2 months of treatment and may be associated with HSS/DRESS (see Section 4.4 Special warnings and precautions for use - Hypersensitivity Syndrome/Drug Reaction with Eosinophilia and Systemic Symptoms). Patients with impaired liver function, elderly patients, or those who are gravely ill may show early signs of toxicity.
The clinical course of acute phenytoin hepatotoxicity ranges from prompt recovery to fatal outcomes. In these patients with acute hepatotoxicity, phenytoin should be immediately discontinued and not re-administered.
The risk of hepatotoxicity and other hypersensitivity reactions to phenytoin may be higher in black patients.
Hematopoietic System
Hematopoietic complications, some fatal, have occasionally been reported in association with administration of phenytoin. These have included thrombocytopenia, leukopenia, granulocytopenia, agranulocytosis, and pancytopenia with or without bone marrow suppression.
There have been a number of reports suggesting a relationship between phenytoin and the development of lymphadenopathy (local or generalized) including benign lymph node hyperplasia, pseudolymphoma, lymphoma, and Hodgkin's disease. Although a cause-and-effect relationship has not been established, the occurrence of lymphadenopathy indicates the need to differentiate such a condition from other types of lymph node pathology. Lymph node involvement may occur with or without signs and symptoms resembling HSS/DRESS (see Section 4.4 Special warnings and precautions for use - Hypersensitivity Syndrome/Drug Reaction with Eosinophilia and Systemic Symptoms). In all cases of lymphadenopathy, follow-up observation for an extended period is indicated and every effort should be made to achieve seizure control using alternative anticonvulsant drugs.
While macrocytosis and megaloblastic anemia have occurred, these conditions usually respond to folic acid therapy. If folic acid is added to phenytoin therapy, a decrease in seizure control may occur.
Central Nervous System Effect
Serum levels of phenytoin sustained above the optimal range may produce confusional states referred to as "delirium", "psychosis", or "encephalopathy", or rarely irreversible cerebellar dysfunction and/or cerebellar atrophy. Accordingly, at the first sign of acute toxicity, serum drug level determinations are recommended. Dose reduction of phenytoin therapy is indicated if serum levels are excessive; if symptoms persist, termination of therapy with phenytoin is recommended.
Metabolic Effect
In view of isolated reports associating phenytoin with exacerbation of porphyria, caution should be exercised in using the medication in patients suffering from this disease.
Patients with rare hereditary problems of galactose intolerance, the Lapp lactase deficiency or glucose-galactose metabolism should not take this medicine.
Musculoskeletal Effect
Phenytoin and other anticonvulsants that have been shown to induce the CYP450 enzyme are thought to affect bone mineral metabolism indirectly by increasing the metabolism of Vitamin D3. This may lead to Vitamin D deficiency and heightened risk of osteomalacia, bone fractures, osteoporosis, hypocalcemia, and hypophosphatemia in chronically treated epileptic patients.
4.5 Interaction with other medicinal products and other forms of interaction
Drug interactions
Phenytoin is extensively bound to serum plasma proteins and is prone to competitive displacement. Phenytoin is metabolized by hepatic cytochrome (CYP) P450 enzymes CYP2C9 and CYP2C19 and is particularly susceptible to inhibitory drug interactions because it is subject to saturable metabolism. Inhibition of metabolism may produce significant increases in circulating phenytoin concentrations and enhance the risk of drug toxicity.
Phenytoin is a potent inducer of hepatic drug-metabolizing enzymes and may reduce the levels of drugs metabolized by these enzymes.
There are many drugs that may increase or decrease serum phenytoin levels or that phenytoin may affect. Serum level determinations for phenytoin are especially helpful when possible drug interactions are suspected.
The most commonly occurring drug interactions are listed below.
Drugs that may increase phenytoin serum levels:
Table 1. Drugs That May Increase Phenytoin Serum Levels
Drug Classes |
Drugs in each Class (such as) |
Alcohol (acute intake) | |
Analgesic/Anti-inflammatory agents |
Salicylates |
Anesthetics | |
Antibacterial agents |
Chloramphenicol Clarithromycin Isoniazid Sulfadiazine Sulfamethoxazole-trimethoprim Sulfonamides |
Anticonvulsants |
Oxcarbazepine Sodium valproate Succinimides Topiramate |
Antifungal agents |
Amphotericin B Fluconazole Itraconazole Ketoconazole Miconazole Voriconazole |
Antineoplastic agents |
Capecitabine Fluorouracil |
Benzodiazepines /Psychotropic agents |
Chlordiazepoxide Diazepam Disulfiram Methylphenidate Trazodone |
Calcium channel blockers / Cardiovascular agents |
Amiodarone Diltiazem Nifedipine |
H2-antagonists |
Cimetidine |
HMG-CoA reductase inhibitors |
Fluvastatin |
Hormones |
Oestrogens |
Immunosuppressant drugs |
Tacrolimus |
Oral hypoglycemic agents |
Tolbutamide |
Proton pump inhibitors |
Omeprazole |
Serotonin re-uptake inhibitors |
Fluoxetine Fluvoxamine Sertraline |
a This list is not intended to be inclusive or comprehensive. Individual drug labels should be consulted.
Drugs that may decrease phenytoin serum levels:
Table 2. Drugs That May Decrease Phenytoin Serum Levels
Drug Classes |
Drugs in each Class (such as) |
Alcohol (chronic intake) | |
Antibacterial agents |
Ciprofloxacin Rifampin |
Anticonvulsants |
Vigabatrin |
Antineoplastic agent |
Bleomycin Carboplatin Cisplatin Doxorubicin |
Antiulcer agents |
Sucralfate |
Antiretrovirals |
Fosamprenavir Ritonavir |
Bronchodilators |
Theophylline |
Cardiovascular agents |
Reserpine |
Folic acid |
Folic acid |
Hyperglycemic agents | |
St. John’s Wort |
St.John’s Wort |
a This list is not intended to be inclusive or comprehensive. Individual drug labels should be consulted.
Serum levels of phenytoin can be reduced by concomitant use of the herbal preparations containing St John’s wort (Hypericum perforatum). This is due to induction of drug metabolising enzymes by St John’s wort. Herbal preparations containing St John’s wort should therefore not be combined with phenytoin. The inducing effect may persist for at least 2 weeks after cessation of treatment with St John’s wort. If a patient is already taking St John’s wort check the anticonvulsant levels and stop St John’s wort. Anticonvulsant levels may increase on stopping St John’s wort. The dose of anticonvulsant may need adjusting.
Drugs that may either increase or decrease phenytoin serum levels:
Table 3. Drugs That May Either Increase Or Decrease Phenytoin Serum Levels
Drug Classes |
Drugs in each Class (such as) |
Antibacterial agents |
Ciprofloxacin |
Anticonvulsants |
Carbamazepine Phenobarbital Sodium valproate Valproic acid |
Antineoplastic agents | |
Psychotropic agents |
Chlordiazepoxide Diazepam Phenothiazines |
a This list is not intended to be inclusive or comprehensive. Individual drug labels should be consulted.
Acute alcohol intake may increase phenytoin serum levels while chronic alcoholism may decrease serum levels.
Drugs whose serum levels and/or effects may be altered by phenytoin.
Table 4 Drugs Whose Serum Levels and/or Effects May be Altered by Phenytoin
Drug Classes
Drugs in each Class (such as)
Antibacterial agents |
Doxycycline Rifampin |
Anticonvulsants |
Carbamazepine Lamotrigine Phenobarbital Sodium valproate Valproic acid |
Antifungal agents |
Posaconazole Voriconazole |
Antihelmintics | |
Antineoplastic agents |
Methotrexate |
Antiretrovirals |
Efavirenz Fosamprenavir Indinavir Lopinavir/ritonavir Ritonavir Saquinavir |
Bronchodilators |
Theophylline |
Calcium channel blockers / Cardiovascular agents |
Digoxin Mexiletine Nicardipine Nimodipine Verapamil |
Corticosteroids | |
Coumarin anticoagulants |
Warfarin |
Cyclosporine | |
Diuretics |
Furosemide |
HMG-CoA reductase inhibitors |
Atorvastatin Fluvastatin Simvastatin |
Hormones |
Oestrogens Oral contraceptives |
Hyperglycemic agents | |
Immunosuppressant drugs | |
Neuromuscular blocking agents |
Pancuronium Rocuronium Vecuronium |
Opioid analgesics |
Methadone |
Oral hypoglycemic agents |
Tolbutamide |
Psychotropic agents / Antidepressants |
Clozapine Paroxetine Quetiapine Sertraline |
Vitamin D |
Vitamin D |
a This list is not intended to be inclusive or comprehensive. Individual drug labels should be consulted.
The effect of phenytoin on warfarin is variable and prothrombin times should be determined when these agents are combined.
Although not a true pharmacokinetic interaction, tricyclic antidepressants and phenothiazines may precipitate seizures in susceptible patients and phenytoin dosage may need to be adjusted.
Drug/Laboratory Test Interactions:
Phenytoin may cause a slight decrease in serum levels of total and free thyroxine, possibly as a result of enhanced peripheral metabolism. These changes do not lead to clinical hypothyroidism and do not affect the levels of circulating TSH. The latter can therefore be used for diagnosing hypothyroidism in the patient on phenytoin. Phenytoin does not interfere with uptake and suppression tests used in the diagnosis of hypothyroidism. It may, however, produce lower than normal values for dexamethasone or metapyrone tests. Phenytoin may cause raised serum levels of glucose, alkaline phosphatase, and gamma glutamyl transpeptidase and lowered serum levels of calcium and folic acid. It is recommended that serum folate concentrations be measured at least once every 6 months, and folic acid supplements given if necessary. Phenytoin may affect blood sugar metabolism tests.
4.6 Fertility, pregnancy and lactation
Fertility
In animal studies, phenytoin had no direct effect on fertility.
Usage in Pregnancy Phenytoin crosses the placenta.
A number of reports suggest an association between the use of anticonvulsant drugs by women with epilepsy and a higher incidence of birth defects in children born to these women. Data are more extensive with respect to phenytoin and phenobarbital, but these are also the most commonly prescribed anticonvulsant drugs. Less systematic or anecdotal reports suggest a possible similar association with the use of all known anticonvulsant drugs.
There are intrinsic methodologic problems in obtaining adequate data on drug teratogenicity in humans. Genetic factors or the epileptic condition itself may be more important than drug therapy in leading to birth defects. The great majority of mothers on anticonvulsant medication deliver normal infants. It is important to note that anticonvulsant drugs should not be discontinued in patients in whom the drug is administered to prevent major seizures because of the strong possibility of precipitating status epilepticus with attendant hypoxia and threat to life. In individual cases where the severity and frequency of the seizure disorder are such that the removal of medication does not pose a serious threat to the patient, discontinuation of the drug may be considered prior to and during pregnancy although it cannot be said with any confidence that even minor seizures do not pose some hazard to the developing embryo or foetus.
Anticonvulsants including phenytoin may produce congenital abnormalities in the offspring of a small number of epileptic patients. The exact role of drug therapy in these abnormalities is unclear and genetic factors, in some studies, have also been shown to be important. Phenytoin Sodium Flynn Hard Capsules should only be used during pregnancy, especially early pregnancy, if in the judgement of the physician the potential benefits clearly outweigh the risk.
In addition to the reports of increased incidence of congenital malformations, such as cleft lip/palate and heart malformations in children of women receiving phenytoin and other antiepileptic drugs, there have more recently been reports of a foetal hydantoin syndrome.
This consists of prenatal growth deficiency, micro-encephaly and mental deficiency in children born to mothers who have received phenytoin, barbiturates, alcohol, or trimethadione. However, these features are all interrelated and are frequently associated with intrauterine growth retardation from other causes.
There have been isolated reports of malignancies, including neuroblastoma, in children whose mothers received phenytoin during pregnancy.
An increase in seizure frequency during pregnancy occurs in a proportion of patients, and this may be due to altered phenytoin absorption or metabolism. Periodic measurement of serum phenytoin levels is particularly valuable in the management of a pregnant epileptic patient as a guide to an appropriate adjustment of dosage. However, postpartum restoration of the original dosage will probably be indicated.
Neonatal coagulation defects have been reported within the first 24 hours in babies born to epileptic mothers receiving phenytoin. Vitamin K1 has been shown to prevent or correct this
defect and may be given to the mother before delivery and to the neonate after birth.
Phenytoin is teratogenic in rats, mice and rabbits, at levels considered to be therapeutic in man. (for full details see section 5.3 Pre-clinical safety data).
Usage in Nursing Mothers
Breast-feeding is not recommended for women taking phenytoin because phenytoin appears to be secreted in low concentrations in human milk.
4.7 Effects on ability to drive and use machines
Caution is recommended in patients performing skilled tasks (e.g. driving or operating machinery) as treatment with phenytoin may cause central nervous system adverse effects such as dizziness and drowsiness (see Section 4.8).
4.8 Undesirable effects
The following adverse reactions have been reported with phenytoin (frequency unknown -cannot be estimated from available data):
Immune system reactions: Anaphylactoid reaction, and anaphylaxis.
Central Nervous System:
Adverse reactions in this body system are common and are usually dose-related. Reactions include nystagmus, ataxia, slurred speech, decreased co-ordination, mental confusion. Cerebellar atrophy has been reported and appears more likely in settings of high PHE levels and/or long-term PHE use. (see Section 4.4 Special warnings and precautions for use -Central Nervous System Effect). Dizziness, vertigo, insomnia, transient nervousness, motor twitchings, taste perversion, headache, paresthesia and somnolence have also been observed.
There have also been rare reports of phenytoin induced dyskinesias, including chorea,
dystonia, tremor and asterixis, similar to those induced by phenothiazine and other neuroleptic drugs.
A predominantly sensory peripheral polyneuropathy has been observed in patients receiving long-term phenytoin therapy.
Gastrointestinal System:
Vomiting, nausea and constipation.
Hepatobiliary disorders:
Acute hepatic failure, toxic hepatitis and liver damage (see Section 4.4 Special warnings and precautions for use - Hepatic Injury).
Dermatologic System:
Dermatological manifestations sometimes accompanied by fever have included scarlatiniform or morbilliform rashes. A morbilliform rash (measles-like) is the most common; other types of dermatitis are seen more rarely. Other more serious forms that may be fatal have included bullous, exfoliative or purpuric dermatitis, lupus erythematosus, SJS and TEN (see Section 4.4 Special warnings and precautions for use - Serious Dermatologic Reactions).
Connective Tissue System:
Coarsening of the facial features, enlargement of the lips, gingival hyperplasia, hirsutism, hypertrichosis, Peyronie's Disease and Dupuytren's contracture may occur rarely.
Haemopoietic System:
Haemopoietic complications, some fatal, have occasionally been reported in association with administration of phenytoin. These have included thrombocytopenia, leucopenia, granulocytopenia, agranulocytosis, pancytopenia with or without bone marrow suppression.Macrocytosis and megaloblastic anaemia have occurred. Lymphadenopathy including benign lymph node hyperplasia, pseudolymphoma, lymphoma, and Hodgkin's disease have been reported. (see Section 4.4 Special warnings and precautions for use -Hematopoietic Effect)
Immune System:
HSS/DRESS (see Section 4.4 Special warnings and precautions for use - Hypersensitivity Syndrome/Drug Reaction with Eosinophilia and Systemic Symptoms), systemic lupus erythematosus, periarteritis nodosa, and immunoglobulin abnormalities.
Other.Polyarthropathy, interstitial nephritis, pneumonitis.
Musculoskeletal System:
There have been reports of decreased bone mineral density, osteopenia, osteoporosis and fractures in patients on long-term therapy with phenytoin. The mechanism by which phenytoin affects bone metabolism has not been identified. However, phenytoin has been shown to induce the CYP450 enzyme, which can affect bone mineral metabolism indirectly by increasing the metabolism of Vitamin D3. This may lead to Vitamin D deficiency and heightened risk of osteomalacia, bone fractures, osteoporosis, hypocalcemia, and hypophosphatemia in chronically treated epileptic patients. Other disorders of bone metabolism such as hypocalcemia, hypophosphatemia and decreased levels of Vitamin D metabolites have also been reported.
Paediatric population
The adverse event profile of phenytoin is generally similar between children and adults, however, gingival hyperplasia occurs more frequently in paediatric patients and in patients with poor oral hygiene.
Reporting of suspected adverse reactions
Reporting suspected adverse reactions after authorisation of the medicinal product is important. It allows continued monitoring of the benefit/risk balance of the medicinal product. Healthcare professionals are asked to report any suspected adverse reactions via the MHRA Yellow Card Scheme Website: www.mhra.gov .uk/yellowcard.
4.9 Overdose
The lethal dose in children is not known. The mean lethal dose for adults is estimated to be 2 g to 5 g. The initial symptoms are nystagmus, ataxia and dysarthria. Irreversible cerebellar dysfunction and cerebellar atrophy have been reported. The patient then becomes comatose, the pupils are unresponsive and hypotension occurs followed by respiratory depression and apnoea. Death is due to respiratory and circulatory depression.
There are marked variations among individuals with respect to phenytoin serum levels where toxicity may occur. Nystagmus on lateral gaze usually appears at 20mg/l, and ataxia at 30mg/l, dysarthria and lethargy appear when the serum concentration is greater than 40mg/l, but a concentration as high as 50mg/l has been reported without evidence of toxicity.
As much as 25 times therapeutic dose has been taken to result in serum concentration over 100mg/l (400 micromoles/l) with complete recovery.
Treatment:
Treatment is non-specific since there is no known antidote. If ingested within the previous 4 hours the stomach should be emptied. If the gag reflex is absent, the airway should be supported. Oxygen, and assisted ventilation may be necessary for central nervous system, respiratory and cardiovascular depression. Haemodialysis can be considered since phenytoin is not completely bound to plasma proteins. Total exchange transfusion has been utilised in the treatment of severe intoxication in children.
In acute overdosage the possibility of the presence of other CNS depressants, including alcohol, should be borne in mind.
5 PHARMACOLOGICAL PROPERTIES
5.1 Pharmacodynamic properties
Phenytoin is effective in various animal models of generalised convulsive disorders, reasonably effective in models of partial seizures but relatively ineffective in models of myoclonic seizures.
It appears to stabilise rather than raise the seizure threshold and prevents spread of seizure activity rather than abolish the primary focus of seizure discharge.
The mechanism by which phenytoin exerts its anticonvulsant action has not been fully elucidated however, possible contributory effects include:
1. Non-synaptic effects to reduce sodium conductance, enhance active sodium extrusion, block repetitive firing and reduce post-tetanic potentiation.
2. Post-synaptic action to enhance gaba-mediated inhibition and reduce excitatory synaptic transmission.
3. Pre-synaptic actions to reduce calcium entry and block release of neurotransmitter.
5.2 Pharmacokinetic properties
Phenytoin is absorbed from the small intestine after oral administration. Various formulation factors may affect the bioavailability of phenytoin, however, non-linear techniques have estimated absorption to be essentially complete. After absorption it is distributed into body fluid including CSF. Its volume of distribution has been estimated to be between 0.52 and 1.19 litres/kg, and it is highly protein bound (usually 90% in adults).
The plasma half-life of phenytoin in man averages 22 hours with a range of 7 to 42 hours. Steady state therapeutic drug levels are achieved at least 7 to 10 days after initiation of therapy.
Phenytoin is hydroxylated in the liver by an enzyme system which is saturable. Small incremental doses may produce very substantial increases in serum levels when these are in the upper range of therapeutic concentrations.
The parameters controlling elimination are also subject to wide interpatient variation. The serum level achieved by a given dose is therefore also subject to wide variation.
5.3 Preclinical safety data
Phenytoin causes embryofetal death and growth retardation in rats, mice, and rabbits. Phenytoin is teratogenic in rats (craniofacial defects including cleft palate, cardiovascular malformations, neural and renal defects, and limb abnormalities), mice (cleft lip, cleft palate, neural and renal defects, limb abnormalities, and digital and ocular abnormalities) and rabbits (cleft palate, limb abnormalities, and digital and ocular abnormalities). The defects produced are similar to major malformations observed in humans and abnormalities described for fetal hydantoin syndrome. The teratogenic effects of phenytoin in animals occur at therapeutic exposures, and therefore a risk to the patients cannot be ruled out.
Carcinogenesis:
Two year carcinogenicity studies in mice and rats showed an increased number of hepatocellular adenomas in mice, but not rats, at plasma concentrations relevant for humans. The clinical significance of these rodent tumours is unknown.
Genetic toxicity studies showed that phenytoin was not mutagenic in bacteria or in mammalian cells in vitro. It is clastogenic in vitro but not in vivo.
6 PHARMACEUTICAL PARTICULARS
6.1 List of excipients
Core:
Lactose monohydrate Magnesium stearate Silica
Shell:
Gelatin
Patent blue V (E131) Quinoline yellow (E104) Titanium dioxide (E171) Sodium lauryl sulfate
Printing ink:
Shellac
Black iron oxide (E172) Propylene glycol
6.2 Incompatibilities
None known
6.3 Shelf life
24 months
6.4 Special precautions for storage
Do not store above 25°C. Store in the original package in order to protect from light.
6.5
Nature and contents of container
(a) PVC/PVdC blister pack containing 28, 30 or 100 capsules Not all pack sizes may be marketed
6.6 Special precautions for disposal and other handling
No special requirements.
7 MARKETING AUTHORISATION HOLDER
Flynn Pharma Ltd Alton house 4 Herbert Street Dublin 2 Ireland
8 MARKETING AUTHORISATION NUMBER(S)
PL 13621/0064
9 DATE OF FIRST AUTHORISATION/RENEWAL OF THE AUTHORISATION
01 February 2004
10 DATE OF REVISION OF THE TEXT
04/11/2016