SERETIDE ACCUHALER and MDI
(GlaxoWellcome)
Composition
Fluticasone propionate, Salmeterol xinafoate.
Salmeterol xinafoate
4-Hydroxy-α'-[[[6-(4-phenylbutoxy)hexyl]amino]-methyl]- 1,3-benzenedimethanol,1-hydroxyl-2-naphthoate.
Fluticasone propionate
S-Fluoromethyl-6α,9α-difluoro-11β-hydroxy-16α- methyl-3-oxo-17 α-propionyloxy-androsta-1, 4-diene-17β-carbothioate.
Seretide Accuhaler also contains the excipient lactose.
Seretide Metered Dose Inhaler (MDI) also contains the excipient norflurane (HFA 134a) which is a CFC-free propellant.
Salmeterol xinafoate:
94749-08-3
Fluticasone propionate:
80474-14-2
Mode Of Action
Seretide contains fluticasone propionate and salmeterol xinafoate which improve lung function by differing modes of action. Salmeterol controls the symptoms of asthma, while fluticasone propionate reduces inflammation and prevents exacerbations of the condition. Seretide can offer a more convenient regimen for patients on concurrent long-acting beta-agonist and inhaled corticosteroid therapy. The respective mechanisms of action of both drugs are discussed below.
Salmeterol
Salmeterol is a selective long-acting beta-2 adrenoceptor agonist and at dosages of less than 100 microgram twice daily has little measurable cardiovascular effect. Salmeterol xinafoate is a racemate, the R-enantiomer being active.
The pharmacological properties of salmeterol offer a slower onset of action, but more effective protection against histamine-induced bronchoconstriction and a longer duration of bronchodilation (lasting for approximately 12 hours) than recommended doses of conventional short-acting beta-2 agonists. The onset of effective bronchodilation (> 15% improvement in FEV1) occurs within 10 to 30 minutes and peak effect occurs between 3 to 4 hours.
In vitro tests have shown salmeterol is a potent and long-lasting inhibitor of the release of mast cell mediators, such as histamine, leukotrienes and prostaglandin D2, from human lung fragments. In one study in man, salmeterol inhibits the early and late phase response to inhaled allergen; the latter persisting for over 30 hours after a single dose when the bronchodilator effect is no longer evident. Single dosing with salmeterol attenuates bronchial hyperresponsiveness. These properties indicate that salmeterol has additional non-bronchodilator activity, but the full clinical significance is not yet clear. The mechanism is different from the anti-inflammatory effect of corticosteroids, which should not be stopped or reduced when salmeterol is prescribed.
Fluticasone propionate
Fluticasone propionate given by inhalation at recommended doses has potent glucocorticoid activity in the airway. The potent anti-inflammatory action improves the symptomatic control of asthma, allows reduction of other drugs, such as rescue bronchodilators, and may limit the risk of decline in lung function over time. The low systemic bioavailability of fluticasone propionate provides a better risk: benefit outcome without the adverse effects that accompany systemically administered corticosteroids.
Pharmacokinetics
There is no evidence in animal or human subjects that the administration of fluticasone propionate and salmeterol together by the inhaled route affects the pharmacokinetics of either component. For pharmacokinetic purposes therefore each component can be considered separately.
Even though plasma levels of Seretide are very low, potential interactions with other substrates and inhibitors of CYP 3A4 cannot be excluded.
Salmeterol
Salmeterol acts locally in the lung, therefore plasma levels are not predictive of therapeutic effect. In addition there are only limited data available on the pharmacokinetics of salmeterol because of the technical difficulty of assaying very low plasma concentrations (approximately 200 pg/mL or less) of the drug after inhaled dosing.
Following administration, salmeterol xinafoate is extensively bound (95-98%) to plasma proteins. Elimination of radioactivity from plasma following oral administration of radiolabelled salmeterol xinafoate is slow (mean t½ is 67 hours). Excretion is predominantly through the faeces and to a lesser extent urine. Aliphatic hydroxylation appears to be the major route of metabolism in humans.
After regular dosing with salmeterol xinafoate, the xinafoate moiety, hydroxynaphthoic acid, can be detected in the systemic circulation, reaching steady state concentrations of approximately 100 ng/mL. These concentrations are up to 1000-fold lower than steady state levels observed in toxicity studies and in longer-term regular dosing (more than 12 months) trials in patients with airways obstruction, there have not been adverse effects attributable to hydroxynaphthoic acid reported.
Fluticasone propionate
Following oral administration 87-100% of the dose is excreted in the faeces, up to 75% as parent compound depending on the dose. There is a non-active major metabolite. Following intravenous administration there is rapid plasma clearance suggestive of extensive hepatic extraction. The plasma elimination half-life is approximately 3 hours. The volume of distribution is approximately 250 litres. Doses delivered by the dry powder inhalers and metered-dose inhalers may not have the same systemic bioavailability; however, there is no difference in clinical efficacy between the inhalers in controlled studies.
Clinical Trials
Seretide Accuhaler
Clinical trials have investigated the safety and efficacy data of fluticasone propionate/salmeterol (Seretide) at three dose strengths (100/50 mcg, 250/50 mcg and 500/50 mcg) in the treatment of patients with reversible obstructive airways disease and asthma. Six studies of 12 or 28 week duration have been carried out in a total of 2080 patients (1671 adults, 152 adolescents and 257 children), of which 769 were treated with Seretide.
Three studies used the 100/50 mcg dose strength (338 patients), two the 250/50 mcg dose strength (264 patients) and one the 500/50 mcg dose strength (167 patients). All studies were of double blind, randomised, parallel group design, and aimed to demonstrate superiority of the combination product over its constituent drugs at each dose strength, or equivalence of the combination product compared to the two drugs taken concurrently from separate inhalers (concurrent therapy).
Seretide vs. salmeterol alone or fluticasone propionate alone
In two studies using the 100/50 mcg and 250/50 mcg doses, the primary efficacy variables were probability of remaining in the study, mean change from baseline in morning pre-dose FEV1 at endpoint, and mean serial FEV1 AUC at Week 1. Patients were symptomatic and demonstrated room for improvement in lung function. Seretide was significantly more effective (p<0.001) than placebo or salmeterol alone in all primary efficacy comparisons. In addition Seretide was significantly more effective than fluticasone propionate alone in all primary efficacy comparisons (p<=0.007) except for probability of remaining in the study for the 100/50 mcg dose (p=0.084). Effects of Seretide were maintained over the treatment period. FEV1 results measured over 12 hours after 1 week of treatment or after 12 weeks of treatment were similar but higher than those seen after the first dose of Seretide. Seretide produced clinically significant improvements in quality of life (>0.5 as assessed by the Asthma Quality of Life Questionnaire) in both studies.
In a third study, Seretide 500/50 mcg was significantly more effective than fluticasone propionate alone (p<0.001). Higher mean changes in morning PEF were seen in the Seretide group for Weeks 1-12 (95% confidence intervals for the treatment difference were -29L/min to -12L/min). As well as the marked improvements in lung function seen with Seretide, reductions in rescue salbutamol use and an increase in the percentage of symptom-free days were seen. Significant differences compared with placebo and with salmeterol alone or fluticasone propionate alone were seen in most of these parameters. Improvements were noted over the first week of dosing.
Seretide vs. concurrent therapy
Four double-blind, double-dummy studies assessed clinical equivalence of Seretide with concurrent therapy with salmeterol and fluticasone propionate. Three were conducted in symptomatic adults and adolescents and one in paediatric patients.
In all studies, large increases in mean morning PEF were seen over Weeks 1-12 in both treatment groups. Improvements were already apparent over Week 1.
Results for the primary efficacy variable (mean morning PEF over Weeks 1-12 in the Intent-to-Treat Population) met the criterion for clinical equivalence (90% confidence limits for the difference between treatments contained within ± 15L/min) in three of the four studies. In one study, the data suggested Seretide had slightly greater efficacy compared to concurrent administration of salmeterol and fluticasone propionate (difference -9 L/min; 90% confidence limits -17, 0 L/min; 95% confidence limits -19, 2 L/min).
Both Seretide and concurrent therapy improved symptom scores, decreased rescue salbutamol usage and increased the percentage of symptom free days and nights. Effects of the two treatments appeared to be similar on these parameters with statistical comparisons generally showing no clinically relevant differences between treatments.
Clinic measures of FEV1 were made at each clinic visit. Improvements seen at 2 weeks were similar to those seen after 12 weeks treatment. In a 28-week study, efficacy, as measured by FEV1, was maintained throughout the duration of treatment. Results were not dependent on the type of pre-study corticosteroid used.
Seretide MDI
Two 12 week, double blind, double dummy, randomised, parallel group clinical studies were performed in 1006 adult and adolescent patients aged >= 12 years. The first study compared the 50/25 mcg strength fluticasone propionate/salmeterol metered dose inhaler (MDI; 165 patients) with the corresponding 100/50 mcg Accuhaler (167 patients), while the second study compared the 250/25 mcg strength MDI (176 patients) with the 500/50 mcg Accuhaler (161 patients). The dosing regimen for the MDI is two inhalations twice daily whilst the Accuhaler is one inhalation twice daily, ensuring the total daily dose of each active ingredient is the same for both formulations. Both studies also included a comparison with CFC fluticasone propionate MDI alone, at the same fluticasone propionate dose as the combination, to reaffirm the superiority of the combination over fluticasone propionate alone despite the change in formulation. All patients had reversible obstructive airways disease and were symptomatic on inhaled corticosteroids, with room for improvement in lung function. No clinical trial was performed with the 125/25 mcg MDI strength because pharmaceutical and clinical pharmacology data have demonstrated dose proportionality across the three strengths of the fluticasone propionate component.
The primary efficacy variable was change in mean morning PEF over weeks 1 - 12, and this met the criterion for clinical equivalence between the MDI and Accuhaler combination formulations (95% confidence limits for the difference between treatments contained within ± 15L/min) in both studies. Comparable results were also seen for other time points in both studies, with almost all 95% confidence intervals falling within ± 15L/min. In no cases were the confidence intervals greater than ± 16L/min. Large increases in mean PEF were seen over weeks 1-12 in both the MDI and the Accuhaler combination groups.
In both studies, fluticasone propionate/salmeterol MDI was significantly more effective than fluticasone propionate MDI alone in change from baseline in mean morning PEF throughout the treatment period. This was manifest as early as week 1 (p<0.001). Mean treatment differences were greater than 15L/min. These results demonstrate clinical superiority of the MDI combination over the FP CFC formulation alone, reaffirming the superiority of the combination over fluticasone propionate alone, despite the change in formulation. While a statistical comparison of fluticasone/salmeterol Accuhaler was not conducted, the differences between these 2 treatment groups were of similar magnitude to those observed for the combination MDI.
Both the Seretide MDI and Accuhaler formulations improved symptoms scores, decreased rescue salbutamol usage and increased the percentage of symptom free days and nights. Effects of the two treatments on these parameters were similar.
Indications
For the regular treatment of asthma, where the use of a combination product is appropriate. This may include:
- Patients on effective maintenance doses of long-acting beta2-agonists and inhaled corticosteroids
- Patients who are symptomatic on current inhaled corticosteroid therapy
Contra-indications
Seretide is contraindicated in patients with a history of hypersensitivity to any ingredients of the preparation.
Precautions
The management of asthma should normally follow a stepwise program and patient response should be monitored clinically and by lung function tests. Treatment of asthma should be in accordance with current National asthma treatment guidelines.
Seretide is not for relief of acute symptoms for which a fast- and short-acting inhaled bronchodilator (eg. salbutamol) is required. Patients should be advised to have their relief medication available at all times.
Increasing use of short-acting bronchodilators to relieve asthma symptoms indicates deterioration of symptom control.
Sudden and progressive deterioration in control of asthma is potentially life threatening and the patient should be reviewed by a physician. Consideration should be given to increasing corticosteroid therapy. Also, where the current dosage of Seretide has failed to give adequate control of asthma, the patient should be reviewed by a physician. Consideration should be given to additional corticosteroid therapies, and to including administration of antibiotics if an infection is present.
Treatment should not be stopped abruptly.
As with all medications containing corticosteroids, Seretide should be administered with caution in patients with active or quiescent pulmonary tuberculosis.
Seretide should be administered with caution in patients with thyrotoxicosis.
Rare instances of glaucoma and increased intraocular pressure have been reported following administration of inhaled corticosteroids.
Care should be taken when transferring patients to Seretide therapy, particularly if there is any reason to suppose that adrenal function is impaired from previous systemic steroid therapy.
Seretide should not be initiated in patients with unstable or acutely deteriorating asthma, which may be a life-threatening condition. Serious acute respiratory events, including fatalities, have been reported when salmeterol has been initiated in this situation. Although it is not possible from these reports to determine whether salmeterol contributed to these adverse events or failed to relieve the deteriorating asthma, the use of salmeterol in this setting is inappropriate.
Seretide should not be used to transfer patients from oral to inhaled steroids.
In rare cases inhaled therapy may unmask underlying eosinophilic conditions (e.g. Churg Strauss syndrome). These cases have usually been associated with reduction or withdrawal of oral corticosteroid therapy. A direct causal relationship has not been established.
Spacer Devices
Most patients will benefit from the consistent use of a spacer device with their metered dose inhaler (MDI or 'puffer'), particularly those with poor inhaler technique. Use of a spacer will also decrease the amount of drug deposited in the mouth and back of the throat, and therefore reduce the incidence of local side effects such as 'thrush' and a hoarse voice.
A change in the make of spacer may be associated with alterations in the amount of drug delivered to the lungs. The clinical significance of these alterations is uncertain. However, in these situations, the person should be monitored for any loss of asthma control.
If using a spacer, the patient should be instructed to actuate the inhaler into the spacer and then slowly breathe in as far as possible. Hold your breath for as long as comfortable, before breathing out slowly. This should be repeated for each actuation of the drug into the spacer. Any delays between actuation and inhalation should be kept to a minimum.
Static on the walls of the spacer may cause variability in drug delivery. Patients should be instructed to wash the spacer in warm water and detergent and allow it to air dry without rinsing or drying with a cloth. This should be performed before initial use of the spacer and at least monthly thereafter.
Adrenocortical function, Bone density and Growth
Inhaled steroids are designed to direct glucocorticoid delivery to the lungs in order to reduce overall systemic glucocorticoid exposure and side effects. In sufficient doses however, all inhaled steroids can have adverse effects; possible systemic effects include depression of the hypothalmic-pituitary adrenal (HPA) axis, reduction of bone density and retardation of growth rate.
The lowest dose of inhaled fluticasone that causes suppression of the HPA axis (as indicated by the 24 hour urinary cortisol concentrations), effects on bone mineral density or growth retardation in children has not yet been established. Some depression of plasma cortisol may occur in a small number of adult patients on higher doses (e.g. >1 mg/day). However, adrenal function and adrenal reserve usually remain within normal range on inhaled fluticasone propionate therapy.
Patients in a medical or surgical emergency, who in the past have required high doses of inhaled steroids and/or intermittent treatment with oral steroids, remain at risk of impaired adrenal reserve for a considerable time. The extent of the adrenal impairment may require specialist advice before elective procedures. The possibility of residual impaired adrenal response should always be borne in mind in emergency and elective situations likely to produce stress and appropriate corticosteroid treatment must be considered.
Use in Children
The growth of paediatric patients receiving corticosteroids, including fluticasone propionate, should be monitored. The potential growth effects of prolonged treatment should be weighed against the clinical benefits obtained. To minimise the systemic effects of inhaled corticosteroids, including fluticasone propionate, each patient should be titrated down to the lowest dose that effectively controls his/her asthma. (See Dosage and Administration.)
In children taking recommended doses of inhaled fluticasone propionate, adrenal function and adrenal reserve usually remain within the normal range. However, the possible effects of previous or intermittent treatment with oral steroids should not be discounted. Nevertheless, the benefits of inhaled fluticasone propionate should minimise the need for oral steroids.
Effects on ability to drive and use machinery
Seretide is unlikely to produce an effect.
Carcinogenicity
No studies on the carcinogenic potential of the combined formulation of salmeterol xinafoate:fluticasone propionate have been conducted in animals. With fluticasone alone, no evidence of a tumorigenic effect was observed in either a 2 year study in rats receiving doses of fluticasone propionate up to 57 mg/kg/day by inhalation or in an 18 month study in mice receiving oral doses of fluticasone propionate up to 1 mg/kg/day. With salmeterol xinafoate alone, oral administration to mice at 0.2, 1.4 or 10 mg/kg/day for 18 months resulted in the development of smooth muscle tumours (lieomyomas and possibly liemyosarcomas) in the uterus. In rats, combined oral / inhalational administration for 24 months at total dose levels of 0.2, 0.7 and 2.6 mg/kg/day resulted in leiomyomas in the suspensory ligament of the ovaries, as well as an increased incidence of benign pituitary tumours. The smooth muscle tumours in both species are thought to result from chronic stimulation of beta-adrenoceptors in these tissues, whereas the mechanism involved in the development of the pituitary tumours is unknown.
Mutagenicity and Impairment of Fertility
Neither salmeterol xinafoate nor fluticasone propionate showed evidence of mutagenic potential when tested alone in a standard battery of genotoxicity assays. No studies examining the potential interaction of salmeterol xinafoate and fluticasone propionate to cause genetic toxicity when co-administered have been conducted.
Neither salmeterol xinafoate nor fluticasone propionate alone show significant effects on fertility. Studies to detect such effects with co-administration have not been conducted.
The non-CFC propellant, norflurane (HFA134a), has been shown to have no toxic effect at very high vapour concentrations, far in excess of those likely to be experienced by patients, in a wide range of animal species exposed daily for periods of two years.
Preclinical Safety Data
Salmeterol xinafoate and fluticasone propionate have been extensively evaluated in animal toxicity tests. Significant toxicities occurred only at doses in excess of those recommended for human use and were those expected for a potent beta-2-adrenoreceptor agonist and glucocorticosteroid.
Co-administration of salmeterol and fluticasone propionate resulted in some cardiovascular lesions not seen upon dosing with the individual drugs (mild atrial myocarditis and focal coronary arteritis in rats and papillary muscle necrosis in dogs). However, these high dose changes were not consistently observed across studies and are unlikely to be of clinical relevance.
Co-administration did not modify other class-related toxicities in animals.
Use in Pregnancy
Category B3. Administration during pregnancy should only be considered if the expected benefit to the mother is greater than any possible risk to the foetus or child.
There is insufficient experience of the use of salmeterol xinafoate and fluticasone propionate in human pregnancy and lactation. Reproductive toxicity studies in animals, either with single drug or in combination, revealed the foetal effects expected at excessive systemic exposure levels of a potent beta-2- adrenoceptor agonist and glucocorticosteroid.
Extensive clinical experience with drugs in these classes has revealed no evidence that the effects are relevant to therapeutic doses.
Australian categorisation definition of Category B3
Drugs which have been taken by only a limited number of pregnant women and women of childbearing age, without an increase in the frequency of malformation or other direct or indirect harmful effects on the human fetus having been observed. Studies in animals have shown evidence of an increased occurrence of fetal damage, the significance of which is considered uncertain in humans.
Use in Lactation
Salmeterol and fluticasone propionate concentrations in plasma after inhaled doses are very low and therefore concentrations in human breast milk are likely to be correspondingly low. Studies in lactating animals support this for salmeterol xinafoate, although after subcutaneous administration of radiolabelled fluticasone propionate to lactating rats, levels of radioactivity in milk were 3 to 7 times plasma levels. There are no data available for human breast milk.
Interactions
Both non-selective and selective beta-blockers should be avoided in patients with reversible obstructive airways disease, unless there are compelling reasons for their use.
Due to the very low plasma concentrations achieved after inhaled dosing clinically significant drug interactions are unlikely. Care should be taken when co-administering known strong CYP3A4 inhibitors (e.g. ketoconazole, ritonavir) as there is potential for increased systemic exposure to fluticasone propionate.
Adverse Reactions
As Seretide contains fluticasone propionate and salmeterol the type and severity of adverse reactions associated with each of the compounds may be expected. There is no evidence of additional adverse events following concurrent administration of the two compounds.
Adverse events which have been associated with salmeterol or fluticasone propionate are given below.
Salmeterol
The pharmacological side-effects of beta-2 agonist treatment, such as tremor, tachycardia, subjective palpitations and headache, have been reported, but tend to be transient and may reduce with regular therapy.
Cardiac arrhythmias (including atrial fibrillation, supraventricular tachycardia and extrasystoles) have been reported. Peripheral vasodilation and a compensatory small increase in heart rate may occur in some patients.
There have been reports of arthralgia and hypersensitivity reactions, including rash, oedema and angioedema. There have been rare reports of muscle cramps.
There have been reports of oropharyngeal irritation.
Fluticasone propionate
Candidiasis (thrush) of the mouth and throat and/or hoarseness occurs in some patients. Such patients may find it helpful to rinse out their mouth with water after inhalation. Symptomatic candidiasis can be treated with topical anti-fungal therapy whilst still continuing with the fluticasone propionate.
Some depression of plasma cortisol may occur in a small number of adult patients on higher doses (>1 mg/day) (see Precautions: Adrenocortical Function).
Cutaneous hypersensitivity reactions have been reported.
As with other inhalation therapy, paradoxical bronchospasm may occur with an immediate increase in wheezing after dosing. This should be treated immediately with a fast-acting inhaled bronchodilator. Seretide should be discontinued immediately, the patient assessed, and if necessary alternative therapy instituted.
Rare cases of facial and oropharyngeal oedema have been reported.
Fluticasone propionate/salmeterol clinical trials
The following undesirable effects were commonly reported:
- hoarseness/dysphonia
- throat irritation
- headache
- candidiasis of mouth and throat and palpitations
Dosage and Administration
Seretide Accuhaler and MDI are for inhalation only.
Seretide Accuhaler and MDI must be used regularly for optimum benefit, even when asymptomatic.
Patients should be regularly assessed by a doctor, so the dose of Seretide they are receiving remains optimal. Strength of dose should only be increased or decreased on medical advice. The dose of fluticasone should be titrated to the lowest dose at which effective control of symptoms is maintained.
Patients should be given the dose of Seretide containing the appropriate fluticasone propionate dosage for the severity of their disease.
Seretide Accuhaler
The Accuhaler releases a powder that is inhaled into the lungs. The device is opened and primed by sliding the lever. The mouthpiece is then placed in the mouth and the lips closed around it. The dose can then be inhaled and the device closed. A dose counter on the Accuhaler indicates the number of doses left.
For more detailed instructions for use refer to the patient information leaflet.
Adults and children over 12 years
One inhalation (100 micrograms fluticasone propionate and 50 micrograms salmeterol) twice daily OR
One inhalation (250 micrograms fluticasone propionate and 50 micrograms salmeterol) twice daily OR
One inhalation (500 micrograms fluticasone propionate and 50 micrograms salmeterol) twice daily.
Children 4 years and over
One inhalation (100 micrograms fluticasone propionate and 50 micrograms salmeterol) twice daily.
There are no data available for use of Seretide in children aged under 4 years.
Special patient groups
There is no need to adjust the dose in elderly patients or in those with renal or hepatic impairment.
Seretide MDI
Seretide MDI has been formulated in three strengths and one pack size, delivering 120 actuations per inhaler.
Each single actuation of Seretide MDI provides 50, 125 or 250 micrograms of fluticasone propionate and salmeterol xinafoate equivalent to 25 micrograms of salmeterol.
The use of one puff bd of the MDI has not been investigated in clinical trials.
Adults and children over 12 years
Two inhalations (50 micrograms fluticasone propionate and 25 micrograms salmeterol) twice daily OR
Two inhalations (125 micrograms fluticasone propionate and 25 micrograms salmeterol) twice daily OR
Two inhalations (250 micrograms fluticasone propionate and 25 micrograms salmeterol) twice daily.
Children 4 years and over
Two inhalations of 50 micrograms fluticasone propionate and 25 micrograms salmeterol twice daily.
There are no data available for use of Seretide in children aged under 4 years.
Special patient groups
There is no need to adjust the dose in elderly patients or in those with renal or hepatic impairment.
Overdosage
There are no data available from clinical trials on overdose with Seretide, however data on overdose with both drugs are given below:
The signs and symptoms of salmeterol overdose are tremor, headache and tachycardia with possible reduction in serum potassium and raised blood glucose levels. The preferred antidotes are cardioselective beta-blocking agents, which should be used with caution in patients with a history of bronchospasm. If Seretide therapy has to be withdrawn due to overdose of the beta agonist component of the drug, provision of appropriate replacement steroid therapy should be considered.
Inhalation of fluticasone propionate doses in excess of those recommended may lead to temporary suppression of adrenal function. This does not need emergency action as adrenal function is recovered in a few days, as verified by plasma cortisol measurements. However, if higher than recommended dosage is continued over prolonged periods, some degree of adrenal suppression may result. Monitoring of adrenal reserve may be necessary. In cases of fluticasone propionate overdose Seretide therapy may still be continued at a suitable dosage for symptom control.
Pack
Seretide Accuhaler
Moulded plastic device containing a foil strip with 60 regularly placed blisters each containing 100 micrograms of fluticasone propionate and 50 micrograms of salmeterol (as xinafoate).
Moulded plastic device containing a foil strip with 60 regularly placed blisters each containing 250 micrograms of fluticasone propionate and 50 micrograms of salmeterol (as xinafoate).
Moulded plastic device containing a foil strip with 60 regularly placed blisters each containing 500 micrograms of fluticasone propionate and 50 micrograms of salmeterol (as xinafoate).
Seretide MDI
Seretide 50/25mcg MDI delivers 50 micrograms of fluticasone propionate and 25 micrograms of salmeterol (as xinafoate) per inhalation. Packs of 120 metered doses.
Seretide 125/25mcg MDI delivers 125 micrograms of fluticasone propionate and 25 micrograms of salmeterol (as xinafoate) per inhalation. Packs of 120 metered doses.
Seretide 250/25mcg MDI delivers 250 micrograms of fluticasone propionate and 25 micrograms of salmeterol (as xinafoate) per inhalation. Packs of 120 metered doses.
Seretide 100/50 Accuhaler: AUST R 70089
Seretide 250/50 Accuhaler: AUST R 70091
Seretide 500/50 Accuhaler: AUST R 70174
Seretide MDI 50/25: AUST R 77814
Seretide MDI 125/25: AUST 77830
Seretide MDI 250/25: AUST R 77831
Storage
Seretide Accuhaler should be stored in a dry place below 30°C (86°F).
Seretide MDI should be stored below 30°C. Protect from frost and direct sunlight.
As with most inhaled medications in pressurised canisters, the therapeutic effect of this Seretide MDI may decrease when the canister is cold. The canister should not be punctured, broken or burnt even when apparently empty.
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