Adrenal suppression from high-dose inhaled fluticasone propionate in children with asthma.

This cross-sectional study was designed to examine the prevalence of adrenocortical suppression in children with asthma treated with high-dose inhaled fluticasone propionate (FP). Children and adolescents (n=50) with asthma, treated with inhaled FP at a dose of > or = 1,000 mg a day for > or = 6 months, were enrolled. Early morning serum cortisol was performed. Subjects with a serum cortisol of < 400 nmol x L(-1) had a tetracosactrin stimulation test. Fifty subjects of mean age 13.1 yrs were treated with a mean dose of 924.7 microg x m(-2) x day(-1) FP for a mean duration of 2 yrs. Of the 50 subjects, 36 (72%) had serum cortisol levels of < 400 nmol x L(-1) and underwent tetracosactrin stimulation test. Of these, 6 (17%) demonstrated a less than two-fold increase in serum cortisol from baseline and peak cortisol level of < or = 550 nmol x L(-1) at 30 or 60 min poststimulation. There was a significant negative correlation between the dose of FP x m(-2) and stimulated peak cortisol level. Biochemical evidence of adrenocortical insufficiency was demonstrated in 12% of the subjects, indicating that high-dose fluticasone propionate use may be associated with dose-dependent adrenocortical suppression.     

Inhaled fluticasone propionate and adrenal effects in adult asthma: systematic review and meta-analysis.

The dose-response relationship of inhaled fluticasone propionate (FP) for adrenal suppression in adults with asthma is not clear. The current authors carried out a systematic review and meta-analysis of placebo-controlled randomised dose-response studies of >or=4 weeks' duration, which assessed the adrenal effects of FP by cosyntropin stimulation tests in adult asthma. The main outcome measure was the proportion of subjects with adrenal function below the lower limit of the normal range. Five studies, with a total of 732 subjects with asthma, met the inclusion criteria. Data on daily doses >1,000 mug were limited to one study. The proportion of subjects with adrenal function below the lower limit of the normal range on placebo was 3.9%; for a 500-microg per day increase in FP dose the odds of an abnormality increased by 1.38 (95% confidence interval 1.01-1.59). The continuous secondary outcome measures showed an inverse linear relationship with the FP dose up to 2,000 microg.day(-1). In conclusion, for routine prescribing within the established therapeutic dose-response range (50-500 microg.day(-1)), fluticasone propionate has minimal effects on adrenal function. This conclusion is limited by the paucity of long-term studies of daily doses of fluticasone propionate >1,000 mug and by the considerable individual variability in the response.     

Adrenal function as assessed by low-dose adrenocorticotropin hormone test before and after switching from inhaled beclomethasone dipropionate to inhaled fluticasone propionate.

Low-dose adrenocorticotropin hormone (ACTH) tests (0.5 microg/L 73 m2) were done before and after switching from inhaled beclomethasone dipropionate to inhaled fluticasone propionate in 12 patients 33-77 years old who had mild-to-severe asthma to compare the effects of these drugs on adrenal function. Low-dose ACTH tests were performed after the subjects had received inhaled beclomethasone dipropionate (200-900 microg/day) for at least 12 wk. Treatment was then switched to inhaled fluticasone propionate (200-600 microg/day) for at least 12 wk, and a second low-dose ACTH test was done. Pulmonary function was assessed on the basis of peak expiratory flow rate (PEFR, % of predicted value). After switching treatment, the daily dose of inhaled corticosteroid decreased by about 40%. Basal serum cortisol and ACTH levels were similar with both treatments. The adrenal response, as assessed by incremental rise in the serum cortisol level (peak minus basal) after ACTH challenge, improved significantly (5.6-7.9 microg/dL, p < 0.01) after switching to fluticasone. All three patients who had lower serum cortisol levels during beclomethasone treatment than during fluticasone treatment showed improvement in both the peak cortisol level and the incremental rise in cortisol. Mean morning and evening PEFRs significantly increased after switching from beclomethasone to fluticasone (morning: 71.2 to 76.0%, p < 0.01; evening: 67.3 to 72.1%, both p < 0.05). The diurnal variation of PEFR significantly decreased from 10.9% to 8.3% after switching treatment (p < 0.01). We conclude that switching from beclomethasone to fluticasone reduces the risk of adrenal dysfunction associated with inhaled steroids and improves pulmonary function.     

Side-effects of fluticasone in asthmatic children: no effects after dose reduction.

To assess long-term effects and side-effects of fluticasone propionate (FP), a 2-yr study was performed, comparing a step-down dose approach (1,000 microg.day(-1), with reductions every 2 months to 500, 200 and 100 microg.day(-1) for the remainder of the study) versus a constant dose (200 microg.day(-1)). In 55 children with chronic persistent asthma, aged 6-10 yrs, airways hyperresponsiveness (AHR) and systemic side-effects (height, bone parameters and adrenal cortical function) were assessed at predetermined intervals in a double-blind prospective 2-yr study. AHR improved after 4 months treatment with 1,000 microg.day(-1) FP followed by 500 microg.day(-1), without significant differences during long-term treatment between the two approaches. Dose-dependent reduction of growth velocity, adrenal cortical function and biochemical bone turnover was found during therapy with 1,000 and 500 microg.day(-1) FP when compared with 200 microg.day(-1). In conclusion, doses of 1,000 and 500 microg.day(-1) fluticasone propionate are associated with marked reductions of growth velocity, bone turnover and adrenal cortical function. However, conventional doses (< or =200 microg.day(-1) fluticasone propionate) appear to be safe in the long-term management of childhood asthma. From a safety point of view, high doses of fluticasone propionate should only be prescribed in exceptions, e.g. in persistent severe asthma.     

A randomized, double-blind study comparing the effects of beclomethasone and fluticasone on bone density over two years.

Cross-sectional studies have suggested that asthmatic patients receiving high dose inhaled corticosteroids and intermittent courses of oral corticosteroids have reduced bone mass. This prospective 2-yr study was undertaken to evaluate changes in bone density of patients receiving high doses of inhaled corticosteroids. Patients (n = 33) (males aged 18-50 yrs, females aged 18-40 yrs) on inhaled corticosteroids 1,000-2,000 microg x day(-1), were randomized in a double-blind fashion to either fluticasone propionate (FP) 1,000 microg x day(-1) or beclomethasone dipropionate (BDP) 2,000 microg x day(-1). In parallel, three open control groups of the same age range were studied: asthmatics (n = 8) receiving low dose inhaled corticosteroids (< or =400 microg x day(-1)) (group A); chronic, severe asthmatics (n = 8) receiving oral corticosteroids (> or =10 mg x day(-1) (group B); and healthy untreated volunteers (n = 7) (group C). Bone densitometry scans (quantitative computed tomography (QCT) of spine; dual X-ray absorptiometry of spine, femoral neck, and single photon absorptiometry of forearm) were performed at baseline and after 6, 12 and 24 months of treatment. Biochemical bone marker measurements (serum osteocalcin, bone alkaline phosphatase, pro-collagen type 1 carboxy terminal propeptide, deoxypyridinoline and C-telopeptide of type 1 collagen) were collected every 3 months. Fifteen FP (mean age 36 yrs, six male) and 9 BDP patients (mean age 33 yrs, five male); completed the study. At 0 months, mean bone mineral density (BMD) was lower in patients receiving inhaled corticosteroids (both low dose and high dose) than in normal volunteers. In the FP-treated group, mean vertebral trabecular BMD quantitative computed tomography remained stable with no evidence of decline, whereas there was some decline in the BDP-treated group. The treatment difference between FP and BDP was statistically significant in favour of FP for quantitative computed tomography measurements after 12 months (p = 0.006) and 24 months (p = 0.004). This study suggests that over 24 months, changes in bone density are minimal in patients on high-dose inhaled corticosteroids.     

Systemic effects of inhaled corticosteroids on growth and bone turnover in childhood asthma: a comparison of fluticasone with beclomethasone.

Inhaled steroids are frequently used in childhood asthma, but concerns based on limited objective evidence remain, regarding long-term side-effects. In this study the systemic effects of standard doses of inhaled steroids in childhood asthma were assessed, comparing beclomethasone dipropionate (BDP) with fluticasone propionate (FP). The study was prospective, randomized and double-blind. Twenty-three steroid-naive children with moderately severe asthma, aged 5-10 yrs, were allocated either BDP (400 microg x day(-1) or FP (200 microg x day(-1)) using a metered-dose inhaler with a spacer. Asthma control was assessed at regular intervals over 20 months. Fasting morning blood and overnight urine samples were collected for estimation of serum cortisol, serum 1-carboxyterminal telopeptide (ICTP), serum osteocalcin and urine deoxypyridinoline (DPD). Bone mineral density (BMD) was measured at each visit. None of the markers of bone turnover showed any change during the study period. BMD increased at normal rates with age. Serum cortisol significantly decreased on BDP, but not on FP. A significant difference in growth rates was found between the groups, with a slower rate of growth towards the end of the observation period in the BDP group. In conclusion when taken in a relatively modest dose over a period of time, beclomethasone dipropionate had significant effects on the hypothalamic-pituitary-adrenal axis and statural growth in childhood asthma. These systemic effects were not seen with an equipotent dose of fluticasone propionate.     

Evaluation of adrenocortical function in 3-7 aged asthmatic children treated with moderate doses of fluticasone propionate: reliability of dehydroepiandrosterone sulphate (dhea-s) as a screening test

BackgroundInhaled corticosteroids (ICS) are the first-line therapy in the treatment of persistent asthma. At medium to high doses and prolonged usage, ICS can supresss the hypothalamic-pituitary-adrenal axis. Dehydroepiandrosterone sulphate (DHEA-S) is a corticotropin-dependent adrenal androgen precursor that is supressible in patients treated with ICS.ObjectivesTo evaluate the adrenal axis in asthmatic children treated with moderate doses of fluticasone propionate and to evaluate the DHEA-S as a possible marker for adrenal axis ?n preadrenarchal children.MethodsTwenty-eight children with persistent asthma with a mean age of 4.4 years (median 4.2; range 2.5-7.1) on long term treatment (mean 6.16; median 6; range 4.5-9 months) with moderate doses (mean 250; median 253; range 158-347 (g/m²/day) of inhaled fluticasone propionate were evaluated with low-dose ACTH stimulation test to assess adrenal function, and DHEA-S levels were compared with the results.ResultsOne out of 28 patients (3.57%) demonstrated an abnormal cortisol response to low-dose ACTH test. There was no correlation between DHEA-S and peak cortisol, morning cortisol and fasting blood glucose levels. However, mean inhaled corticosteroid dosages were inversely correlated with the DHEA-S.Conclus?onsIn most of the children with persistent asthma, mild to moderate fluticazone propionate doses supress the hypothalamic-pituitary-adrenal axis rarely. Chronic moderate doses of ICS may suppress adrenal androgen levels without supression of cortisol production. DHEA-S levels may be used as a practical method to follow adrenal functions and may be an earlier indicator of adrenal dysfunction in children.     

吸入丙酸氟替卡松对支气管哮喘患者肾上腺功能影响的meta分析

目的 根据现有临床研究评价吸入丙酸氟替卡松(FP)对支气管哮喘(简称哮喘)患者肾上腺功能影响的剂量效应关系.方法 从1978-2007年MEDLINE光盘数据库和1978-2007年中国生物医学光盘数据库,检索哮喘患者吸入FP为研究对象、比较吸入FP 4周后.进行促肾上腺皮质素刺激实验的随机对照实验文献,对肾上腺功能影响的剂量-效应关系进行随机、安慰剂对照的meta分析.结果 有5项研究中的732例哮喘患者符合纳入标准,安慰剂组肾上腺功能低于正常值例数是3.9%,FP组增加至500 μg/d的剂量,肾上腺功能异常增加的比数比是1.38(95%的可信限为1.01～1.59);当FP逐渐增加至2 000 μg/d,与肾上腺功能异常呈线性关系.结论 常规应用FP 200～500 μg/d是安全的,对肾上腺功能的影响很小.     

Adrenal Function as Assessed by Low-Dose Adrenocorticotropin Hormone Test Before and After Switching from Inhaled Beclomethasone Dipropionate to Inhaled Fluticasone Propionate

Low-dose adrenocorticotropin hormone (ACTH) tests (0.5 µg/L 73 m²) were done before and after switching from inhaled beclomethasone dipropionate to inhaled fluticasone propionate in 12 patients 33–77 years old who had mild-to-severe asthma to compare the effects of these drugs on adrenal function. Low-dose ACTH tests were performed after the subjects had received inhaled beclomethasone dipropionate (200–900 µg/day) for at least 12 wk. Treatment was then switched to inhaled fluticasone propionate (200–600 µg/day) for at least 12 wk, and a second low-dose ACTH test was done. Pulmonary function was assessed on the basis of peak expiratory flow rate (PEFR, % of predicted value). After switching treatment, the daily dose of inhaled corticosteroid decreased by about 40%. Basal serum cortisol and ACTH levels were similar with both treatments. The adrenal response, as assessed by incremental rise in the serum cortisol level (peak minus basal) after ACTH challenge, improved significantly (5.6–7.9 µg/dL, p<0.01) after switching to fluticasone. All three patients who had lower serum cortisol levels during beclomethasone treatment than during fluticasone treatment showed improvement in both the peak cortisol level and the incremental rise in cortisol. Mean morning and evening PEFRs significantly increased after switching from beclomethasone to fluticasone (morning: 71.2 to 76.0%, p<0.01; evening: 67.3 to 72.1%, both p<0.05). The diurnal variation of PEFR significantly decreased from 10.9% to 8.3% after switching treatment (p<0.01). We conclude that switching from beclomethasone to fluticasone reduces the risk of adrenal dysfunction associated with inhaled steroids and improves pulmonary function.     

吸入丙酸氟替卡松对支气管哮喘患者肾上腺功能影响的meta分析

目的根据现有临床研究评价吸入丙酸氟替卡松（FP）对支气管哮喘（简称哮喘）患者肾上腺功能影响的剂量-效应关系。方法从1978-2007年MEDLINE光盘数据库和1978-2007年中国生物医学光盘数据库,检索哮喘患者吸入FP为研究对象、比较吸入FP4周后,进行促肾上腺皮质素刺激实验的随机对照实验文献,对肾上腺功能影响的剂量-效应关系进行随机、安慰剂对照的meta分析。结果有5项研究中的732例哮喘患者符合纳入标准,安慰剂组肾上腺功能低于正常值例数是3.9% FP组增加至500μg/d的剂量,肾上腺功能异常增加的比数比是1.38（95%的可信限为1.01～1.59） 当FP逐渐增加至2000μg/d,与肾上腺功能异常呈线性关系。结论常规应用FP200～500μg/d是安全的,对肾上腺功能的影响很小。     

Adrenal suppression with dry powder formulations of fluticasone propionate and mometasone furoate

Mometasone furoate (MF) and fluticasone propionate (FP) are high potency inhaled corticosteroids. The systemic bioavailability of MF is claimed to be negligible, leading to a minimal potential for systemic adverse effects. We assessed the overnight urinary cortisol/creatinine as the primary outcome of adrenal suppression in 21 patients with persistent asthma (mean FEV1 = 91%). Patients were randomized in a crossover fashion to receive 2 weekly consecutive doubling incremental doses of either FP Accuhaler (500, 1,000, and 2,000 microg/day) or MF Twisthaler (400, 800, and 1,600 microg/day). For the 21 per protocol completed patients, there was significant suppression of overnight urinary cortisol/creatinine with high and medium doses of both drugs-as geometric mean fold suppression (95% confidence interval) from baseline: FP 2,000 microg, 1.85 (1.21-2.82, p = 0.002); FP 1,000 microg, 1.45 (1.07-1.96, p = 0.02); MF 1,600 microg, 1.92 (1.26-2.93, p = 0.001); and MF 800 microg, 1.39 (1.04-1.88, p = 0.02). For secondary outcomes of 8:00 A.M. plasma cortisol, serum osteocalcin, and early morning urinary cortisol/creatinine, there was significant suppression with MF and FP at the highest dose. Our data refute the assertion that MF has negligible systemic bioavailability and a lower potential for systemic adverse effects compared with FP.     

Children with mild asthma: do they benefit from inhaled corticosteroids?

In children with mild asthma, who show hardly any abnormalities in pulmonary function, objective measurement of the effect of inhaled corticosteroids is difficult. The short term effect of fluticasone propionate (FP) in these children was evaluated, using both subjective and objective parameters. A total of 68 children (5-10 yrs old) were randomly assigned to either FP 250 microg or placebo twice daily as metered-dose inhaler via spacer during 12 weeks. Symptom scores, use of rescue medication, wheezing, parent global evaluation and pulmonary function tests including forced expiratory volume in one second (FEV1), peak expiratory flow (PEF) and bronchial responsiveness (provocation dose of methacholine causing a 20% fall in FEV1 (PD20)) were evaluated. FP-treated versus placebo-treated children showed significant changes in percentage symptom-free days, use of beta2-mimetics, morning and evening PEF, FEV1 % pred and wheezing. No significant improvements were found in parent global evaluation, absolute values of FEV1 nor PD20. These findings show that inhaled corticosteroids are effective in children with mild asthma. This effect can be assessed by both objective and subjective parameters. Early start of inhaled corticosteroids should be considered even when pulmonary function is normal.     

Comparable effects of inhaled fluticasone propionate and budesonide on the HPA-axis in adult asthmatic patients

This randomized, double-blind, double-dummy, multicentre cross-over study compared the effects on the hypothalamic-pituitary-adrenal (HPA) axis of fluticasone propionate (750 microg twice daily given via the Diskus) and budesonide (800 microg twice daily given via the Turbuhaler). Two treatment periods of 2 weeks each were preceded by a 2-week run-in period and separated by a 2-week washout period. During run-in and washout, patients received beclomethasone dipropionate (BDP) or budesonide at a constant dose of 1500-1600 microg day(-1). Sixty patients aged 18-75 years with moderate to severe asthma not fully controlled by treatment with 1500-1600 microg day(-1) budesonide or BDP entered run-in and 45 completed the study. HPA axis suppression was assessed by morning serum cortisol (area under the curve from 08.00 to 10.30 hours) and 12-h nocturnal urinary cortisol excretion, measured at the end of run-in (baseline 1), at the end of washout (baseline 2), and at the end of each treatment period. Neither budesonide nor fluticasone produced significant suppression of either parameter compared to baselines. Only a few patients had serum-cortisol and urinary cortisol values below the normal range, before and after treatment. This shows that the patients did not have adrenal suppression before entering the study. The ratio between the AUC serum cortisol measured after fluticasone treatment and after budesonide treatment was 0.99 (95% CI 0.92-1.06), indicating equivalent effects on the HPA axis. This result was achieved after having omitted two patients' results, due to their very sensitive reaction to budesonide, but not to fluticasone. Two exacerbations of acute asthma occurred during budesonide treatment and none during fluticasone treatment. Both treatments were well tolerated. In conclusion, budesonide 1600 microg day(-1) via Turbuhaler and fluticasone propionate 1500 microg day(-1) via Diskus had no clinical effects on the HPA axis in patients with moderate to severe asthma.     

The effect of inhaled budesonide on adrenal and growth suppression in asthmatic children.

The present authors evaluated adrenal reserve in asthmatic children on long-term inhaled corticosteroids and whether possible adrenal suppression could be predicted by growth retardation. Low-dose synacthen test (0.5 microg x 1.73 m(-2)) was performed in 72 asthmatic children with a median age of 9.4 (range 4.2-15.7) yrs on long-term treatment (median 18 (range 6-84) months) with low-to-moderate doses (median 363 (range 127-1012) microg x m(-2)) of inhaled budesonide, as well as in 30 controls. Adrenal suppression was considered as a peak serum cortisol <495 nmol x L(-1). The current authors calculated height standard deviation score (HSDS) at the time of testing and height velocity SDS (HVSDS) in the preceding year. Mean HSDS was 0.06+/-1.3 and HVSDS was -0.9+/-2.3. Adrenal suppression was disclosed in 15 asthmatic children (20.8%). There were no differences in HSDS and HVSDS between children with and without adrenal suppression. There was no correlation between peak cortisol response and dose or duration of treatment. However, a positive relationship between HVSDS and duration of treatment was noted. These data suggest that long-term treatment of asthmatic children with low and moderate doses of inhaled budesonide may result in mild adrenal suppression that cannot be predicted by growth deceleration. The negative influence of inhaled corticosteroids on growth becomes less the longer the duration of treatment.     

Adrenal suppression, evaluated by a low dose adrenocorticotropin test, and growth in asthmatic children treated with inhaled steroids

The aim of the present study was to evaluate the prevalence of adrenal suppression and growth retardation in children using moderate doses of budesonide or fluticasone propionate. Seventy-five asthmatic children were randomly divided into three treatment groups: 30 to the fluticasone propionate (FP), 30 to the budesonide (BUD), and 15 to the cromone (CROM) group. FP doses were 500 microg/day during the first 2 months and 200 microg/day thereafter. The respective BUD doses were 800 and 400 microg/day. A low dose ACTH (0.5 microg/1.73 m2) test was performed before treatment and 2, 4, and 6 months later. The test was considered abnormal if the stimulated serum cortisol concentration was more than 2 SD lower than the pretreatment mean (<330 nmol/L). The low dose ACTH test was abnormal after both the high and low steroid doses in 23% of the children. At the 4 month measurement there were more abnormal tests in the BUD (n = 9) than in the FP (n = 5) group (P < 0.05). At that time also the stimulated concentration of serum cortisol was lower in the BUD than in the CROM group (P < 0.01), whereas the difference between the FP and CROM groups was not significant. During the study year the mean decrease in height SD score was 0.23 in the children treated with BUD, 0.03 in the children treated with FP, and 0.09 in the children treated with CROM; the difference between the BUD and FP groups was significant (P < 0.05). In conclusion, the low dose ACTH test revealed mild adrenal suppression in a quarter of the children using moderate doses of inhaled steroids. A FP dose of 200 microg/day caused less adrenal and growth suppression than did a BUD dose of 400 microg/day.     

Salmeterol/fluticasone propionate (50/500 microg) in combination in a Diskus inhaler (Seretide) is effective and safe in the treatment of steroid-dependent asthma

This multicentre double-blind, double-dummy study compared the safety and efficacy of a new combination Diskus inhaler containing both salmeterol 50 microg and fluticasone propionate 500 microg (Seretide, GlaxoWellcome, France) with the same doses of the two drugs delivered via separate Diskus inhalers and with the same dose of fluticasone propionate alone. Patients were eligible for study entry if they had received an inhaled corticosteroid continuously for 12 weeks prior to run-in, and had received treatment with beclomethasone dipropionate or budesonide 1500-2000 microg day(-1) or fluticasone propionate 750-1000 microg day(-1) for at least 4 weeks prior to run-in. In total, 503 patients receiving inhaled corticosteroids were randomized to 28 weeks' treatment with either salmeterol/fluticasone propionate (50/500 microg) via a single Diskus inhaler (combination) and placebo, or salmeterol 50 microg and fluticasone propionate 500 microg administered via separate Diskus inhalers (concurrent), or fluticasone propionate 500 microg and placebo. All treatments were administered twice daily, mean morning peak expiratory flow rate (PEFR) and asthma symptoms were measured for the first 12 weeks and safety data were collected throughout the 28-week study. Over weeks 1 to 12, improvement in adjusted mean morning PEFR was 35 and 33 l min(-1), respectively, in the combination and concurrent therapy treatment groups (12 and 10% increase from baseline, respectively). The mean difference between treatments was -3 l min(-1) (90% confidence interval -10.4 l min(-1)) which was within the criteria for clinical equivalence. However, the combination therapy was statistically significantly superior to fluticasone propionate alone for mean morning PEFR (P<0.001) and other measures of lung function, whilst clinical equivalence of the combination and concurrent therapies was observed. All three treatments were well tolerated. In addition, there were no differences between the three treatments in either the c.hange in serum cortisol or urinary cortisol concentrations, which, for each treatment group, were no significantly different from baseline at the end of the treatment period. Thus, the combination of salmeterol and fluticasone propionate in a single inhaler is as well tolerated and effective in achieving asthma control in steroid-dependent patients as the separate administration of the two drugs, and both combination and concurrent therapy are superior to administration of the same dose of corticosteroid alone.     

Serum dehydroepiandrosterone sulfate concentration as an indicator of adrenocortical suppression in asthmatic children treated with inhaled steroids

ACTH regulates adrenal androgen production, which may thus be reduced during glucocorticosteroid therapy. Dehydroepiandrosterone sulfate is the most abundant androgen secreted by the adrenals. We wished to evaluate whether serum levels of dehydroepiandrosterone sulfate can be used as an indicator of adrenal suppression during inhaled steroid treatment in children. Sixty school-aged children with newly diagnosed asthma were randomly divided into budesonide (n = 30) and fluticasone propionate (n = 30) groups. Fifteen cromone-treated children served as a control group. The budesonide dose was 800 microg/d during the first 2 months and 400 microg/d thereafter. The respective fluticasone propionate doses were 500 and 200 microg/d. Serum dehydroepiandrosterone sulfate concentrations were measured before and after 2 and 4 months of treatment. In the budesonide group, serum dehydroepiandrosterone sulfate decreased from the baseline by a mean of 21% (95% confidence interval, 13-29%; P < 0.001) after 2 months of high dose treatment and by 16% (95% confidence interval, 8-25%; P < 0.001) after 4 months of treatment. In the fluticasone propionate group, the respective figures were 10% (95% confidence interval, 4-16%; P < 0.01) and 6% (95% confidence interval, 16% decrease-3% increase; P = NS). A low dose ACTH test indicated adrenocortical suppression at 4 months in 14 (23%) steroid-treated children. In these children, dehydroepiandrosterone sulfate decreased by a mean of 21% (95% confidence interval, 14-28%), whereas in those 46 steroid-treated children with normal ACTH test results, dehydroepiandrosterone sulfate decreased by 8% (95% confidence interval, 0-16%; P < 0.05 between these groups). In the control group, dehydroepiandrosterone sulfate levels tended to increase (by a mean of 26%), reflecting the normal physiological change at this age. In conclusion, inhaled steroid treatment suppresses dehydroepiandrosterone sulfate production in a dose-dependent manner. Monitoring of serum dehydroepiandrosterone sulfate concentrations can be used as a practical method to follow adrenocortical function and to detect its suppression during inhaled steroid treatment in children.     

Effects of inhaled corticosteroids on growth in asthmatic children: a comparison of fluticasone propionate with budesonide.

In asthmatic children inhaled corticosteroids are widely used. However, there are some concerns about the systemic adverse effects of these drugs, especially in the growing child. We performed this prospective study in order to compare the effects of 400 microg/day of budesonide (BUD) and 250 microg/day of fluticasone propionate (FP) on growth in prepubertal (aged 4-11.5 years), moderate persisting asthmatic children. One hundred patients (51 boys and 49 girls), who were randomized into two groups, were recruited for the study. The first group was treated with BUD, 2X 200 microg/day, and the second group was treated with FP, 2X 125 microg/day, by using a medium-size volume-spacer metered-dose inhaler. Growth in children with asthma who were treated by inhaled corticosteroids was calculated by growth velocity over a 12-month period. Comparisons between treatment groups were calculated by t-test and chi-square test. There were no significant differences between BUD and FP groups for sex, age, first height, and growth velocity. Moderate persisting, prepubertal asthmatic children treated with 250 microg/day of FP appeared to have no different linear growth than those children who received 400 microg/day of BUD.     

Aseptic femoral head necrosis in a patient receiving long term courses of inhaled and intranasal corticosteroids

Aseptic (avascular) necrosis of the femoral head in adults has been associated with a variety of disease entities. It is also recognized as a potential complication of systemic corticosteroid therapy. Inhaled corticosteroids are the first line anti-inflammatory agents for the long term treatment of asthma. However, long term treatment of asthma with inhaled corticosteroids has been accompanied by concern about both systemic and topical side effects. The most worrying potential systemic effects are adrenal insufficiency, growth suppression, glaucoma and osteoporosis. Fluticasone proprionate may be prescribed at higher doses to relieve respiratory symptoms in the belief that it generates fewer side effects than other inhaled steroids. Studies have shown that fluticasone is safer than beclomethasone or budesonide, with limited oral absorption and extensive hepatic first pass metabolism leading to a lower systemic bioavailability. However growth retardation and asymptomatic adrenal suppression in children receiving high-dose fluticasone have been reported. We report a rare case of avascular osteonecrosis of the femoral head associated with the use of long term inhaled fluticasone propionate along with the intranasal application of triamcinolone acetonide.     

A dose-ranging study of fluticasone propionate administered once daily via multidose powder inhaler to patients with moderate asthma

STUDY OBJECTIVE: This dose-ranging study evaluated the clinical efficacy and safety of inhaled fluticasone propionate administered once daily via a multidose powder inhaler in patients with moderate asthma (FEV(1), 45 to 75% predicted). MATERIALS AND METHODS: In this multicenter trial, 330 patients (> or = 12 years old) previously receiving inhaled corticosteroids or beta(2)-agonists alone were randomized in a double-blind manner to receive fluticasone propionate at 100, 200, or 500 microg once daily or matching placebo for 12 weeks. RESULTS: Once-daily treatment with fluticasone propionate resulted in an improvement in efficacy variables, such as FEV(1), morning and evening peak expiratory flow (PEF), asthma symptom scores, nighttime awakenings, albuterol use, and duration of study participation. A dose-related trend was observed for improvements in morning and evening PEF and albuterol use. Statistical significance for pairwise comparisons was achieved for 200 microg and 500 microg fluticasone propionate vs placebo for all efficacy variables, and for 100 microg fluticasone propionate vs placebo for morning and evening PEF at most or all time points. Drug-related adverse events were few (< or = 5%) and mostly related to the topical effects of inhaled corticosteroids. No dose-response effect or clinically relevant differences were observed in morning plasma cortisol concentrations or after cosyntropin stimulation. CONCLUSION: Once-daily treatment with fluticasone propionate was well tolerated and demonstrated some dose-related trends in improvements in lung function and asthma control in patients with moderate asthma.