Aliskiren penetrates adipose and skeletal muscle tissue and reduces renin-angiotensin system activity in obese hypertensive patients.

OBJECTIVE: In animals, the direct renin inhibitor aliskiren showed extensive tissue binding in the kidney and long-lasting renal effects. Aliskiren provides prolonged blood pressure-lowering effects following treatment discontinuation in patients. Therefore, we investigated whether aliskiren attains tissue concentrations sufficient to inhibit local renin-angiotensin system (RAS) activity in patients. METHODS: We included 10 hypertensive patients with abdominal adiposity in an open-label study. Following 1-2 weeks washout, patients received 2 weeks placebo, then 4 weeks aliskiren 300 mg once daily, followed by 4 weeks washout, and then 4 weeks amlodipine 5 mg once daily. Drug concentrations and RAS biomarkers were measured in interstitial fluid using microdialysis and in biopsies from abdominal subcutaneous adipose and skeletal muscle. RESULTS: We detected aliskiren in all compartments. After 4 weeks of treatment, microdialysate aliskiren concentrations (ng/ml) were 2.4 ±â€Š2.1 (adipose) and 7.1 ±â€Š4.2 (skeletal muscle), similar to plasma concentrations (8.4 ±â€Š4.4); tissue concentrations (ng/g) were 29.0 ±â€Š16.7 (adipose) and 107.3 ±â€Š68.6 (skeletal muscle). Eight weeks after discontinuation, aliskiren was measurable in tissue biopsies but not in plasma or in interstitial fluid. Pooled microdialysate samples from two sets of four patients suggested reduction in tissue angiotensin II with aliskiren but not with amlodipine. CONCLUSION: In obese hypertensive patients, aliskiren penetrates adipose and skeletal muscle tissue at levels that are apparently sufficient to reduce tissue RAS activity. Furthermore, tissue binding may contribute to aliskiren's prolonged blood pressure-lowering effect following discontinuation.

Early clinical development of artemether-lumefantrine dispersible tablet: palatability of three flavours and bioavailability in healthy subjects.

BACKGROUND: Efforts to ease administration and enhance acceptability of the oral anti-malarial artemether-lumefantrine (A-L) crushed tablet to infants and children triggered the development of a novel dispersible tablet of A-L. During early development of this new formulation, two studies were performed in healthy subjects, one to evaluate the palatability of three flavours of A-L, and a second one to compare the bioavailability of active principles between the dispersible tablet and the tablet (administered crushed and intact). METHODS: Study 1 was performed in 48 healthy schoolchildren in Tanzania. Within 1 day, all subjects tasted a strawberry-, orange- and cherry-flavoured oral A-L suspension for 10 seconds (without swallowing) in a randomized, single-blind, crossover fashion. The palatability of each formulation was rated using a visual analogue scale (VAS). Study 2 was an open, randomized crossover trial in 48 healthy adults given single doses of A-L (80 mg artemether + 480 mg lumefantrine) with food. The objectives were to compare the bioavailability of artemether, dihydroartemisinin (DHA) and lumefantrine between the dispersible tablet and the tablet administered crushed (primary objective) and intact (secondary objective). RESULTS: Study 1 showed no statistically significant difference in VAS scores between the three flavours but cherry had the highest score in several ratings (particularly for overall liking). Study 2 demonstrated that the dispersible and crushed tablets delivered bioequivalent artemether, DHA and lumefantrine systemic exposure (area under the curve [AUC]); mean ± SD AUC0-tlast were 208 ± 113 vs 195 ± 93 h.ng/ml for artemether, 206 ± 81 vs 199 ± 84 h.ng/ml for DHA and 262 ± 107 vs 291 ± 106 h x µg/ml for lumefantrine. Bioequivalence was also shown for peak plasma concentrations (Cmax) of DHA and lumefantrine. Compared with the intact tablet, the dispersible tablet resulted in bioequivalent lumefantrine exposure, but AUC and Cmax values of artemether and DHA were 20-35% lower. CONCLUSIONS: Considering that cherry was the preferred flavour, and that the novel A-L dispersible tablet demonstrated similar pharmacokinetic performances to the tablet administered crushed, a cherry-flavoured A-L dispersible tablet formulation was selected for further development and testing in a large efficacy and safety study in African children with malaria.

Pharmacokinetics, safety and tolerability of single and multiple oral doses of aliskiren in healthy Chinese subjects: a randomized, single-blind, parallel-group, placebo-controlled study.

BACKGROUND: Aliskiren is the first oral direct renin inhibitor to be approved for the treatment of hypertension. The pharmacokinetic and pharmacodynamic profile of aliskiren has been extensively characterized in Caucasian individuals; however, drug disposition, treatment response and tolerability can vary among ethnic groups, and these variations are difficult to predict. OBJECTIVE: To evaluate the single- and multiple-dose pharmacokinetics of aliskiren in healthy Chinese subjects. METHODS: This was a randomized, single-blind, parallel-group, placebo-controlled study. On day -1, subjects were randomized to one of four cohorts (aliskiren 75, 150, 300 or 600 mg). On day 1, eight individuals in each cohort received a single dose of active treatment and two received placebo. Subjects randomized to aliskiren 300 mg received additional once-daily doses on days 5-11 to establish steady-state pharmacokinetics. Subjects receiving aliskiren 75, 150 or 600 mg (cohorts 1, 2 and 4) completed the study at the end of the 96-hour pharmacokinetic assessment period. Subjects receiving aliskiren 300 mg (cohort 3) had additional pharmacokinetic assessments on days 5-15. The study was carried out at the Peking Union Medical College Hospital, Beijing, China, and included 40 healthy Chinese subjects. The main outcome measures were the pharmacokinetic parameters for aliskiren, including area under the plasma concentration-time curve from time zero to infinity (AUC(infinity)) and maximum plasma concentration (C(max)). RESULTS: Aliskiren AUC(infinity) and C(max) increased greater than proportionally across the 8-fold dose range (75-600 mg; mean AUC(infinity) 291-4726 ng x h/mL, mean C(max) 62-699 ng/mL), but a dose-proportional 2-fold increase was observed within the clinically approved dose range (150-300 mg; mean AUC(infinity) 876-1507 ng x h/mL, mean C(max) 137-271 ng/mL). CONCLUSION: At steady state, the mean AUC during the dosage interval (AUC(tau)) for aliskiren 300 mg (1532 +/- 592 ng x h/mL) was similar to the AUC(infinity) observed following a single dose. Aliskiren exhibits similar single-dose and steady-state pharmacokinetics in Chinese subjects compared with those observed in Caucasian individuals in previous studies.

Influence of body weight and gender on the pharmacokinetics, pharmacodynamics, and antihypertensive efficacy of aliskiren.

Gender and body weight influence the pharmacokinetics and pharmacodynamics of many drugs. This pooled analysis of 17 clinical studies evaluated the effect of gender, body mass index (BMI), body weight, and lean body weight (LBW) on the pharmacokinetics of the direct renin inhibitor aliskiren in healthy volunteers (n = 392). A separate pooled analysis of 5 clinical studies in patients with hypertension (n = 2327) assessed the influence of gender and BMI on the effects of aliskiren on plasma renin activity and blood pressure. Area under the aliskiren plasma concentration-time curve (AUC(τ)) was 22% lower and the peak aliskiren plasma concentration (C(max)) was 24% lower in men than women (P < .05). BMI was not significantly correlated with AUC(τ) (r = 0.005; P = .917); AUC(τ) was negatively correlated with body weight (r = -0.235; P < .0001) and LBW (r = -0.295; P < .0001). Results were similar for C(max). Adjusting individual aliskiren AUC(τ) and C(max) values for overall mean body weight or LBW abolished gender differences. Based on r(2) values, LBW variation accounted for 8.9% of aliskiren AUC(τ) variation. In patients with hypertension, gender and BMI did not significantly influence the effects of aliskiren on plasma renin activity or blood pressure. It was concluded that lower systemic exposure to aliskiren in men versus women relates to differences in body weight; neither gender nor body weight has clinically relevant effects on the pharmacokinetics or pharmacodynamics of aliskiren.

Pharmacokinetic interaction of the direct renin inhibitor aliskiren with furosemide and extended-release isosorbide-5-mononitrate in healthy subjects.

This study investigated the pharmacokinetics, safety, and tolerability of aliskiren administered alone or in combination with either the loop diuretic furosemide or an oral extended-release formulation of isosorbide-5-mononitrate (ISMN). In separate studies, 22 healthy subjects (ages 18-45 years) received either ISMN 40 mg or furosemide 20 mg once-daily for 3 days followed by a 3-day washout. Subjects then received aliskiren 300 mg once-daily for 7 days followed by combination therapy for 3 days. Pharmacokinetic assessments were taken at regular intervals over 24 h after dosing on the last day of each treatment period. At steady state, aliskiren AUC(tau) was decreased by 7% (geometric mean ratio [90% CI], 0.93 [0.84, 1.04]), and C(max) by 20% (0.80 [0.65, 0.97]) with furosemide coadministration compared with aliskiren administration alone. Aliskiren coadministration reduced furosemide AUC(tau) by 28% (0.72 [0.64, 0.81]) and C(max) by 49% (0.51 [0.39, 0.66]) compared with furosemide alone. Coadministration of aliskiren and ISMN was associated with only minor changes in the pharmacokinetic parameters of aliskiren (AUC(tau) 1.03 [0.90, 1.18]; C(max) 0.94 [0.69, 1.29]) and ISMN (AUC(tau) 0.88 [0.71, 1.10]; C(max) 0.94 [0.79, 1.13]). Headache and dizziness were the most common adverse events in both studies; dizziness and BP values below normal (SBP < 90 and/or DBP < 50 mmHg) were more frequent with aliskiren and ISMN coadministration than with either agent alone. Coadministration of aliskiren and ISMN had no clinically relevant effect on either aliskiren or ISMN pharmacokinetics. In conclusion, coadministration of aliskiren and furosemide reduced furosemide exposure and had a minor effect on aliskiren pharmacokinetics. The clinical significance of reduced systemic exposure to furosemide during coadministration of aliskiren is uncertain.

A study of the pharmacokinetic interactions of the direct renin inhibitor aliskiren with metformin, pioglitazone and fenofibrate in healthy subjects.

OBJECTIVE: Hypertension and type 2 diabetes are common comorbidities, thus many patients receiving antihypertensive medication require concomitant therapy with hypoglycemic or lipid-lowering drugs. The aim of these three studies was to investigate the pharmacokinetics, safety and tolerability of aliskiren, a direct renin inhibitor for the treatment of hypertension, co-administered with the glucose-lowering agents metformin or pioglitazone or the lipid-lowering agent fenofibrate in healthy volunteers. METHODS: In three open-label, multiple-dose studies, healthy volunteers (ages 18 to 45 years) received once-daily treatment with either metformin 1000 mg (n = 22), pioglitazone 45 mg (n = 30) or fenofibrate 200 mg (n = 21) and aliskiren 300 mg, administered alone or co-administered in a two-period study design. Blood samples were taken frequently on the last day of each treatment period to determine plasma drug concentrations. RESULTS: Co-administration of aliskiren with metformin decreased aliskiren area under the plasma concentration- time curve during the dose interval (AUC(tau)) by 27% (geometric mean ratio [GMR] 0.73; 90% confidence interval [CI] 0.64, 0.84) and maximum observed plasma concentration (C(max)) by 29% (GMR 0.71; 90% CI 0.56, 0.89) but these changes were not considered clinically relevant. Co-administration of aliskiren with fenofibrate had no effect on aliskiren AUC (GMR 1.05; 90% CI 0.96, 1.16) or C(max) (GMR 1.05; 90% CI 0.80, 1.38); similarly, co-administration of aliskiren with pioglitazone had no effect on aliskiren AUC(tau) (GMR 1.05; 90% CI 0.98, 1.13) or C(max) (GMR 1.01; 90% CI 0.84, 1.20). All other AUC and C(max) GMRs for aliskiren, metformin, pioglitazone, ketopioglitazone, hydroxypioglita-zone and fenofibrate were close to unity and the 90% CI were contained within the bioequivalence range of 0.80 to 1.25. CONCLUSION: Co-administration of aliskiren with metformin, pioglitazone or fenofibrate had no significant effect on the pharmacokinetics of these drugs in healthy volunteers. These findings indicate that aliskiren can be co-administered with metformin, pioglitazone or fenofibrate without the need for dose adjustment.

Pharmacokinetics of the oral direct renin inhibitor aliskiren in combination with digoxin, atorvastatin, and ketoconazole in healthy subjects: the role of P-glycoprotein in the disposition of aliskiren.

This study investigated the potential pharmacokinetic interaction between the direct renin inhibitor aliskiren and modulators of P-glycoprotein and cytochrome P450 3A4 (CYP3A4). Aliskiren stimulated in vitro P-glycoprotein ATPase activity in recombinant baculovirus-infected Sf9 cells with high affinity (K(m) 2.1 micromol/L) and was transported by organic anion-transporting peptide OATP2B1-expressing HEK293 cells with moderate affinity (K(m) 72 micromol/L). Three open-label, multiple-dose studies in healthy subjects investigated the pharmacokinetic interactions between aliskiren 300 mg and digoxin 0.25 mg (n = 22), atorvastatin 80 mg (n = 21), or ketoconazole 200 mg bid (n = 21). Coadministration with aliskiren resulted in changes of <30% in AUC(tau) and C(max,ss) of digoxin, atorvastatin, o-hydroxy-atorvastatin, and rho-hydroxy-atorvastatin, indicating no clinically significant interaction with P-glycoprotein or CYP3A4 substrates. Aliskiren AUC(tau) was significantly increased by coadministration with atorvastatin (by 47%, P < .001) or ketoconazole (by 76%, P < .001) through mechanisms most likely involving transporters such as P-glycoprotein and organic anion-transporting peptide and possibly through metabolic pathways such as CYP3A4 in the gut wall. These results indicate that aliskiren is a substrate for but not an inhibitor of P-glycoprotein. On the basis of the small changes in exposure to digoxin and atorvastatin and the <2-fold increase in exposure to aliskiren during coadministration with atorvastatin and ketoconazole, the authors conclude that the potential for clinically relevant drug interactions between aliskiren and these substrates and/or inhibitors of P-glycoprotein/CPY3A4/OATP is low.

Effects of aliskiren, a direct Renin inhibitor, on cardiac repolarization and conduction in healthy subjects.

This multicenter, double-blind study evaluated the effects of aliskiren, a direct renin inhibitor approved for hypertension, on cardiac repolarization and conduction. Healthy volunteers (n = 298) were randomized to aliskiren 300 mg, aliskiren 1200 mg, moxifloxacin 400 mg (positive control), or placebo once daily for 7 days. Digitized electrocardiograms were obtained at baseline and day 7 of treatment over 23 hours postdose. Placebo-adjusted mean changes from baseline in QTcF (Fridericia corrected), QTcI (individualized correction), PR, and QRS intervals were compared at each time point (time-matched analysis) and for values averaged across the dosing period (baseline-averaged analysis). In time-matched analysis, mean changes in QTcF with aliskiren were below predefined limits for QTc prolongation (mean increase <5 milliseconds; upper 90% confidence interval [CI] <10 milliseconds) except aliskiren 1200 mg at 23 hours (5.2 milliseconds; 90% CI 2.2, 8.1). With moxifloxacin, significant QTcF prolongation occurred at most time points, confirming the sensitivity of the assay. Baseline-averaged analysis was consistent with time-matched analysis. Instances of QTcF interval >450 milliseconds or a >30-millisecond increase from baseline with aliskiren (< or = 1%) were similar or lower than placebo (< or = 4%). Results were similar for QTcI. Aliskiren had no effect on PR or QRS duration. In conclusion, aliskiren at the highest approved dose (300 mg) and a 4-fold higher dose had no effect on cardiac repolarization or conduction in healthy volunteers.

A study of the pharmacokinetic interactions of the direct renin inhibitor aliskiren with allopurinol, celecoxib and cimetidine in healthy subjects.

OBJECTIVE: Aliskiren is the first in a new class of orally effective direct renin inhibitors approved for the treatment of hypertension. This multiple-dose study investigated the potential for pharmacokinetic interactions between aliskiren and three drugs, each predominantly eliminated by a different clearance/metabolic pathway: allopurinol (glomerular filtration), celecoxib (cytochrome P450 metabolism) and cimetidine (P-glycoprotein and organic anion/cation transporters). RESEARCH DESIGN AND METHODS: Three open-label, multiple-dose studies in healthy subjects investigated possible pharmacokinetic interactions between aliskiren 300 mg od and allopurinol 300 mg od (n = 20), celecoxib 200 mg bid (n = 22), or cimetidine 800 mg od (n = 22). Subjects received aliskiren alone or co-administered with allopurinol, celecoxib or cimetidine. Allopurinol and celecoxib were also administered alone and in combination with aliskiren. Plasma drug concentrations were determined by LC/MS/MS. RESULTS: Co-administration of aliskiren with allopurinol had no effect on allopurinol AUC(tau) (ratio of geometric means 0.93 [90% CI, 0.88, 0.98]) or oxypurinol AUC(tau) (mean ratio 1.12 [90% CI, 1.08, 1.16]) and C(max) (mean ratio 1.08 [90% CI, 1.04, 1.13]), with 90% CI within the bioequivalence range 0.80-1.25, and a minor effect on allopurinol C(max) (mean ratio 0.88 [90% CI, 0.78, 1.00]). Aliskiren co-administration had no effect on AUC(tau) or C(max) of celecoxib (mean ratios and 90% CI within range 0.80-1.25). Neither allopurinol nor celecoxib significantly altered aliskiren AUC(tau) or C(max) (geometric mean ratios 0.88-1.02 with 90% CI including 1.00, but with some 90% CI outside the 0.80-1.25 range due to high variability). Co-administration of aliskiren with cimetidine increased aliskiren AUC(tau) by 20% (mean ratio 1.20 [90% CI, 1.07, 1.34]) and C(max) by 25% (mean ratio 1.25 [90% CI, 0.98, 1.59]). CONCLUSIONS: In this multiple-dose study, aliskiren showed no clinically relevant pharmacokinetic interactions when co-administered with allopurinol, celecoxib or cimetidine in healthy subjects.

Pharmacokinetics, safety, and tolerability of the novel oral direct renin inhibitor aliskiren in elderly healthy subjects.

This open-label, multicenter study compared the pharmacokinetics and safety of the oral direct renin inhibitor aliskiren in 29 elderly (>or=65 years) and 28 young (18-45 years) healthy subjects. Plasma drug concentrations were determined for up to 168 hours following a single 300-mg oral dose of aliskiren. In elderly compared with young subjects, AUC(0-infinity) was 57% higher (ratio of geometric means 1.57, 90% confidence interval: 1.19, 2.06; P = .008) and C(max) was 28% higher (1.28, 90% confidence interval: 0.91, 1.79; P=.233). Other parameters, including t(max) and Vd/F, were similar between age groups. No differences in aliskiren exposure were observed between subjects ages 65 to 74 years (n=16) and >or=75 years (n=13). Aliskiren was well tolerated by all age groups, including the very elderly. In conclusion, aliskiren exposure is modestly increased in elderly subjects. Based on its wide therapeutic index and shallow dose response for blood pressure lowering, no initial dose adjustment should be needed for elderly patients.

Aliskiren exhibits similar pharmacokinetics in healthy volunteers and patients with type 2 diabetes mellitus.

BACKGROUND: The renin system is an attractive target for antihypertensive therapy in patients with diabetes mellitus. However, diabetes is associated with changes in gastrointestinal, renal and hepatic function that may affect the absorption and disposition of oral drugs. This study compared the pharmacokinetics and pharmacodynamics of the orally active direct renin inhibitor, aliskiren, in healthy volunteers and patients with type 2 diabetes. METHODS: This was an open-label study conducted in 30 patients with type 2 diabetes and 30 healthy volunteers matched for age, bodyweight and race. Following a 10-hour fast, all participants received a single oral dose of aliskiren 300mg. Blood samples were taken at frequent intervals for 96 hours post-dose for determination of plasma concentrations of aliskiren (using a high-performance liquid chromatography-tandem mass spectroscopy method). Plasma renin activity (PRA) and renin concentration (RC) were also measured for 24 hours after dosing. RESULTS: Aliskiren exhibited similar pharmacokinetics in patients with type 2 diabetes and healthy volunteers. Exposure to aliskiren was slightly higher in patients with type 2 diabetes compared with healthy volunteers (mean area under the plasma concentration-time curve from 0 to 24 hours 1859 vs 1642 ng . h/mL; maximum observed plasma drug concentration 394 vs 348 ng/mL), while apparent clearance corrected for bioavailability was slightly lower (205 vs 234 L/h) and elimination half-life slightly longer (44 vs 39.9 hours), but there were no statistically significant differences for any pharmacokinetic parameters. There was no significant correlation between glycaemic control (% glycosylated haemoglobin) and any of the measured pharmacokinetic parameters in patients with type 2 diabetes. Aliskiren caused sustained suppression of PRA for at least 24 hours after dosing despite increasing RC; there were no major differences in the pharmacodynamic effects of aliskiren between patients with type 2 diabetes and healthy volunteers. Aliskiren was well tolerated in both patient groups, with no clinically significant changes in laboratory values and a low risk of adverse events. CONCLUSION: Aliskiren showed a similar pharmacokinetic profile in healthy volunteers and patients with type 2 diabetes, and administration of a single oral 300 mg dose of aliskiren was well tolerated by both patients and healthy volunteers. The pharmacodynamic effects of aliskiren were also similar in healthy volunteers and diabetic patients, with sustained inhibition of renin system activity observed for at least 24 hours after dosing.

Randomized calcineurin inhibitor cross over study to measure the pharmacokinetics of co-administered enteric-coated mycophenolate sodium.

Enteric-coated mycophenolate sodium (EC-MPS) (myfortic) is an advanced formulation delivering mycophenolic acid (MPA), designed to improve MPA-related upper gastrointestinal adverse events by delaying the release of MPA until the small intestine. A randomized, calcineurin inhibitor crossover, steady-state pharmacokinetic study in stable renal transplant patients receiving EC-MPS demonstrated increased MPA exposure of 19% higher, MPA C(max,ss) 19% lower and MPA C(min,ss) approximately twofold higher with tacrolimus, than cyclosporine microemulsion. No study drug-related adverse events were recorded, but mean blood glucose concentration was higher in patients receiving tacrolimus (p = 0.031). The dose changes in relation to MPA exposure in patients is dependent on the clinical situation and may not always be warranted. These observations should be taken into consideration when switching from one calcineurin inhibitor to another, but the final dosage should be based on both this pharmacokinetic data and the clinical situation.

Lumiracoxib: pharmacokinetic and pharmacodynamic profile when coadministered with fluconazole in healthy subjects.

This two-way crossover study evaluated the effect of fluconazole on the pharmacokinetics and selective COX-2 inhibition of lumiracoxib. Thirteen healthy subjects were randomized to fluconazole (day 1: 400 mg; days 2-4: 200 mg) or no drug. On day 4, all subjects received a single dose of lumiracoxib (400 mg). Lumiracoxib pharmacokinetics were assessed during the following 48 hours. Thromboxane B(2) (TxB(2)) inhibition was measured prior to lumiracoxib dosing and 2 hours afterwards. Fluconazole caused a small (18%) but not clinically relevant increase in lumiracoxib mean AUC(0- infinity ) but had no effect on lumiracoxib mean C(max). The geometric mean ratio (lumiracoxib plus fluconazole/lumiracoxib alone) for AUC(0- infinity ) was 1.19 (90% confidence interval [CI] = 1.12, 1.27) and for C(max) was 1.11 (90% CI = 0.98, 1.27). The decrease in TxB(2) from predose was not significantly different for lumiracoxib (11.8%) or lumiracoxib plus fluconazole (7.1%); no correlation between lumiracoxib concentration and TxB(2) decrease was seen. As fluconazole is a strong inhibitor of cytochrome P450 (CYP) 2C9, other CYP2C9 inhibitors are unlikely to affect lumiracoxib pharmacokinetics with clinical relevance, making dosage adjustment unnecessary.

Pharmacokinetics of multiple doses of valsartan in patients with heart failure.

Angiotensin II has adverse actions in heart failure including vasoconstriction, aldosterone secretion, and activation of the sympathetic nervous system. Valsartan, a potent specific angiotensin II type 1 receptor blocker, may produce beneficial effects in heart failure. The purpose of this study was to evaluate the steady-state pharmacokinetics of valsartan 40, 80, and 160 mg each given every 12 h for 7 days in heart failure patients. Eighteen patients with chronic stable heart failure and left ventricular ejection fractions

Formoterol provides long-lasting protection against exercise-induced bronchospasm.

BACKGROUND: Patients with exercise-induced bronchospasm (EIB) may benefit from a prophylactic beta2-adrenergic agonist that combines rapid onset with long duration of action. OBJECTIVE: To compare the protective effect against EIB of a single inhaled dose of formoterol powder delivered via the Aerolizer inhaler (Novartis Pharmaceuticals, East Hanover, NJ) with the effect of placebo and albuterol. METHODS: Eighteen patients with EIB were randomized to treatment in a double-blind, placebo-controlled, four-way, crossover study. Seventeen patients completed all four crossover periods. Each patient received in random sequence a single dose of formoterol (12 or 24 microg), albuterol (180 microg), or placebo at intervals of 5 +/- 2 days. Pulmonary function measurements were taken before and after exercise challenge tests (ECTs) at 15 minutes postdosing and at 4, 8, and 12 hours postdosing. RESULTS: Both doses of formoterol produced significantly greater protection against EIB, compared with placebo, at all timepoints (P < or = 0.016). The two doses of formoterol were not significantly different from one another at any time. Protection against EIB with albuterol was clinically significant only for the 15-minute ECT and was statistically superior to placebo for the 15-minute and 4-hour ECTs. Although formoterol and albuterol exhibited a rapid onset of action, formoterol provided longer-lasting protection over the 12-hour observation period. Rescue medication was used substantially less with either dose of formoterol, compared with albuterol or placebo. All treatments were well tolerated. Two-hour postdosing electrocardiograms and vital signs were unremarkable for all study treatments. CONCLUSION: A single dose of formoterol (12 or 24 microg) provides protection against EIB within 15 minutes of dosing and persists for up to 12 hours. Formoterol is safe and well tolerated.