Salmeterol and Fluticasone Propionate and Survival in Chronic Obstructive Pulmonary Disease
Peter M.A. Calverley, M.D., Julie A. Anderson, M.A., Bartolome Celli, M.D., Gary T. Ferguson, M.D., Christine Jenkins, M.D., Paul W. Jones, M.D., Julie C. Yates, B.S., Jørgen Vestbo, M.D., for the TORCH investigators
Background Long-acting beta-agonists and inhaled corticosteroidsare used to treat chronic obstructive pulmonary disease (COPD),but their effect on survival is unknown.
Methods We conducted a randomized, double-blind trial comparingsalmeterol at a dose of 50 µg plus fluticasone propionateat a dose of 500 µg twice daily (combination regimen),administered with a single inhaler, with placebo, salmeterolalone, or fluticasone propionate alone for a period of 3 years.The primary outcome was death from any cause for the comparisonbetween the combination regimen and placebo; the frequency ofexacerbations, health status, and spirometric values were alsoassessed.
Results Of 6112 patients in the efficacy population, 875 diedwithin 3 years after the start of the study treatment. All-causemortality rates were 12.6% in the combination-therapy group,15.2% in the placebo group, 13.5% in the salmeterol group, and16.0% in the fluticasone group. The hazard ratio for death inthe combination-therapy group, as compared with the placebogroup, was 0.825 (95% confidence interval [CI], 0.681 to 1.002;P=0.052, adjusted for the interim analyses), corresponding toa difference of 2.6 percentage points or a reduction in therisk of death of 17.5%. The mortality rate for salmeterol aloneor fluticasone propionate alone did not differ significantlyfrom that for placebo. As compared with placebo, the combinationregimen reduced the annual rate of exacerbations from 1.13 to0.85 and improved health status and spirometric values (P<0.001for all comparisons with placebo). There was no difference inthe incidence of ocular or bone side effects. The probabilityof having pneumonia reported as an adverse event was higheramong patients receiving medications containing fluticasonepropionate (19.6% in the combination-therapy group and 18.3%in the fluticasone group) than in the placebo group (12.3%,P<0.001 for comparisons between these treatments and placebo).
Conclusions The reduction in death from all causes among patientswith COPD in the combination-therapy group did not reach thepredetermined level of statistical significance. There weresignificant benefits in all other outcomes among these patients.(ClinicalTrials.gov number, NCT00268216
[ClinicalTrials.gov]
.)
Chronic obstructive pulmonary disease (COPD) is a major causeof illness, death, and the use of health care resources globally.1,2,3The disease causes approximately 2.75 million deaths annually,and the number is projected to increase.2 Treatment for COPDis focused on minimizing risk factors, improving symptoms, andpreventing exacerbations.3 With the exception of smoking-cessationprograms for patients with early disease,4 home oxygen treatmentfor persistent hypoxemia,5,6 and lung-reduction surgery forselected patients with emphysema,7 no treatment has been shownto reduce mortality.
Pulmonary inflammation is prominent in COPD.8 Antiinflammatorydrugs such as inhaled corticosteroids have little or no effecton the rate of decline of lung function9,10 but may reduce thefrequency of exacerbations,9 especially when combined with aninhaled long-acting beta-agonist.11 Retrospective analyses suggestthat inhaled corticosteroids reduce the mortality rate amongpatients with COPD12 and that adding a long-acting beta-agonistmight increase this effect.13 We hypothesized that the combinationof the long-acting beta-agonist salmeterol and the inhaled corticosteroidfluticasone propionate would reduce mortality among patientswith COPD, as compared with usual care. To test this hypothesis,we undertook the Towards a Revolution in COPD Health (TORCH)trial, a double-blind, placebo-controlled, randomized, parallel-groupstudy comparing salmeterol plus fluticasone propionate (thecombination regimen) with each of the components alone and withplacebo over a 3-year period.
Methods
Details of the study design and the analysis plan were publishedpreviously.14 The complete study protocol is in Supplementary Appendix 1,available with the full text of this article at www.nejm.org.
Patients
We recruited patients who were current or former smokers withat least a 10-pack-year history. Eligible patients were 40 to80 years of age and had received a diagnosis of COPD, with aprebronchodilator forced expiratory volume in 1 second (FEV1)of less than 60% of the predicted value,15 an increase of FEV1with the use of 400 µg of albuterol of less than 10% ofthe predicted value for that patient, and a ratio of prebronchodilatorFEV1 to forced vital capacity (FVC) equal to or less than 0.70.For the exclusion criteria, see Table 1 in Supplementary Appendix 2.All patients gave written informed consent. The study was approvedby local ethics review committees and was conducted in accordancewith the Declaration of Helsinki and Good Clinical Practiceguidelines.
Study Design
This double-blind study was conducted at 444 centers in 42 countries;center and data auditing ensured the integrity of the data (seethe study protocol in Supplementary Appendix 1). After a 2-weekrun-in period, eligible patients were randomly assigned, inpermuted blocks with stratification according to country andsmoking status, to treatment with the combination of salmeterolat a dose of 50 µg and fluticasone propionate at a doseof 500 µg (Advair Diskus, Seretide, GlaxoSmithKline) orsalmeterol (Serevent, GlaxoSmithKline) alone at a dose of 50µg, fluticasone propionate (Flovent Diskus, Flixotide,GlaxoSmithKline) alone at a dose of 500 µg, or placebo,all taken in the morning and the evening for 3 years. Studymedications were administered as a dry powder with the use ofan inhaler (Diskus, Accuhaler, GlaxoSmithKline). Inhalers werecollected every 12 weeks, and the number of doses remainingin each inhaler was recorded to check adherence to the studyregimen. Before the run-in period, all use of corticosteroidsand inhaled long-acting bronchodilators was stopped, but patientscould continue other medications for COPD.
After randomization, patients were seen every 12 weeks to confirmvital status, record any unscheduled visits to a health careprovider, and note the occurrence of any adverse events. Postbronchodilatorspirometry was performed and health status was assessed every24 weeks. An independent safety and efficacy data monitoringcommittee performed safety reviews every 6 months, and two interimefficacy analyses were performed, the first after the first358 deaths had occurred and the second after a total of 680deaths had occurred.
Outcome Measurements
Vital status was assessed until 3 years after treatment hadbegun, regardless of whether the patients continued to takestudy medication. The primary end point was the time to deathfrom any cause by 3 years. An independent clinical end pointcommittee, whose members were unaware of the treatment assignments,determined the primary cause of death and whether death wasrelated to COPD. The committee used information obtained frominvestigators, medical records, and other data, as available.
Secondary end points were the frequency of exacerbations, definedas a symptomatic deterioration requiring treatment with antibioticagents, systemic corticosteroids, hospitalization, or a combinationof these, and health status, as assessed according to scoreson the St. George's Respiratory Questionnaire.16 Scores arebased on a scale of 0 to 100, with lower scores indicating betterfunctioning; a change of 4 units is generally considered clinicallyrelevant. The questionnaire was administered in the 28 countrieswhere a validated translation was available. Lung function wasassessed with the use of postbronchodilator spirometry. Forpatients who withdrew from the study prematurely, all data onexacerbations, health status, and lung function available atthe time of a patient's withdrawal from the study were includedin the analysis.
Safety Evaluation
Adverse events and medications were reviewed at each study visit.Additional information was collected about any fractures, classifiedas either traumatic or nontraumatic, with nontraumatic fracturesconsidered to be caused by falls from less than standing heightor falls occurring spontaneously. Dual-energy x-ray absorptiometryat the hip and lumbar spine and slit-lamp examinations wereperformed on patients' entry into the study and annually thereafterin a safety substudy conducted in the United States and involving658 patients.
Statistical Analysis
All reported data analyses were prespecified. Assuming a 17%mortality rate in the placebo group at 3 years,17 we estimatedthat 1510 patients would be needed for each study group to detecta reduction in mortality of 4.3 percentage points in the combination-therapygroup, as compared with the placebo group (hazard ratio fordeath, 0.728), at a two-sided alpha level of 0.05 with 90% power.Two interim analyses of death from any cause were planned toassess whether there was overwhelming evidence of a benefitfrom the combination regimen, as compared with placebo, or ofharm in any study group; these analyses were performed by theindependent safety and efficacy data monitoring committee accordingto the method of Whitehead.18 As a consequence, the P valuefor the primary comparison between the combination regimen andplacebo was adjusted upward to conserve an overall significancelevel of 0.050.
The difference in times to death from any cause between thecombination-therapy group and the placebo group was analyzedwith the use of the log-rank test (with stratification accordingto smoking status) and expressed as a hazard ratio. We useda Cox proportional-hazards model as a supportive secondary analysis.
The frequency of exacerbations was analyzed with the use ofa generalized linear model (assuming a negative binomial distribution,which accounts for variability among patients in the numberand frequency of exacerbations), with the number of exacerbationsas the outcome and the logarithm of time during which treatmentwas received as an offset variable. Total scores on the St.George's Respiratory Questionnaire and postbronchodilator FEV1were analyzed as changes from baseline values with the use ofrepeated-measures analysis of covariance (ANCOVA). Estimateddifferences between treatments at each visit were averaged withequal weights to determine the overall treatment effect duringthe 3-year study period. All efficacy analyses were performedaccording to the intention-to-treat principle. Comparisons otherthan those between the combination regimen and placebo and betweenthe combination regimen and salmeterol alone were exploratory.
Times to the first fracture, eye disorder, and pneumonia werecompared among the study groups in the safety population withthe use of Kaplan–Meier estimates and the log-rank test,with stratification according to smoking status. In the safetysubstudy, bone mineral density for the total hip and lumbarspine was analyzed by repeated measures of ANCOVA, and the developmentof cataracts was analyzed with the use of logistic regression.(For details of the statistical analysis, see Supplementary Appendixes 1 and 2.)
The steering committee, made up of six academic investigatorsand two employees of the sponsor, developed the design and conceptof the study, approved the statistical plan, had full accessto and interpreted the data, wrote the manuscript, and was responsiblefor the decision to publish the manuscript. An academic authorwrote a draft of the manuscript; an employee of the sponsorperformed the statistical analysis. The academic authors vouchfor the veracity and completeness of the data and the data analysis.The sponsor did not place any restrictions on the academic authorsregarding statements made in the final manuscript.
Results
Study Population
Of 8554 patients recruited, 6184 underwent randomization (Figure 1).Of these, 72 patients at five sites were excluded from the efficacyanalysis because these sites failed to meet the standards ofthe study for Good Clinical Practice and ethical practices andwere closed before the study ended (see Supplementary Appendix 2).These 72 patients were included in the safety analysis, anda total of 6112 patients were included in the efficacy population.
Figure 1. Enrollment of Patients and Completion of the Study.
Adverse events included death during the study period but may not have included deaths occurring after patients withdrew from the study. The number of patients who underwent randomization and the number of those included in the safety population differ in the placebo group and the fluticasone group, because one patient who was assigned to placebo received fluticasone propionate for more than half the study period; this patient was therefore included in the safety population of the fluticasone group and in the efficacy population of the placebo group. In each study group, patients were excluded from the efficacy analysis because during routine site visits and data audits, data from centers at which there were unacceptable research practices were excluded (see Supplementary Appendix 2). Vital status for patients included in the efficacy analysis was established at the end of the study, except for one patient in the combination-therapy group whose data were censored at the last point at which he was known to be alive (day 792).
Demographic and baseline clinical characteristics of the efficacypopulation are shown in Table 1. The mean age was 65 years,and the mean value of postbronchodilator FEV1 was 44% of thepredicted value. During the year before entry into the study,more than half the patients had used inhaled corticosteroids,a long-acting beta-agonist, or both, and 57% of the patientshad reported an exacerbation. The proportion of patients whowithdrew from the study was significantly higher in the placebogroup (44%) than in the three other groups, and the proportionwas lowest in the combination-therapy group (34%) (Figure 2A).The total number of years of exposure to the study drugs was3678 in the combination-therapy group, 3238 in the placebo group,3499 in the salmeterol group, and 3532 in the fluticasone group.The rate of adherence to treatment was similar in all groups,ranging from 88% to 89% of the prescribed doses taken.
In the combination regimen, salmeterol was administered at a dose of 50 µg and fluticasone propionate at a dose of 500 µg twice daily. Salmeterol alone was administered at a dose of 50 µg twice daily, and fluticasone propionate alone was administered at a dose of 500 µg twice daily. Cumulative incidences of discontinuation of a study drug at 3 years were 43.5% in the placebo group, 36.4% in the salmeterol group, 38.1% in the fluticasone group, and 33.7% in the group receiving the combination of salmeterol plus fluticasone propionate (Panel A). Intergroup comparisons yielded the following hazard ratios for the discontinuation of a study medication: 0.69 (95% CI, 0.62 to 0.78, P<0.001) for the combination-therapy group versus the placebo group; 0.89 (95% CI, 0.79 to 0.999; P<0.05) for the combination-therapy group versus the salmeterol group; 0.86 (95% CI, 0.76 to 0.96; P=0.010) for the combination-therapy group versus the fluticasone group; 0.78 (95% CI, 0.70 to 0.86; P<0.001) for the salmeterol group versus the placebo group; and 0.81 (95% CI, 0.72 to 0.90; P<0.001) for the fluticasone group versus the placebo group. Patients discontinuing a study medication were included in the mortality analysis at 3 years but could receive any treatment. In the analysis for the primary end point of the probability of death from any cause at 3 years, the risk of death in the placebo group was 15.2%, as compared with 12.6% in the combination-therapy group. Salmeterol and fluticasone propionate in combination reduced the risk of death at any time during the 3-year study period by 17.5% (P=0.052) (Panel B). The probability of COPD-related death at 3 years was 6.0% in the placebo group, 6.1% in the salmeterol group, 6.9% in the fluticasone group, and 4.7% in the combination-therapy group (Panel C). The effect of each study medication on health status (assessed according to changes in patients' total scores on the St. George's Respiratory Questionnaire) and FEV1 during the 3-year study period are shown in Panels D and E, respectively. Values in the tables below the graphs represent the numbers of patients alive (Panel B), the numbers of of patients alive or dead from non–COPD-related causes (Panel C), or the number of patients remaining in the study (Panels A, D, and E). I bars represent standard errors (at approximately 1, 2, and 3 years in Panels A, B, and C). HR denotes hazard ratio.
Mortality
Vital status was known at 3 years for 6111 of the 6112 patientsincluded in the efficacy population. There were 875 deaths within3 years after randomization. The proportions of deaths fromany cause at 3 years were 12.6% in the combination-therapy group,15.2% in the placebo group, 13.5% in the salmeterol group, and16.0% in the fluticasone group. The absolute risk reductionfor death in the combination-therapy group as compared withthe placebo group was 2.6%, and the hazard ratio was 0.825 (95%confidence interval [CI], 0.681 to 1.002; P=0.052), correspondingto a reduction in the risk of death at any time in the 3 yearsof 17.5% (95% CI, –0.2 to 31.9) (all adjusted for theinterim analyses) (Figure 2B and Table 2).
Table 2. Results of the Mortality Analysis and the Efficacy Analysis for Exacerbation.
Prespecified secondary analyses for mortality were also performed:Cox proportional-hazards testing yielded a hazard ratio of 0.811(95% CI, 0.670 to 0.982; P=0.03) (Table 2); log-rank testing,stratified according to smoking status and country of residence,yielded a hazard ratio of 0.815 (95% CI, 0.673 to 0.987; P=0.04)(see Table 2 in Supplementary Appendix 2). There was no interactionbetween treatment and age, sex, region of country, baselineFEV1 categorized by disease stage according to the Global Initiativefor Chronic Obstructive Lung Disease, body-mass index, or smokingstatus. Adjusting for exposure to smoking (pack-years) did notaffect the results.
The risk of death in the salmeterol group and in the fluticasonegroup did not differ significantly from that in the placebogroup (Table 2). The risk was similar among patients who diedwhile receiving a study medication (data not shown) and thosewho died from COPD-related causes (Figure 2C). The risk of deathin the combination-therapy group did not differ significantlyfrom that in the salmeterol group, but patients receiving thecombination regimen were less likely to die than those receivingfluticasone propionate (hazard ratio for death, 0.774 [95% CI,0.641 to 0.934]; P=0.007). Overall, 27% of the deaths were adjudicatedas due to cardiovascular causes, 35% to pulmonary causes, and21% to cancer (for other causes of death, see Table 3 in Supplementary Appendix 2).
Exacerbations, Health Status, and Lung Function
According to our statistical models, the annual rate of exacerbationswas 0.85 (95% CI, 0.80 to 0.90) in the combination-therapy groupand 1.13 (95% CI, 1.07 to 1.20) in the placebo group, resultingin a rate ratio for exacerbations of 0.75 (95% CI, 0.69 to 0.81;P<0.001), which is a reduction of 25% and corresponds toa number needed to treat of four to prevent one exacerbationin 1 year. Annual rates of exacerbations in the salmeterol groupand the fluticasone group were significantly lower than in theplacebo group (Table 2). Overall, 26% of the patients were hospitalizedat least once during the 3-year study period. Annual admissionrates were 17% lower in the combination-therapy and salmeterolgroups than in the placebo group (P0.03) (Table 2), correspondingto a number needed to treat of 32 to prevent one hospitalizationin 1 year.
Total scores on the St. George's Respiratory Questionnaire initiallyimproved from baseline in all groups, with the greatest changesoccurring in the combination-therapy group (mean score at baseline,48.7, with a mean reduction of 3.0 units averaged over 3 years),as compared with the placebo group (a mean score of 48.4 atbaseline, with an increase of 0.2 unit in the placebo group)(Figure 2D and Table 3). Similarly, for lung function, the meanbaseline FEV1 in the combination-therapy group was 1.236 literswith an average increase of 0.029 liter, whereas in the placebogroup, the mean baseline FEV1 was 1.257 liters and a decreaseof 0.062 liter. Averaged over 3 years, the health status (areduction of 3.1 units in the score for the St. George's RespiratoryQuestionnaire) and spirometric measurements (an increase inFEV1 of 0.092 liter) in the combination-therapy group were significantlybetter than in the groups receiving placebo, salmeterol alone,or fluticasone propionate alone (Figure 2E and Table 3).
Adverse events were reported by 90% of the patients in the study,and serious adverse events were reported by 41% of the patients(Table 4). (For mortality data for the safety population, seeFig. 1 and Table 4 in Supplementary Appendix 2.) The most frequentlyreported adverse event was an exacerbation of COPD. The probabilityof having pneumonia reported as an adverse event during the3-year study period was significantly greater among patientsreceiving a study medication containing fluticasone propionate:the probability was 19.6% in the combination-therapy group,12.3% in the placebo group, 13.3% in the salmeterol group, and18.3% in the fluticasone group (P<0.001 for the comparisonbetween both the combination-therapy and fluticasone groupsand the placebo group). Among patients receiving study medications,there were 8 deaths from pneumonia in the combination-therapygroup, 7 in the placebo group, 9 in the salmeterol group, and13 in the fluticasone group. There was no significant differencein the probability of fractures among the groups (6.3% in thecombination-therapy group, 5.1% in the placebo group, 5.1% inthe salmeterol group, and 5.4% in the fluticasone group). Therewas no excess of cardiac disorders among patients treated withthe combination regimen or salmeterol alone (reported eventrates per study year, 0.087 in the combination-therapy group,0.113 in the placebo group, 0.114 in the salmeterol group, and0.102 in the fluticasone group). In the safety substudy, therewere no significant differences in bone mineral density or inthe numbers of patients in whom cataracts developed betweenthe groups receiving active study drugs and the placebo group(Table 4).
Table 4. Adverse Events among 6184 Patients in the Safety Population and 658 Patients in the Substudy of Bone Mineral Density.
Discussion
In this trial, the reduction in mortality from any cause inthe combination-therapy group, as compared with the placebogroup, did not meet the predetermined level of statistical significance.During the 3 years of the study, treatment with the combinationregimen resulted in significantly fewer exacerbations and improvedhealth status and lung function, as compared with placebo.
There are two possible reasons why the reduction in mortalityin the combination-therapy group, as compared with the placebogroup, did not achieve statistical significance. The first isthat there is no effect of salmeterol plus fluticasone propionateon survival. In this scenario, the data would suggest that theobserved symptomatic and functional improvement derives frommechanisms other than those that prolong life. It could be thatmortality is influenced mainly by factors that are currentlyunidentified and unresponsive to therapy with salmeterol plusfluticasone propionate.
The second possible reason, which we believe is the more likelyone, is that salmeterol plus fluticasone propionate does havean effect on mortality but that our study was underpowered todetect this effect. Our power calculations were based on theInhaled Steroids in Obstructive Lung Disease in Europe (ISOLDE)study, and there were fewer deaths in the placebo group thananticipated.14,17 The TORCH study was designed to have 90% powerto detect an effect of 4.3 percentage points on overall mortality;in practice, we identified a reduction of 2.6 percentage points.In addition, there was a high withdrawal rate, which was highestamong patients in the placebo group, who were free to receiveactive therapy subsequently. Furthermore, performing the secondinterim analysis so close to the final analysis increased thethreshold required for significance. More studies are neededto determine whether either of these explanations or anotherexplanation accounts for the primary finding.
Our data on the secondary outcomes are consistent with and extendprevious observations in studies using combinations of inhaledcorticosteroids and long-acting beta-agonists19,20,21 in showingthat the combination regimen reduced exacerbations significantly,as compared with placebo, including those exacerbations requiringhospitalization. The combination regimen was also significantlybetter than each of its components alone in preventing exacerbations,and these benefits were accompanied by sustained improvementsin health status and FEV1; the values for both were better atthe end of the trial than at baseline. Unlike previous studiesin which reductions in exacerbations and improvements in healthstatus have also been reported,19,21 in our study there wasno requirement of exacerbations during the year before entryinto the trial. Furthermore, the greater number of patientswithdrawing from the placebo group is likely to have resultedin an underestimation of the effect of the combination regimenon all the secondary outcomes. Nevertheless, the number neededto treat to prevent an exacerbation in 1 year was 4, and thenumber needed to treat to prevent a hospitalization was 32.
An important safety finding, identified because the size ofthe study was sufficient to detect infrequent events, was theexcess of patients who received a diagnosis of pneumonia amongthose receiving study medications containing fluticasone propionate.This finding had not been previously reported in studies involvingthe use of inhaled corticosteroids by patients with COPD. Sincethe finding was unexpected, there was no prospective definitionof pneumonia in the study protocol (e.g., confirmation on chestradiography). However, this finding was observed in the differentsubgroups, which suggests that it may be an important signalwhose mechanism is currently unclear and requires further study.The increase in pneumonia did not appear to represent an increasein the number of deaths. As determined by the independent clinicalend-point committee, among deaths attributed to pneumonia inpatients in the safety population while they were receivinga study medication, there was one more death in the combination-therapygroup and six more in the fluticasone group than in the placebogroup.
The increase in oropharyngeal side effects among patients receivingfluticasone propionate or the combination regimen was expected,but there was no evidence of excess cardiac events among thosereceiving salmeterol alone or the combination regimen. The totalnumber of fractures, including those associated with minimaltrauma or none, did not differ significantly among the fourgroups. This finding was in keeping with the absence of a significantdifference among the groups in bone mineral density among patientsin the U.S. substudy. The prevalence of cataracts at baselinein all the study groups was high, but it was not influencedby treatment during the course of the study. However, exposureto the study medications for 3 years may not be long enoughto detect differences in the occurrence of fractures and eyedisorders.
The TORCH study recruited patients with COPD from around theworld, and we think that our findings can therefore be generalized.The particular strengths of the study are the virtually completesurvival data to 3 years and the independent adjudication ofcauses of death, which eliminated between-country variationin death certification. Although the TORCH study is a largeCOPD trial, as compared with studies of mortality associatedwith other major chronic illnesses such as cardiovascular disease,22,23,24its size is modest. The results of our mortality analysis shouldbe viewed in this context. The potential for a reduction inthe risk of death of 2.6 percentage points among patients treatedwith salmeterol plus fluticasone propionate, as compared withplacebo, and the 17.5% reduction in the risk of death that wasidentified in the study clearly merit further investigationin future large, prospective trials. Until such trials are completed,our data support the use of salmeterol plus fluticasone propionatein the clinical management of COPD.
Supported by GlaxoSmithKline.
Dr. Calverley reports receiving consulting fees from AstraZeneca,GlaxoSmithKline, Pfizer, and Hoffmann–La Roche, speakingfees from Altana, Chiesi, GlaxoSmithKline, and Pfizer, and grantsupport from Altana and GlaxoSmithKline; Dr. Celli, consultingfees and speaking fees from Altana, AstraZeneca, BoehringerIngelheim, and GlaxoSmithKline, and grant support from BoehringerIngelheim and GlaxoSmithKline; Dr. Ferguson, consulting feesor speaking fees from Boehringer Ingelheim, GlaxoSmithKline,Novartis, and Schering-Plough, and grant support from Altana,Boehringer Ingelheim, Emphasys Medical, Mannkind, and Oscient;Dr. Jenkins, consulting fees and speaking fees from Altana Pharma,AstraZeneca, Boehringer Ingelheim, and GlaxoSmithKline and grantsupport from GlaxoSmithKline; Dr. Jones, consulting fees fromAstraZeneca, GlaxoSmithKline, Novartis, and Hoffmann–LaRoche, speaking fees from AstraZeneca and GlaxoSmithKline, andgrant support from Boehringer Ingelheim and GlaxoSmithKline;and Dr. Vestbo, consulting fees from AstraZeneca, BoehringerIngelheim, GlaxoSmithKline, and Hoffmann–La Roche, speakingfees from AstraZeneca, Boehringer Ingelheim and GlaxoSmithKline,and grant support from GlaxoSmithKline. Ms. Anderson and Ms.Yates are employees of and hold stock in GlaxoSmithKline. Noother potential conflict of interest relevant to this articlewas reported.
This study is dedicated to the memory of Professor Romain Pauwels,who played a major role in planning the TORCH investigationand led the investigators until his untimely death.
We thank Professor Neil Pride for important and material contributionsto the design and direction of the study, the GlaxoSmithKlineTORCH team, and David Cutler (Gardiner-Caldwell Communications),for technical support in the preparation of the manuscript.
* Committee members of the Towards a Revolution in COPD Health(TORCH) trial are listed in the Appendix.
Source Information
From University Hospital Aintree, Liverpool, United Kingdom (P.M.A.C.); GlaxoSmithKline Research and Development, Greenford, United Kingdom (J.A.A.); Caritas St. Elizabeth's Medical Center, Boston (B.C.); Pulmonary Research Institute of Southeast Michigan, Livonia (G.T.F.); Woolcock Institute of Medical Research, Sydney (C.J.); St. George's University of London, London (P.W.J.); GlaxoSmithKline Research and Development, Research Triangle Park, NC (J.C.Y.); and Wythenshawe Hospital, Manchester, United Kingdom, and Hvidovre Hospital, Hvidovre, Denmark (J.V.).
Address reprint requests to Dr. Calverley at the Department of Medicine, Clinical Science Centre, University Hospital Aintree, Longmoor Lane, Liverpool L9 7AL, United Kingdom, or at pmacal{at}liverpool.ac.uk.
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Appendix
For a complete list of investigators of the Towards a Revolutionin COPD Health (TORCH) study, see Supplementary Appendix 2.Committee members were as follows: Steering Committee: P.M.A.Calverley (chair), Liverpool, United Kingdom; J.A. Anderson,Greenford, United Kingdom; B. Celli, Boston; G.T. Ferguson,Livonia, MI; C. Jenkins, Sydney; P.W. Jones, London; K. Knobil,J.C. Yates, Research Triangle Park, NC; J. Vestbo, Manchester,United Kingdom. Safety and Efficacy Data Monitoring Committee:R. Cherniack, Denver; T. Similowski, Paris; J. Cleland, Hull,United Kingdom; A. Whitehead, Reading, United Kingdom. ClinicalEnd Point Committee: R. Wise, Baltimore; L. McGarvey, Belfast,Northern Ireland; M. John, Berlin.
Prevention of Death in COPD
Barnes P. J., La Vecchia C., Fabbri L. M., Duerden M., Kupfer Y., Tessler S., Keaney N., Calverley P., Anderson J., Celli B.
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N Engl J Med 2007;
356:2211-2214, May 24, 2007.
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0.03) (Table 2), corresponding to a number needed to treat of 32 to prevent one hospitalization in 1 year. 
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