BioCAST/IFCT-1002: epidemiological and molecular features of lung cancer in never-smokers
- Sébastien Couraud1,2,3,4⇑,
- Pierre-Jean Souquet1,2,
- Christophe Paris5,
- Pascal Dô6,
- Hélène Doubre7,
- Eric Pichon8,9,
- Adrien Dixmier10,
- Isabelle Monnet11,
- Bénédicte Etienne-Mastroianni12,13,
- Michel Vincent14,
- Jean Trédaniel15,
- Marielle Perrichon16,
- Pascal Foucher17,
- Bruno Coudert18,
- Denis Moro-Sibilot19,20,
- Eric Dansin21,
- Stéphanie Labonne1,2,
- Pascale Missy22,
- Franck Morin22,
- Hélène Blanché23 and
- Gérard Zalcman24
- on behalf of The French Cooperative Intergroup IFCT25
- 1Dept of Respiratory Medicine, Lyon Sud Hospital, Hospices Civils de Lyon, Lyon, France
- 2Faculty of Medicine Lyon-Sud Charles Mérieux, Lyon 1 University, Lyon, France
- 3Centre for Clinical Epidemiology, Lady Davis Institute for Medical Research, Jewish General Hospital, Montreal, Quebec, Canada
- 4Dept of Epidemiology, Biostatistics and Occupational Health, McGill University, Montreal, Quebec, Canada
- 5(CP) INGRES, EA7298, Lorraine University, Vandoeuvre Les Nancy, France
- 6Francois Baclesse Cancer Institute, Caen, France
- 7Pulmonology Unit, Foch General Hospital, Paris, France
- 8Pulmonology Unit, University Hospital of Tours, Tours, France
- 9François Rabelais University, Respiratory Diseases Study Centre, U1100/EA6305, Tours, France
- 10Pulmonology Unit, Orleans Regional Hospital, Orléans, France
- 11Pulmonology Unit, Centre Hospitalier Intercommunal de Créteil, Créteil, France
- 12Dept of Respiratory Medicine, Hôpital Louis Pradel, Hospices Civils de Lyon, Lyon, France
- 13Claude Bernard University Lyon 1, Lyon, France
- 14Pulmonology Dept, Saint Joseph-Saint Luc Hospital, Lyon, France
- 15Pulmonology Dept, Paris - Saint Joseph Hospital, and Sorbonne Paris Cité University, Paris, France
- 16Pulmonology Dept, Bourg-en-Bresse General Hospital, Bourg en Bresse, France
- 17Thoracic Oncology, Dijon University Hospital, Dijon, France
- 18Oncology Dept, Georges François Leclerc Cancer Centre, Dijon, France
- 19Pulmonology and Thoracic Oncology Dept, Grenoble University Hospital, Grenoble, France
- 20Medicine Faculty, Joseph Fourrier University, La Tronche, France
- 21Oncology Dept, Oscar Lambret Cancer Centre, Lille, France
- 22Intergroupe Francophone de Cancérologie Thoracique, Paris, France
- 23Fondation Jean Dausset - CEPH, Paris, France
- 24Pulmonology and Thoracic Oncology Dept, Caen University Hospital, and UMR INSERM 1086, Caen Basse-Normandie University, Caen, France
- 25For collaborators of the BioCAST/IFCT-1002 study, please see the acknowledgements section
- Sébastien Couraud, Service de Pneumologie, Hospices Civils de Lyon, CH Lyon Sud, 165 Chemin du Grand Revoyet, F-69495 Pierre Bénite, France. E-mail: sebastien.couraud{at}chu-lyon.fr
Abstract
Lung cancer in never-smokers (LCINS) (fewer than 100 cigarettes in lifetime) is considered as a distinct entity and harbours an original molecular profile. However, the epidemiological and molecular features of LCINS in Europe remain poorly understood.
All consecutive newly diagnosed LCINS patients were included in this prospective observational study by 75 participating centres during a 14-month period. Each patient completed a detailed questionnaire about risk factor exposure. Biomarker and pathological analyses were also collected. We report the main descriptive overall results with a focus on sex differences.
384 patients were included: 65 men and 319 women. 66% had been exposed to passive smoking (significantly higher among women). Definite exposure to main occupational carcinogens was significantly higher in men (35% versus 8% in women). A targetable molecular alteration was found in 73% of patients (without any significant sex difference): EGFR in 51%, ALK in 8%, KRAS in 6%, HER2 in 3%, BRAF in 3%, PI3KCA in less than 1%, and multiple in 2%.
We present the largest and most comprehensive LCINS analysis in a European population. Physicians should track occupational exposure in men (35%), and a somatic molecular alteration in both sexes (73%).
Abstract
Occupational exposure and targetable mutation should be tracked in lung cancer of European never-smokers. http://ow.ly/FB2WS
Introduction
Although tobacco smoking is the strongest causal factor for lung cancer, 10–25% of lung cancer worldwide occurs in lifelong nonsmokers (300 000 deaths each year) [1–3]. A “never-smoker” is well-defined as an individual who has smoked fewer than 100 cigarettes during their lifetime. Lung cancer occurring in never-smokers (LCINS) is now considered a distinct entity. However, this disease appears strongly linked to geographical origins. For example, LCINS is drastically more common in Asia than in the USA or Europe [2]. This could be related to distinct features pertaining to inherited susceptibility, as well as to varied exposure to occupational and environmental carcinogens in different geographical areas. Thus, it is possible that LCINS is, in fact, globally a very heterogeneous disease [1, 2]. Although the disease is thought to be well characterised, very little data on LCINS are available in Europe [4], and nobody has concomitantly assessed most of the known risk factors for lung cancer.
LCINS is also known to hold an original spectrum of driver mutations. Thus, human epidermal growth factor receptor family (EGFR (also called HER1) and HER2 (human epidermal growth factor receptor 2)) mutations appear more frequent, while KRAS (Kirsten rat sarcoma viral oncogene homologue) and BRAF (v-Raf murine sarcoma viral oncogene homologue B), thought to be related to tobacco carcinogens, are less common in this group [5–7]. Finally, ALK (anaplastic lymphoma kinase) rearrangements also occur slightly more frequently in never-smoking patients [8]. This spectrum is another argument favouring the hypothesis that separate genetic pathways lead to lung carcinogenesis in ever- and never-smokers [1].
Given that the clinical and molecular epidemiology of LCINS in Europe is still poorly understood, the French Collaborative Intergroup for Thoracic Cancer Research (IFCT) sought to investigate this specific entity through a prospective cohort of LCINS. The BioCAST (IFCT-1002) study's main objective was to describe a French population of LCINS patients and especially the distribution of risk factor exposure and biomarker patterns. Here we report this study's main descriptive results, focusing on potential sex differences among LCINS patients.
Population and methods
Population
Main inclusion criteria were: 1) being a self-declared never-smoker (i.e., declaring having smoked fewer than 100 cigarettes during lifetime); 2) being newly diagnosed with a non-small cell lung cancer (NSCLC) by biopsy or by cytological sampling; 3) being aged at least 18 years; 4) speaking and understanding French (or having access to a relative able to translate); 5) having phone access, either at home or at the hospital; and 6) granting signed consent.
The IFCT sponsored the BioCAST study. The study was conducted in 75 participating centres throughout metropolitan France, from November 1, 2011 to January 31, 2013. Participating centres were asked to include all consecutive newly diagnosed LCINS cases. IFCT research staff members were in charge of administrative management and quality assurance (in compliance with international research standards) [9].
Ethics
The Sud-Est IV Lyon ethics committee approved the study protocol on September 13, 2011. The Advisory Committee on Information Processing for Health Research permitted use of a computerised database on September 8, 2011, and the National Commission for Data Protection was contacted on September 23, 2011, in accordance with French law. Blood sample collection was declared to the French Ministry of Research on July 1, 2011. The BioCAST study was registered on the US National Institute of Health website www.clinicaltrials.gov under the CTC ID NCT01465854.
Study design
Patients signed their consent after receiving information about the study from their physicians. Afterward, and before any anti-cancer treatment, each patient's blood was sampled. Patients were then contacted by phone in order to schedule a dedicated phone interview and complete a standardised questionnaire. All patients had the opportunity to fully prepare this questionnaire before the pre-planned interview. Patients were also encouraged to seek assistance from a relative if needed (in cases of fatigue, deafness, memory deficiency or poor spoken French). Two trained research assistants performed all the interviews in order to control for reporting and interrogation biases. Additional medical data, as well as molecular testing and pathological reports were collected directly from participating physicians.
Patients' questionnaire
A 17-page questionnaire was delivered to patients upon inclusion. It included questions about demographics, socio-educative level and alternative tobacco consumption, as well as cannabis smoking, passive smoking exposure, occupational exposure, personal medical history, family history, alcohol intake and fried and stir-fried cooking exposure. Occupational exposures to bronchial carcinogens were assessed using a lifelong task-based questionnaire, the efficacy of which for detecting occupational exposure was recently published [10]. All patients were questioned about their home addresses and exposure to solid fuel for cooking or heating. Finally, women declared oral contraceptive and post-menopausal hormone replacement therapy intake, as well as other details on reproductive factors. Additional detailed information on recorded data and exposure measurements are provided in supplemental file S1.
Biomarker analyses
The French National Cancer Institute (INCa) launched a network of 28 molecular genetics platforms that provide routine cancer molecular testing for all patients [11]. Each BioCAST participant centre was asked to systematically order tests for somatic mutations in EGFR and KRAS, as well as ALK fusion gene, to its local molecular genetics laboratory. Investigator sites were also encouraged to request BRAF, HER2, and PI3KCA mutation analyses, which are also routinely performed (free of charge to the patient) at these platforms. All centres were advised to follow local policy, and were therefore allowed to forego further mutation testing if one mutation reputed to exclude the others was found. Final and detailed reports of these analyses were collected for each patient.
Actually, biomarker testing methods are not homogeneous throughout all centres. However, the ERMETIC study was designed to assess concordance of results between each centres (blinded cross validation study compared to an international reference lab) and between the different methods used in such centres (direct sequencing, PCR-based, Restriction fragment-length polymorphism, and high-resolution melting). This validation study showed good concordance rate suggesting that, despite some difference in sample processing and analyses, results are accurate [12, 13].
Blood samples bio-bank
Four tubes of each patient's blood were collected for further studies (two stored in EDTA, one dry and one ACD-citrated). Samples were transported to the BioCAST central laboratory (hosted at the Centre d’Étude du Polymorphisme Humain, Fondation Jean Dausset, Paris, France) at room temperature within 24 h of sampling and were then processed.
Statistics
Categorical variables were expressed as percentages. Comparisons of proportions used the Chi-squared test when the expected count in a given category was at least five, or Fisher's exact test otherwise. We used the one-sample Kolmogorov–Smirnov test in order to assess the plausibility of a normal distribution assumption for continuous variables. Normally distributed continuous variables were expressed as mean and standard deviation. Comparisons of means were conducted using the bilateral t-test. Differences in distribution of continuous variables between two independent samples were assessed using the Mann–Whitney U-test, and the Kruskal–Wallis one-way ANOVA was used to compare more than two independent samples. Some continuous variables were also categorised in quartiles, tertiles or clinically relevant categories according to their distribution in the overall population. Missing values were reported as such, and all tests were two-sided. All statistics were calculated using the SPSSv20 (IBM SPSS Statistics, New York, NY, USA).
Results
Population
Altogether, 384 consecutive French never-smokers were included during the study period. Of these, 336 (87.5%) completed the interview, 359 (93%) had at least one biomarker testing, and 381 (99.2%) underwent the correct blood sampling procedure (fig. 1).
Main demographic data
Table 1 gives the overall population's main features and a sex comparison. The sex ratio was 4.9 in favour of women. There was no patient-reported alternative smoking (water-pipe, cigar, pipe or gum) or cannabis use. 91% of patients originated from Europe: 276 from Western Europe, 22 from Southern Europe and six from Eastern Europe. Men were, on average, 4 years younger than women (p=0.016), and the proportion of patients aged <55 years old at diagnosis was significantly higher among males. In addition, men were better educated, more pre-obese and exhibited higher alcohol consumption than women.
Histology and stage of the disease
The main pathological lung cancer features found in our 384 patients are shown in table S2 in the online supplementary material. We found no significant difference between the sexes. Notably, the frequency of squamous cell carcinoma (SCC) was similar in both sexes (9% in women versus 7% in men; p=0.606). Most cases were adenocarcinoma (85%). The other histological types were SCC (8%), large cell carcinoma (4%), adenosquamous (n=5), sarcomatoid carcinoma (n=4) and carcinoma not otherwise specified (n=2). thyroid transcription factor 1 (TTF-1) immunostaining was positive in 76% of patients. Table S3 in the online supplementary material shows sample type and origin. Most were core biopsies (90%) from primitive tumours (69%) and were classified as stage IV (73%).
Occupational exposure
Data about exposure to occupational carcinogens was available in 334 patients, and results are presented in table 2. Altogether, 13% of patients were found to have been definitely exposed to at least one occupational carcinogen, with a striking difference between the sexes: 35% of men compared with only 8% of women (p<10−4). The most frequent carcinogenic agent was polycyclic aromatic hydrocarbons, followed by asbestos, silica and diesel exhaust. Whatever the agent considered, men were in all cases significantly more exposed than women.
Passive smoke exposure
Overall, 219 (66%) of the 334 patients were ever exposed to passive smoking, either in a domestic setting (59%) or in the workplace (18%) (table 3). Domestic exposure to passive smoking was significantly more common among women than men (64 versus 38%; p=0.0001), but this sex difference was not observed for workplace exposure. Moreover, of those exposed in a domestic setting, women were exposed for a significantly longer period than men. For patients exposed in a domestic setting, exposure began during childhood in 62% of patients. Men were more frequently exposed in childhood than women, suggesting that women were mainly exposed via their spouses.
Domestic pollution
Table S4 in the online supplementary material provides exposure to domestic pollution. Women more frequently reported having ever been exposed to cooking oil fumes (41 versus 18%; p=0.001). 26% of patients reported to have been exposed for >50% of their lifetimes to solid fuel fumes; here there was no significant difference between men and women.
Personal and familial medical history
24% of patients reported having at least two biological first-degree relatives with lung cancer, and 17% reported a personal history of at least one other cancer. Medical histories of pertussis, tuberculosis and pneumonia were reported in 21%, 8% and 6% of patients, respectively. In addition, 13% had been diagnosed with a chronic bronchial disease. There were no differences between the sexes with respect to these variables (Table S5 in the online supplementary material).
Reproductive factors and hormone intake in women are reported in table S6 in the online supplementary material. Overall, 115 (42%) patients had used oral contraceptives, and 70 (25%) had undergone post-menopause hormonal replacement therapy.
Biomarkers (somatic mutations)
EGFR mutations were tested in 340 patients, KRAS in 293, ALK rearrangements in 192, BRAF in 22, HER2 in 201, and PI3KCA in 187. Altogether, we found 220 molecular alterations in 208 patients (table 4). Six patients carried a somatic mutation within two (n=5) or three (n=1) genes simultaneously (multiple mutations), while five others hosted two simultaneous somatic mutations in the EGFR gene (table S7 in the online supplementary material). Alterations in the EGFR gene were the most common: 147 patients displayed 153 mutations, with deletions in exon 19 and substitution L858R in exon 21 being the most frequent (n=74 and 33, respectively). We also found one missense mutation T790M in exon 20 and one alteration never reported before in the Catalogue of Somatic Mutations in Cancer (COSMIC) database (http://cancer.sanger.ac.uk/cancergenome/projects/cosmic) (c.2303_2305delinsTCT in exon 20). In addition, 24 gene fusions involving the ALK gene were observed in 23 patients. We also noted 20 KRAS mutations in 18 patients, 10 BRAF mutations in nine patients, eight HER2 mutations in eight patients, and five PI3KCA mutations in three patients. Overall, an EGFR mutation was found in 43% of individuals, a KRAS mutation in 7%, a BRAF mutation in 5%, a HER2 mutation in 4%, a PIK3CA (phosphatidylinositol-3-kinase, catalytic subunit α) mutation in 2%, and an ALK rearrangement in 13% of patients tested for the corresponding biomarker. We found no significant difference in the mutation frequency as well as in the mutation type according to the gender. For EGFR, women exhibit a higher frequency than men but the difference remains non-significant (39 versus 44% respectively; p=0.438). In addition, we found no difference among sex for the type of mutation found in each biomarker; but however, women tend to exhibit more KRAS transition mutations than men (table 5).
Taking all these data together, 77 (27%) patients were considered “pan-negative” (all biomarkers found were wild type; or at least wild-type EGFR, KRAS and ALK simultaneously). In the remaining 284 patients with complete data, the most common alteration found was an EGFR mutation (in 51% of patients), followed by an ALK rearrangement (8%), a missense mutation in KRAS (6%), HER2 (3%), BRAF (3%) and PIK3CA (<1%). Only 2% carried multiple mutations (see fig. 2). Therefore, 73% of French never-smokers carried a targetable molecular alteration.
Discussion
Among French never-smokers with lung cancer, we found that occupational exposure to carcinogens was significantly higher in men than in women, whereas domestic exposure, both to passive smoking and to cooking-oil, was higher in women. Most of the tumours we studied (73%) carried a targetable mutation.
To our knowledge, our study is the largest and most comprehensive ever conducted that focused on LCINS in a European population. Indeed, most published cohort studies used a retrospective design, were dedicated to Asian populations and/or explored only a single or a small subset of risk factors simultaneously. In Europe, the EPIC (European Prospective Investigation into Cancer and Nutrition) cohort hosted 97 newly diagnosed lung cancer cases [15]. In Asia, a paper from Kim et al. [16], recently reported to be the largest and most comprehensive series on never-smokers, effectively analysed 229 Asian patients, using a retrospective review for EGFR, KRAS and ALK. Kawagushi et al. [17] also keep a prospective registry of never-smoker from Japan, Singapore, Korea as well as few patients in US, but they only reported their results on passive smoking exposure.
Our main findings are consistent with published literature. In fact, Clément-Duchêne et al. [18] have already shown, in 67 French never-smokers, that occupational exposure and passive smoking were differently distributed between the sexes. Indeed, some lung cancers are known to be related to domestic pollution exposure, although modestly, even in Europe [19]. Regarding biomarker distribution, we have shown that French never-smokers carry 73% of targetable mutations. This finding situates French never-smoker between Asian (more than 80%) and American (55%) never-smokers [1, 20, 21].
Our study does carry some limitations. First, due to financial constraints, we had no control patients. Thus, our cohort could not be used in order to estimate any risk ratios. However, our only aim was to assess the prevalence of known lung cancer risk factors and explore their actual distribution among certain subgroups. In order to put our findings into perspective, our data were compared to those of two recently published, nationwide epidemiological studies assessing the main features of French lung cancer smoker patients: 1) the KBP-CPHG (Cancer broncho-pulmonaire du Collège de Pneumologie des Hôpitaux Généraux) 2010 study, which includes 6246 lung cancers in smokers, for demographical, histological and staging data [14] (table 1); 2) the “Biomarker-France” study, sponsored by IFCT and funded by French NCI (INCa), of which preliminary results were reported after inclusion of the first 7789 lung cancers from smokers, for mutation profile data [22] (table 5). Indeed, our data perfectly mirror both the clinical and biological features of ever-smoker lung cancer patients, as reported in those two large series, conducted in the same French background, during the same period of time as BioCAST [14]. However, most of the collected variables had never been assessed in comparable epidemiological studies, or according to smoking status and, thus, are lacking of any comparable data in independent series of patients. Besides, our findings were congruous with existing literature: lung cancer in never smoker is more frequent among women, and adenocarcinoma. In addition, the mutation profile in never smoker strongly differs from smokers [1]. A second critical point is the retrospective reporting of risk factor exposures by patients themselves, without any possibility for a biological exposure objective assessment. However, we tried to minimise interrogation and reporting biases (by using a standardised questionnaire with only two trained, dedicated interviewers), as well as memorisation bias (by delivering the questionnaire prior to the interview to provide more time to answer all questions, and by allowing post-interview revisions and additions). However, our study remains submitted to recall bias. The third critical point is our modest accrual. Although our cohort is one of the largest in this specific field, comparative subgroup analysis was only based on small-number subsets. Therefore, our study lacked sufficient power for estimating differences between patient subsets. For instance, with only 65 patients in the male subgroup, we were able to detect a 23% difference with 80% power and a 0.05 alpha risk (using a bilateral test) [23]. This point is especially critical for mutations since all, except EGFR, deal with small numbers. In addition, our study emphasised exposure patterns that have occurred over the last decades, and it thus did not reflect current occupational and social changes that may result in distinct exposure profiles. Finally, our analysis is restricted to biomarkers tested in the routine setting in France. Thus, some important biomarkers commonly expressed in never smokers such as ROS1 (6% in never smokers) and RET rearrangements were not included in this study [24, 25].
In spite of these limitations, our study carries some strength. First, the never-smoker inclusion criterion was very strict although consensual (fewer than 100 cigarettes in the lifetime) and was checked by physician at inclusion and by staff during interview. Indeed, many studies may be biased, by assessing the “non-smoker” status retrospectively from medical charts, with a risk of overlapping between former- and never-smoker. We also checked for alternative smoking and can thus ensure the lack of contamination from any former (or even very light) smokers. Another noteworthy strength is our comprehensive approach. We collected data on possible exposures to most known or supposed risk factors (including a detailed investigation of occupational exposure), as well as medical data and comprehensive information from tumour biomarker analysis.
This paper reports descriptive finding of the large cohort of European LCINS. Based on these data, we will provide in future papers the main differences in clinical and molecular epidemiology regarding exposure to main risk factors such as passive-smoking, occupational exposure, domestic pollution or reproductive factors [26]. In addition, some new data will result from collaboration with French national institutions for assessment of radon exposure and atmospheric pollution exposure into the BioCAST cohort. Lastly, the population-attributable fraction for most known risk factors of LCINS will be computed taking all this data into account [27].
In conclusion, this study, the largest and most comprehensive analysis of LCINS in a European population, reports differences in age and carcinogen exposure distribution by gender, and emphasizes the crucial role of targetable somatic mutations in this specific population. Physicians facing a never-smoker with a lung cancer should keep in mind than two-thirds of men underwent an occupational exposure and that three-quarters of patients may carry a targetable mutation. The BioCAST/IFCT-1002 study is also an interesting tool for investigating biomarker profiles according to numerous risk exposures and further results are expected soon.
Acknowledgements
The authors thank M. William Lebossé (Junior Research Assistant), who performed interviews with patients; M. Quan Tran and Antoine Deroy (Data Manager); Pascale Missy (PhD), (all IFCT, Paris, France) who provided administrative support; each investigator in the 75 BioCAST participating centres; the patients and their families, who greatly contributed to this work by giving their time to prepare the questionnaire and participate in the interview.
The collaborators of the BioCAST/IFCT-1002 study were: Pierre-Jean Souquet, Hospices Civils de Lyon, Hôpital Lyon Sud, Lyon; Radj Gervais, Centre François Baclesse, Caen; Hélène Doubre, Hôpital Foch, Suresnes, Paris; Eric Pichon, Centre Hospitalier Universitaire de Tours, Tours; Adrien Dixmier, Centre Hospitalier d'Orléans, Orléans; Isabelle Monnet, Centre Hospitalier Intercommunal de Créteil, Paris; Bénédicte Mastroianni, Hospices Civils de Lyon, Hôpital Louis Pradel, Lyon; Michel Vincent, Hôpital Saint-Joseph, Lyon; Jean Tredaniel, Hôpital Saint Joseph, Paris; Marielle Perrichon, Centre Hospitalier de Bourg-en-Bresse, Bourg-en-Bresse; Pascal Foucher, Centre Hospitalier Universitaire Bocage, Dijon; Bruno Coudert, Centre Georges-François Leclerc, Dijon; Denis Moro-Sibilot, Centre Hospitalier Universitaire de Grenoble, Grenoble; Eric Dansin, Centre Oscar Lambret, Lille; Patrick Dumont, Centre Hospitalier de Chauny, Chauny; Lionel Moreau, Centre Hospitalier de Colmar, Colmar; Didier Debieuvre, Centre Hospitalier de Mulhouse, Mulhouse; Jacques Margery, Hôpital d'Instruction des Armées de Percy, Clamart, Paris; Élisabeth Quoix, Centre Hospitalier Universitaire de Strasbourg, Nouvel Hôpital Civil, Strasbourg; Bernard Duvert, Centre Hospitalier de Montélimar, Montélimar; Laurent Cellerin, Centre Hospitalier Universitaire de Nantes, Hôpital Nord Laennec, Nantes; Nathalie Baize, Centre Hospitalier Universitaire d'Angers, Angers; Bruno Taviot, Centre Médical Nicolas de Pontoux, Chalon-sur-Saône; Marie Coudurier, Centre Hospitalier Chambéry, Chambéry; Jacques Cadranel, Assistance Publique–Hôpitaux de Paris, Hôpital Tenon, Paris; Patrick Chatellain, Centre Hospitalier d'Annemasse, Annemasse; Jérôme Virally, Centre Hospitalier Intercommunal d'Aulnay-Sous-Bois, Paris; Virginie Westeel, Centre Hospitalier Universitaire de Besançon, Besançon; Sylvie Labrune, Assistance Publique–Hôpitaux de Paris, Hôpital Ambroise Paré, Boulogne, Boulogne; Laureline le Maignan de Kerangat, Centre Hospitalier Général Le Mans, Le Mans; Jean-Marc Dot, Hôpital d'Instruction des Armées Desgenettes, Lyon; Sébastien Larive, Centre Hospitalier de Mâcon, Mâcon; Christos Chouaid, Assistance Publique–Hôpitaux de Paris, Hôpital Saint-Antoine, Paris; Daniel Coëtmeur, Centre Hospitalier Général de Saint-Brieuc, Saint-Brieuc; Clarisse Audigier-Valette, Centre Hospitalier Intercommunal de Toulon, Toulon; Jean-Pierre Gury, Centre Hospitalier Intercommunal de Vesoul, Vesoul; Luc Odier, Centre Hospitalier de Villefranche sur Saône, Villefranche sur Saône; Tsellina Desfemmes-Baleyte, Centre Hospitalier Universitaire de Caen, Caen; Yannick Duval, Centre Hospitalier de Cannes, Cannes; Patrick Merle, Centre Hospitalier Universitaire de Clermont-Ferrand, Clermont-Ferrand; Gilles Devouassoux, Hospices Civils de Lyon, Hôpital de la Croix Rousse, Lyon; Reza Azarian, Centre Hospitalier de Versailles, Versailles; Patricia Barre, Centre Hospitalier de Cahors, Cahors; Olivier Raffy, Centre Hospitalier de Chartres, Chartres; Philippe Masson, Centre Hospitalier de Cholet, Cholet; Stéphanie Dehette, Centre Hospitalier de Compiègne, Compiègne; Caroline Toussaint Batbedat, Centre Hospitalier de Lagny-sur-Marne, Paris; Gérard Oliviero, Centre Hospitalier de Longjumeau, Paris; Marc Derollez, Polyclinique du Parc, Maubeuge; Nadine Paillot, Centre Hospitalier Régional de Metz, Metz; Jérôme Dauba, Centre Hospitalier de Mont De Marsan, Mont De Marsan; Dominique Herman, Centre Hospitalier de Nevers, Nevers; Jean-Michel Rodier, Assistance Publique–Hôpitaux de Paris, Hôpital Bichat, Paris; Suzanna Bota, Centre Hospitalier Universitaire de Rouen, Rouen; Philippe Brun, Centre Hospitalier de Valence, Valence; Geneviève Letanche, Clinique de Vénissieux Lyon; Mohamed Khomsi, Centre Hospitalier d'Annonay, Annonay; Béatrice Gentil-Lepecq, Centre Hospitalier de Bourgoin-Jallieu, Bourgoin-Jallieu; Philippe Ravier, Cabinet de Pneumologie, Dijon, Dijon; Yassine Hammou, Clinique Mutualiste, Lyon; Fabrice Barlesi, Assistance Publique-Hôpitaux de Marseille, Hôpital Nord, Marseille; Hélène Laize, Centre Hospitalier de Rambouillet, Rambouillet; Pierre Fournel, Institut de Cancérologie de la Loire, Saint-Priest en Jarez; Christelle Clement-Duchene, Centre Hospitalier Universitaire de Nancy, Vandoeuvre-Les-Nancy; Joël Castelli, Centre Hospitalier Départemental Castelluccio, Ajaccio; Sophie Schneider, Centre Hospitalier de Bayonne, Bayonne; Antoine Levy, Centre Hospitalier Jacques Cœur, Bourges; Jérôme Dauba, Centre Hospitalier de Dax, Dax; Geneviève Jolimoy, Centre d'Oncologie et de Radiothérapie du Parc, Dijon; Hervé Pegliasco, Fondation Hôpital Ambroise Paré, Marseille; Michel Poudenx, Centre Antoine Lacassagne, Nice; Alain Prevost, Institut Jean-Godinot, Reims; Philippe Romand, Centre Hospitalier de Thonon-les-Bains, Thonon-les-Bains; Laurence Bigay-Game, Centre Hospitalier Universitaire de Toulouse, Toulouse; Etienne Suc, Clinique St Jean Languedoc, Toulouse; all France.
Footnotes
For editorial comment see Eur Respir J 2015; 45: 1214–1217 [DOI: 10.1183/09031936.00046915]
This article has supplementary material available from erj.ersjournals.com.
Support statement: The BioCAST/IFCT-1002 study was supported by research grants from Astra-Zeneca, Boehringer Ingelheim, Lilly, Pfizer, Pierre-Fabre and Roche. Funding for this article has been deposited with FundRef. Those awarding funding had no role in the design, analysis and interpretation of the results, and the authors worked independently.
Conflict of interest: Disclosures can be found alongside the online version of this article at erj.ersjournals.com
- Received March 5, 2014.
- Accepted November 23, 2014.
- Copyright ©ERS 2015