Low-dose computed tomography screening for lung cancer in people with workplace exposure to asbestos

P. Maisonneuve; C. Rampinelli; R. Bertolotti; A. Misotti; F. Lococo; M. Casiraghi; L. Spaggiari; M. Bellomi; P. Novellis; M. Solinas; E. Dieci; M. Alloisio; L. Fontana; B. Persechino; S. Iavicoli; G. Veronesi

doi:10.1016/j.lungcan.2019.03.003

Low-dose computed tomography screening for lung cancer in people with workplace exposure to asbestos

P. Maisonneuve, C. Rampinelli, R. Bertolotti, A. Misotti, F. Lococo, M. Casiraghi, L. Spaggiari, M. Bellomi, P. Novellis, M. Solinas, E. Dieci, M. Alloisio, L. Fontana, B. Persechino, S. Iavicoli, G. Veronesi

Research output: Contribution to journal › Article › peer-review

Abstract

Objectives: Smoking is the main risk factor for lung cancer, but environmental and occupational exposure to carcinogens also increase lung cancer risk. We assessed whether extending low-dose computed tomography (LDCT) screening to persons with occupational exposure to asbestos may be an effective way reducing lung cancer mortality. Materials and methods: We conducted a nested case-control study within the COSMOS screening program, assessing past asbestos exposure with a questionnaire. LDCT scans of asbestos-exposed participants were reviewed to assess the presence of pulmonary, interstitial and pleural alterations in comparison to matched unexposed controls. We also performed an exhaustive review, with meta-analysis, of the literature on LDCT screening in asbestos-exposed persons. Results: Exposure to asbestos, initially self-reported by 9.8% of COSMOS participants, was confirmed in 216 of 544 assessable cases, corresponding to 2.6% of the screened population. LDCT of asbestos-exposed persons had significantly more pleural plaques, diaphragmatic pleural thickening and pleural calcifications, but similar frequency of parenchymal and interstitial alterations to unexposed persons. From 16 papers, including this study, overall lung cancer detection rates at baseline were 0.81% (95% CI 0.50–1.19) in asbestos-exposed persons, 0.94% (95% CI 0.47–1.53) in asbestos-exposed smokers (12 studies), and 0.11% (95% CI 0.00-0.43) in asbestos-exposed non-smokers (9 studies). Conclusion: Persons occupationally exposed to asbestos should be monitored to gather more information about risks. Although LDCT screening is effective in the early detection lung cancer in asbestos-exposed smokers, our data suggest that screening of asbestos-exposed persons with no additional risk factors for cancer does is not viable due to the low detection rate. © 2019 Elsevier B.V.

Original language	English
Pages (from-to)	23-30
Number of pages	8
Journal	Lung Cancer
Volume	131
DOIs	https://doi.org/10.1016/j.lungcan.2019.03.003
Publication status	Published - 2019

Keywords

Asbestos-exposed
Low-dose chest CT
Lung cancer screening
Lung-neoplasms
Meta-analysis
Pleural plaques
Pleural thickening
asbestos
adult
Article
cancer mortality
cancer risk
cancer screening
case control study
computer assisted tomography
controlled study
female
high risk population
human
interstitial lung disease
lung cancer
lung parenchyma
major clinical study
male
middle aged
occupational exposure
pleura disease
pleura plaque
pleura thickening
pleural calcification
priority journal
self report
smoking
workplace

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10.1016/j.lungcan.2019.03.003

https://www.scopus.com/inward/record.uri?eid=2-s2.0-85062708455&doi=10.1016%2fj.lungcan.2019.03.003&partnerID=40&md5=1b16e61ec422b9188e1778e2717b7345

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Maisonneuve, P., Rampinelli, C., Bertolotti, R., Misotti, A., Lococo, F., Casiraghi, M., Spaggiari, L., Bellomi, M., Novellis, P., Solinas, M., Dieci, E., Alloisio, M., Fontana, L., Persechino, B., Iavicoli, S., & Veronesi, G. (2019). Low-dose computed tomography screening for lung cancer in people with workplace exposure to asbestos. Lung Cancer, 131, 23-30. https://doi.org/10.1016/j.lungcan.2019.03.003

Low-dose computed tomography screening for lung cancer in people with workplace exposure to asbestos. / Maisonneuve, P.; Rampinelli, C.; Bertolotti, R.; Misotti, A.; Lococo, F.; Casiraghi, M.; Spaggiari, L.; Bellomi, M.; Novellis, P.; Solinas, M.; Dieci, E.; Alloisio, M.; Fontana, L.; Persechino, B.; Iavicoli, S.; Veronesi, G.

In: Lung Cancer, Vol. 131, 2019, p. 23-30.

Research output: Contribution to journal › Article › peer-review

Maisonneuve, P , Rampinelli, C , Bertolotti, R, Misotti, A, Lococo, F , Casiraghi, M , Spaggiari, L, Bellomi, M, Novellis, P, Solinas, M, Dieci, E, Alloisio, M, Fontana, L, Persechino, B, Iavicoli, S & Veronesi, G 2019, 'Low-dose computed tomography screening for lung cancer in people with workplace exposure to asbestos', Lung Cancer, vol. 131, pp. 23-30. https://doi.org/10.1016/j.lungcan.2019.03.003

Maisonneuve, P. ; Rampinelli, C. ; Bertolotti, R. ; Misotti, A. ; Lococo, F. ; Casiraghi, M. ; Spaggiari, L. ; Bellomi, M. ; Novellis, P. ; Solinas, M. ; Dieci, E. ; Alloisio, M. ; Fontana, L. ; Persechino, B. ; Iavicoli, S. ; Veronesi, G. / Low-dose computed tomography screening for lung cancer in people with workplace exposure to asbestos. In: Lung Cancer. 2019 ; Vol. 131. pp. 23-30.

@article{9ebe146a777c4708bc2050c2ea3f221a,

title = "Low-dose computed tomography screening for lung cancer in people with workplace exposure to asbestos",

abstract = "Objectives: Smoking is the main risk factor for lung cancer, but environmental and occupational exposure to carcinogens also increase lung cancer risk. We assessed whether extending low-dose computed tomography (LDCT) screening to persons with occupational exposure to asbestos may be an effective way reducing lung cancer mortality. Materials and methods: We conducted a nested case-control study within the COSMOS screening program, assessing past asbestos exposure with a questionnaire. LDCT scans of asbestos-exposed participants were reviewed to assess the presence of pulmonary, interstitial and pleural alterations in comparison to matched unexposed controls. We also performed an exhaustive review, with meta-analysis, of the literature on LDCT screening in asbestos-exposed persons. Results: Exposure to asbestos, initially self-reported by 9.8% of COSMOS participants, was confirmed in 216 of 544 assessable cases, corresponding to 2.6% of the screened population. LDCT of asbestos-exposed persons had significantly more pleural plaques, diaphragmatic pleural thickening and pleural calcifications, but similar frequency of parenchymal and interstitial alterations to unexposed persons. From 16 papers, including this study, overall lung cancer detection rates at baseline were 0.81% (95% CI 0.50–1.19) in asbestos-exposed persons, 0.94% (95% CI 0.47–1.53) in asbestos-exposed smokers (12 studies), and 0.11% (95% CI 0.00-0.43) in asbestos-exposed non-smokers (9 studies). Conclusion: Persons occupationally exposed to asbestos should be monitored to gather more information about risks. Although LDCT screening is effective in the early detection lung cancer in asbestos-exposed smokers, our data suggest that screening of asbestos-exposed persons with no additional risk factors for cancer does is not viable due to the low detection rate. {\textcopyright} 2019 Elsevier B.V.",

keywords = "Asbestos-exposed, Low-dose chest CT, Lung cancer screening, Lung-neoplasms, Meta-analysis, Pleural plaques, Pleural thickening, asbestos, adult, Article, cancer mortality, cancer risk, cancer screening, case control study, computer assisted tomography, controlled study, female, high risk population, human, interstitial lung disease, lung cancer, lung parenchyma, major clinical study, male, middle aged, occupational exposure, pleura disease, pleura plaque, pleura thickening, pleural calcification, priority journal, self report, smoking, workplace",

author = "P. Maisonneuve and C. Rampinelli and R. Bertolotti and A. Misotti and F. Lococo and M. Casiraghi and L. Spaggiari and M. Bellomi and P. Novellis and M. Solinas and E. Dieci and M. Alloisio and L. Fontana and B. Persechino and S. Iavicoli and G. Veronesi",

note = "Cited By :3 Export Date: 27 February 2020 CODEN: LUCAE Correspondence Address: Maisonneuve, P.; Unit of Clinical Epidemiology, Division of Epidemiology and Biostatistics, IEO, European Institute of Oncology IRCCS, Via Ripamonti 435, Italy; email: patrick.maisonneuve@ieo.it Chemicals/CAS: asbestos, 1332-21-4 Funding details: Istituto Nazionale per l'Assicurazione Contro Gli Infortuni sul Lavoro Funding text 1: This work was financed by INAIL as part of Research Activity Plan BRiC 2016 – ID56. ED and MS are recipients grants from the Umberto Veronesi foundation. The authors thank Don Ward for help with the English was added to the cases and non-cases to allow calculation of study weights and variance. Appendix A References: Bray, F., Ferlay, J., Soerjomataram, I., Siegel, R.L., Torre, L.A., Jemal, A., Global cancer statistics 2018: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries (2018) CA Cancer J. Clin., 68, pp. 394-424; Malarkey, D.E., Hoenerhoff, M., Maronpot, R.R., Carcinogenesis: mechanisms and manifestations (2013) Haschek and Rousseaux's Handbook of Toxicologic Pathology, p. 107. , W.M. Haschek C.G. Rousseaux M.A. Wallig Academic Press Waltham, MA; Pr{\"u}ss-Ust{\"u}n, A., Wolf, J., Corval{\'a}n, C., Bos, R., Neira, M., Preventing Disease through Healthy Environments. A Global Assessment of the Burden of Disease from Environmental Risks (2016), World Health Organization WHO 92 4 156519 6; Doll, R., Peto, R., The causes of cancer: quantitative estimates of avoidable risks of cancer in the United States today (1981) J. Natl. Cancer Inst., 66, pp. 1191-1308; Nenonen, N., H{\"a}m{\"a}l{\"a}inen, P., Takala, J., Saarela, K.L., Lim, S.L., Lim, G.K., Manickam, K., Global Estimates of Occupational Accidents and Fatal Work-related Diseases in 2014 based on 2010 and 2011 Data (2014), http://goo.gl/UlZorD, http://goo.gl/tN7XDn, Report to the ILO Tampere, Singapore, ILO Geneva and; Takala, J., Work-related Illnesses, Identification, Causal Factors and Prevention {\textquoteleft}safe Work – Healthy Work – for Life{\textquoteright} Greek EU Presidency Conference Athens, 16-17 June 2014 (2014); Loomis, D., Guha, N., Hall, A.L., Straif, K., Identifying occupational carcinogens: an update from the IARC Monographs (2018) Occup. Environ. Med., 75, pp. 593-603; Straif, K., The burden of occupational cancer (2008) Occup. Environ. Med., 65, pp. 787-788; National Lung Screening Trial Research Team, Aberle, D.R., Adams, A.M., Berg, C.D., Black, W.C., Clapp, J.D., Reduced lung-cancer mortality with low-dose computed tomographic screening (2011) N. Engl. J. Med., 365, pp. 395-409; De Koning, H., Van Der Aalst, C., Ten Haaf, K., Oudkerk, M., Effects of volume CT lung cancer screening: mortality results of the NELSON randomised-controlled population based trial (2018) Presented at: IASLC 19th World Conference on Lung Cancer, , https://wclc2018.iaslc.org/media/2018%20WCLC%20Press%20Program%20Press%20Release%20De%20Koning%209.25%20FINAL%20.pdf, Abstract PL02.05; Veronesi, G., Ajay, M., Mulshine, J.L., Pelosi, G., Scanagatta, P., Paganelli, G., Lung cancer screening with low-dose computed tomography: a non- -invasive diagnostic protocol for baseline lung nodules (2008) Lung Cancer, 61, pp. 340-349; Maisonneuve, P., Bagnardi, V., Ajay, M., Spaggiari, L., Pelosi, G., Rampinelli, C., Lung Cancer risk prediction for smokers to select screening CT - model based COSMOS on the Italian trial (2011) Cancer Prev. Res. (Phila), 4, pp. 1778-1789; Henschke, C.I., McCauley, D.I., Yankelevitz, D.F., Naidich, D.P., McGuinness, G., Miettinen, O.S., Early Lung Cancer action Project: overall design and findings from baseline screening (1999) Lancet, 354, pp. 99-105; Black, W.C., Gareen, I.F., Soneji, S.S., Sicks, J.D., Keeler, A.B., Abeler, D.R., Cost-effectiveness of CT screening in the national lung screening trial (2014) N. Engl. J. Med., 371, pp. 1793-1802; Veronesi, G., Maisonneuve, P., Spaggiari, L., Rampinelli, C., Pelosi, G., Preda, L., Long-term outcomes of a pilot CT screening for lung cancer (2010) Ecancermedicalscience, 4, p. 186; Wolff, H., Vehmas, T., Oksa, P., Rantanen, J., Vainio, H., Asbestos, asbestosis, and cancer, the Helsinki criteria for diagnosis and attribution 2014: recommendations (2015) Scand. J. Work Environ. Health, 41, pp. 5-15; Bach, P.B., Kattan, M.W., Thornquist, M.D., Kris, M.G., Tate, R.C., Barnett, M.J., Variations in lung cancer risk among smokers (2003) J. Natl. 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year = "2019",

doi = "10.1016/j.lungcan.2019.03.003",

language = "English",

volume = "131",

pages = "23--30",

journal = "Lung Cancer",

issn = "0169-5002",

publisher = "Elsevier Ireland Ltd",

}

TY - JOUR

T1 - Low-dose computed tomography screening for lung cancer in people with workplace exposure to asbestos

AU - Maisonneuve, P.

AU - Rampinelli, C.

AU - Bertolotti, R.

AU - Misotti, A.

AU - Lococo, F.

AU - Casiraghi, M.

AU - Spaggiari, L.

AU - Bellomi, M.

AU - Novellis, P.

AU - Solinas, M.

AU - Dieci, E.

AU - Alloisio, M.

AU - Fontana, L.

AU - Persechino, B.

AU - Iavicoli, S.

AU - Veronesi, G.

N1 - Cited By :3 Export Date: 27 February 2020 CODEN: LUCAE Correspondence Address: Maisonneuve, P.; Unit of Clinical Epidemiology, Division of Epidemiology and Biostatistics, IEO, European Institute of Oncology IRCCS, Via Ripamonti 435, Italy; email: patrick.maisonneuve@ieo.it Chemicals/CAS: asbestos, 1332-21-4 Funding details: Istituto Nazionale per l'Assicurazione Contro Gli Infortuni sul Lavoro Funding text 1: This work was financed by INAIL as part of Research Activity Plan BRiC 2016 – ID56. ED and MS are recipients grants from the Umberto Veronesi foundation. The authors thank Don Ward for help with the English was added to the cases and non-cases to allow calculation of study weights and variance. Appendix A References: Bray, F., Ferlay, J., Soerjomataram, I., Siegel, R.L., Torre, L.A., Jemal, A., Global cancer statistics 2018: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries (2018) CA Cancer J. Clin., 68, pp. 394-424; Malarkey, D.E., Hoenerhoff, M., Maronpot, R.R., Carcinogenesis: mechanisms and manifestations (2013) Haschek and Rousseaux's Handbook of Toxicologic Pathology, p. 107. , W.M. Haschek C.G. Rousseaux M.A. Wallig Academic Press Waltham, MA; Prüss-Ustün, A., Wolf, J., Corvalán, C., Bos, R., Neira, M., Preventing Disease through Healthy Environments. A Global Assessment of the Burden of Disease from Environmental Risks (2016), World Health Organization WHO 92 4 156519 6; Doll, R., Peto, R., The causes of cancer: quantitative estimates of avoidable risks of cancer in the United States today (1981) J. Natl. Cancer Inst., 66, pp. 1191-1308; Nenonen, N., Hämäläinen, P., Takala, J., Saarela, K.L., Lim, S.L., Lim, G.K., Manickam, K., Global Estimates of Occupational Accidents and Fatal Work-related Diseases in 2014 based on 2010 and 2011 Data (2014), http://goo.gl/UlZorD, http://goo.gl/tN7XDn, Report to the ILO Tampere, Singapore, ILO Geneva and; Takala, J., Work-related Illnesses, Identification, Causal Factors and Prevention ‘safe Work – Healthy Work – for Life’ Greek EU Presidency Conference Athens, 16-17 June 2014 (2014); Loomis, D., Guha, N., Hall, A.L., Straif, K., Identifying occupational carcinogens: an update from the IARC Monographs (2018) Occup. Environ. Med., 75, pp. 593-603; Straif, K., The burden of occupational cancer (2008) Occup. Environ. Med., 65, pp. 787-788; National Lung Screening Trial Research Team, Aberle, D.R., Adams, A.M., Berg, C.D., Black, W.C., Clapp, J.D., Reduced lung-cancer mortality with low-dose computed tomographic screening (2011) N. Engl. J. Med., 365, pp. 395-409; De Koning, H., Van Der Aalst, C., Ten Haaf, K., Oudkerk, M., Effects of volume CT lung cancer screening: mortality results of the NELSON randomised-controlled population based trial (2018) Presented at: IASLC 19th World Conference on Lung Cancer, , https://wclc2018.iaslc.org/media/2018%20WCLC%20Press%20Program%20Press%20Release%20De%20Koning%209.25%20FINAL%20.pdf, Abstract PL02.05; Veronesi, G., Ajay, M., Mulshine, J.L., Pelosi, G., Scanagatta, P., Paganelli, G., Lung cancer screening with low-dose computed tomography: a non- -invasive diagnostic protocol for baseline lung nodules (2008) Lung Cancer, 61, pp. 340-349; Maisonneuve, P., Bagnardi, V., Ajay, M., Spaggiari, L., Pelosi, G., Rampinelli, C., Lung Cancer risk prediction for smokers to select screening CT - model based COSMOS on the Italian trial (2011) Cancer Prev. Res. (Phila), 4, pp. 1778-1789; Henschke, C.I., McCauley, D.I., Yankelevitz, D.F., Naidich, D.P., McGuinness, G., Miettinen, O.S., Early Lung Cancer action Project: overall design and findings from baseline screening (1999) Lancet, 354, pp. 99-105; Black, W.C., Gareen, I.F., Soneji, S.S., Sicks, J.D., Keeler, A.B., Abeler, D.R., Cost-effectiveness of CT screening in the national lung screening trial (2014) N. Engl. J. Med., 371, pp. 1793-1802; Veronesi, G., Maisonneuve, P., Spaggiari, L., Rampinelli, C., Pelosi, G., Preda, L., Long-term outcomes of a pilot CT screening for lung cancer (2010) Ecancermedicalscience, 4, p. 186; Wolff, H., Vehmas, T., Oksa, P., Rantanen, J., Vainio, H., Asbestos, asbestosis, and cancer, the Helsinki criteria for diagnosis and attribution 2014: recommendations (2015) Scand. J. Work Environ. Health, 41, pp. 5-15; Bach, P.B., Kattan, M.W., Thornquist, M.D., Kris, M.G., Tate, R.C., Barnett, M.J., Variations in lung cancer risk among smokers (2003) J. Natl. Cancer Inst., 95, pp. 470-478; Cassidy, A., Myles, J.P., van Tongeren, M., Page, R.D., Liloglou, T., Duffy, S.W., The LLP risk model: an individual risk prediction model for lung cancer (2008) Br. J. Cancer, 98, pp. 270-276; Spitz, M.R., Hong, W.K., Amos, C.I., Wu, X., Schabath, M.B., Dong, Q., A risk model for prediction of lung cancer (2007) J. Natl. Cancer Inst., 99, pp. 715-726; Silva, M., Sverzellati, N., Colombi, D., Milanese, G., La Vecchia, C., Galeone, C., Pleural plaques in lung cancer screening by low-dose computed tomography: prevalence, association with lung cancer and mortality (2017) BMC Pulm. Med., 17, p. 155; Wallace, B.C., Schmid, C.H., Lau, J., Trikalinos, T.A., Meta-Analyst: software for meta-analysis of binary, continuous and diagnostic data (2009) BMC Med. Res. 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PY - 2019

Y1 - 2019

N2 - Objectives: Smoking is the main risk factor for lung cancer, but environmental and occupational exposure to carcinogens also increase lung cancer risk. We assessed whether extending low-dose computed tomography (LDCT) screening to persons with occupational exposure to asbestos may be an effective way reducing lung cancer mortality. Materials and methods: We conducted a nested case-control study within the COSMOS screening program, assessing past asbestos exposure with a questionnaire. LDCT scans of asbestos-exposed participants were reviewed to assess the presence of pulmonary, interstitial and pleural alterations in comparison to matched unexposed controls. We also performed an exhaustive review, with meta-analysis, of the literature on LDCT screening in asbestos-exposed persons. Results: Exposure to asbestos, initially self-reported by 9.8% of COSMOS participants, was confirmed in 216 of 544 assessable cases, corresponding to 2.6% of the screened population. LDCT of asbestos-exposed persons had significantly more pleural plaques, diaphragmatic pleural thickening and pleural calcifications, but similar frequency of parenchymal and interstitial alterations to unexposed persons. From 16 papers, including this study, overall lung cancer detection rates at baseline were 0.81% (95% CI 0.50–1.19) in asbestos-exposed persons, 0.94% (95% CI 0.47–1.53) in asbestos-exposed smokers (12 studies), and 0.11% (95% CI 0.00-0.43) in asbestos-exposed non-smokers (9 studies). Conclusion: Persons occupationally exposed to asbestos should be monitored to gather more information about risks. Although LDCT screening is effective in the early detection lung cancer in asbestos-exposed smokers, our data suggest that screening of asbestos-exposed persons with no additional risk factors for cancer does is not viable due to the low detection rate. © 2019 Elsevier B.V.

AB - Objectives: Smoking is the main risk factor for lung cancer, but environmental and occupational exposure to carcinogens also increase lung cancer risk. We assessed whether extending low-dose computed tomography (LDCT) screening to persons with occupational exposure to asbestos may be an effective way reducing lung cancer mortality. Materials and methods: We conducted a nested case-control study within the COSMOS screening program, assessing past asbestos exposure with a questionnaire. LDCT scans of asbestos-exposed participants were reviewed to assess the presence of pulmonary, interstitial and pleural alterations in comparison to matched unexposed controls. We also performed an exhaustive review, with meta-analysis, of the literature on LDCT screening in asbestos-exposed persons. Results: Exposure to asbestos, initially self-reported by 9.8% of COSMOS participants, was confirmed in 216 of 544 assessable cases, corresponding to 2.6% of the screened population. LDCT of asbestos-exposed persons had significantly more pleural plaques, diaphragmatic pleural thickening and pleural calcifications, but similar frequency of parenchymal and interstitial alterations to unexposed persons. From 16 papers, including this study, overall lung cancer detection rates at baseline were 0.81% (95% CI 0.50–1.19) in asbestos-exposed persons, 0.94% (95% CI 0.47–1.53) in asbestos-exposed smokers (12 studies), and 0.11% (95% CI 0.00-0.43) in asbestos-exposed non-smokers (9 studies). Conclusion: Persons occupationally exposed to asbestos should be monitored to gather more information about risks. Although LDCT screening is effective in the early detection lung cancer in asbestos-exposed smokers, our data suggest that screening of asbestos-exposed persons with no additional risk factors for cancer does is not viable due to the low detection rate. © 2019 Elsevier B.V.

KW - Asbestos-exposed

KW - Low-dose chest CT

KW - Lung cancer screening

KW - Lung-neoplasms

KW - Meta-analysis

KW - Pleural plaques

KW - Pleural thickening

KW - asbestos

KW - adult

KW - Article

KW - cancer mortality

KW - cancer risk

KW - cancer screening

KW - case control study

KW - computer assisted tomography

KW - controlled study

KW - female

KW - high risk population

KW - human

KW - interstitial lung disease

KW - lung cancer

KW - lung parenchyma

KW - major clinical study

KW - male

KW - middle aged

KW - occupational exposure

KW - pleura disease

KW - pleura plaque

KW - pleura thickening

KW - pleural calcification

KW - priority journal

KW - self report

KW - smoking

KW - workplace

U2 - 10.1016/j.lungcan.2019.03.003

DO - 10.1016/j.lungcan.2019.03.003

M3 - Article

VL - 131

SP - 23

EP - 30

JO - Lung Cancer

JF - Lung Cancer

SN - 0169-5002

ER -

Low-dose computed tomography screening for lung cancer in people with workplace exposure to asbestos

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