Tackling second-hand exposure to tobacco smoke and aerosols of electronic cigarettes: the TackSHS project protocol

Abordando la exposición a las emisiones del tabaco y de los cigarrillos electrónicos: protocolo del proyecto TackSHS

Esteve Fernández María José López Silvano Gallus Sean Semple Luke Clancy Panagiotis Behrakis Ario Ruprecht Giuseppe Gorini Ángel López-Nicolás Cornel Radu-Loghin Joan B. Soriano TackSHS Project InvestigatorsAbout the authors

Abstract

Objective

The TackSHS project aims to comprehensively elucidate the impact that exposure to secondhand smoke (SHS) from cigarettes and second-hand aerosols (SHA) from electronic cigarettes have on the respiratory health of the European population according to socioeconomic characteristics and other determinants.

Method

The TackSHS project involves a series of coordinated studies carried out by 11 academic and public health organisations from six European countries. The project will investigate: a) the determinants of SHS and SHA exposure assessed at the individual level (surveys on representative general population samples) and in common environments (environmental sampling in specific settings); b) the overall disease burden, mortality and morbidity attributable to such exposure; and c) its economic impact in terms of direct health care costs. The project will also examine specific acute respiratory health changes in healthy individuals and patients with respiratory diseases exposed to SHS and SHA. In addition, the project will examine the effectiveness of a novel intervention to reduce SHS exposure in households where smoking is permitted. All these studies are inter-related and involve collaborative coordination among the participant organisations.

Conclusion

The comprehensive, integrated approach of the TackSHS project will enable a significant step forward from the current status quo in the understanding of the impact of SHS and SHA exposure on health and provide the basis for health policy recommendations to help European countries to further reduce the harm caused by SHS and SHA exposure.

Keywords:
Second-hand smoke; Passive smoking; Electronic cigarette; Electronic nicotine delivery systems; Aerosols; Second-hand aerosols; Respiratory health; Burden of disease; Economic impact

Resumen

Objetivo

El proyecto TackSHS pretende caracterizar el impacto global de la exposición al humo ambiental de tabaco (HAT) y al aerosol de los cigarrillos electrónicos (ACE) en la salud respiratoria de la población europea según variables socioeconómicas y otros determinantes.

Método

El proyecto TackSHS consiste en una serie de estudios coordinados y gestionados por 11 organizaciones académicas y de salud pública de seis países europeos. El proyecto estudiará: a) los determinantes de la exposición al HAT y al ACE a nivel individual (encuestas en muestras representativas de la población general) y en espacios comunes (muestras ambientales en lugares específicos); b) su carga general de enfermedad y la morbimortalidad atribuible a tal exposición; y c) su impacto económico en términos de costes sanitarios directos e indirectos. Además, el proyecto investigará cambios específicos a corto plazo en la salud respiratoria en personas sanas y en pacientes con enfermedades respiratorias expuestos al HAT y al ACE. También examinará la efectividad de una intervención novedosa para reducir la exposición al HAT en hogares donde se permite fumar. Todos estos estudios están interrelacionados y conllevan una coordinación colaborativa entre las instituciones participantes.

Conclusión

El enfoque integral del proyecto TackSHS permitirá un avance significativo en la evidencia sobre la comprensión del impacto de la exposición al HAT y al ACE en la salud, y proporcionará una base para desarrollar recomendaciones políticas sanitarias para ayudar a los países europeos a reducir los daños causados por la exposición al HAT y al ACE.

Palabras clave:
Humo ambiental del tabaco; Tabaquismo pasivo; Cigarrillos electrónicos; Sistemas electrónicos de administración de nicotina; Exposición al aerosol; Salud respiratoria; Carga de enfermedad; Impacto económico

Introduction

Research produced during the past three decades has provided substantial evidence of the harm that shortand long-term exposure to second-hand smoke (SHS) represents to respiratory and cardiovascular health of adults and children.11. IARC Working Group on the Evaluation of Carcinogenic Risks to Humans. Tobacco smoke and involuntary smoking. Lyon: International Agency for Research on Cancer; 2004. vol. 83-22. Junker MH, Danuser B, Monn C, et al. Acute sensory responses of nonsmokers at very low environmental tobacco smoke concentrations in controlled laboratory settings. Environ Health Perspect. 2001;109:1045-52. While interest in SHS exposure prevalence and its effects is increasing,33. Oberg M, Jaakkola MS, Woodward A, et al. Worldwide burden of disease from exposure to second-hand smoke: a retrospective analysis of data from 192 countries. Lancet. 2011;377:139-46. important gaps remain when designing national and international health policies aiming to protect populations. One of them is a scarcity of studies objectively measuring markers of SHS in settings where smoking is not regulated, such as private and outdoor public places. In addition, electronic cigarettes (e-cigarettes) have irrupted into the market of tobacco products in the past decade, creating an on-going debate among the research community on their health effects and potential impact on public health.44. Chapman S. E-cigarettes: the best and the worst case scenarios for public health an essay by Simon Chapman. BMJ. 2014;349:g5512. While active e-cigarette use and its health effects have received substantial attention in research, evidence on the health impact of bystanders' exposure to second-hand aerosols (SHA) generated by its use is still scarce.55. Glasser AM, Collins L, Pearson JL, et al. Overview of electronic nicotine delivery systems: a systematic review. Am J Prev Med. 2017;52:e33-66.

The project “Tackling secondhand tobacco smoke and ecigarette emissions: exposure assessment, novel interventions, impact on lung diseases and economic burden in diverse European populations” (the TackSHS project: www.tackshs.eu) was developed to address these and other challenges in the research of SHS and SHA. The TackSHS project intends to comprehensively elucidate the impact that SHS and SHA exposure have on the European population and how health impacts vary according to socioeconomic and other demographic characteristics, with a particular emphasis on specific vulnerable groups. This paper describes the specific objectives and methods of each study or 'work-package' within the project.

Method

The TackSHS project is organised in 11 work-packages (WP) of which eight are research-oriented and correspond to independent studies, with a further three WPs involved in providing support (coordination, instrument calibration, and results dissemination) during the 48 months of the project (November 2015 - October 2019). The overall structure of the project is depicted in Figure 1. A summary of the WPs with the leading partners is provided in Table I of the online Appendix.

Figure 1
TackSHS project structure and organisation of the work packages (WPs). SHS: Secondhand smoke; e-cig: electronic cigarettes.

Study 1. Environmental assessment of SHS exposure in private and outdoor settings in Europe (WP2)

This is a European cross-sectional study, led by the Agència de Salut Pública de Barcelona (Spain), that aims to objectively assess SHS exposure across a range of different environments where smoking was not regulated at the time this project was planned. The study will be conducted in 11 European countries (Bulgaria, France, Germany, Greece, Ireland, Italy, Poland, Portugal, Romania, Spain and the United Kingdom) representing geographical, legislative (country-specific smoke-free policies) and cultural variations across the European Union (EU). Private settings studied will include homes and cars, while outdoor settings will include terraces of hospitality venues, children playgrounds and entrances to primary school buildings. Around 1000 environmental measurements will be collected: 180 measurements from homes in 9 countries and 660 measurements from outdoor settings in the 11 countries involved in the study; and 120 environmental measurements will be collected in cars in two countries (Spain and the United Kingdom). These countries were selected considering differences in smoking legislation in cars. A convenience sample will be obtained considering neighbourhoods from different socioeconomic status, which will be assessed using local ecological synthetic indexes. SHS will be assessed through the measurement of airborne nicotine. Nicotine samplers, which consist of a 37-mm diameter plastic cassette containing a filter treated with sodium bisulphate, will be used. A passive sampling will be performed in homes (7day sampling) and cars (24-hour sampling). In outdoor settings, active sampling will be used attaching a nicotine sampler to an air pump with a flow rate of 3 L/min, and 30-min measurements will be taken. Sampling will be done avoiding the warmest and the coldest months of the year. All the nicotine samples will be analysed by gas chromatography/mass spectrometry.66. Lopez MJ, Nebot M, Albertini M, et al. Secondhand smoke exposure in hospitality venues in Europe. Environ Health Perspect. 2008;116:1469-72.

Study 2. The TackSHS survey: a pan-European study on SHS and SHA exposure (WP3)

This is a European cross-sectional study, led by the Istituto di Ricerche Farmacologiche Mario Negri IRCCS (Italy), that aims to: 1) estimate the prevalence and the determinants of smoking, e-cigarette use, and exposure to SHS and SHA; 2) analyse attitudes, perceptions and behaviours of the adult European population towards smoke-free policies in their countries; and 3) compare selected smoking-related data originated in this study and a previously conducted pan-European survey (i.e., the PPACTE project).77. Gallus S, Lugo A, La Vecchia C, et al. Pricing Policies and Control of Tobacco in Europe (PPACTE) project. Eur J Cancer Prev. 2014;23:177-85. Approximately 12,000 individuals aged 15 years and older will be enrolled in 12 EU countries (the same countries listed for WP2 plus Latvia). The TackSHS survey will be representative of the country-specific population using a similar methodology of a previous project.77. Gallus S, Lugo A, La Vecchia C, et al. Pricing Policies and Control of Tobacco in Europe (PPACTE) project. Eur J Cancer Prev. 2014;23:177-85. The sample size in each specific country (approximately n = 1000) will enable the estimation of prevalence in that country with a standard error of 1.6%. The sampling methodology (in most of the countries multistage/stratified random sampling) will ensure the representativeness of the adult population in terms of sex, age, geographic area and selected socioeconomic characteristics. A standard questionnaire developed ad hoc from existing validated questionnaires will be used to collect information on cigarette smoking, use of e-cigarettes and emergent heated tobacco products. The questionnaire focuses particularly on the exposure to SHS and the passive exposure to SHA from e-cigarettes in different indoor and outdoor settings. WP3 will also examine compliance with the current country-specific smoke-free legislations, attitudes and perceptions towards various tobacco control policies, including smoking ban regulations that are already adopted, and an extension of these regulations to other (outdoor) public places. Finally, the survey will explore participants' knowledge of the harmful effects of SHS and SHA.

Study 3. Air quality feedback to reduce SHS exposure in homes (WP4)

This is an intervention study, led by the University of Stirling (Scotland, UK), aiming to encourage behaviour-change towards a smoke-free home environment. The study will provide the participants (smokers who smoke at home and take care of at least one child) regular feedback in the form of personalised air quality measurements made in their homes. This study will develop a targeted intervention with socioeconomically deprived smokers in four countries (Greece, Italy, Scotland, and Spain) based on a previously piloted intervention.88. Semple S, Apsley A, Azmina Ibrahim T, et al. Fine particulate matter concentrations in smoking households: just how much secondhand smoke do you breathe in if you live with a smoker who smokes indoors? Tob Control. 2015;24:e205-11. The study will aim to recruit 160 smokers (40 in each country). Participants will have particle counting instruments to measure in real time particulate matter concentration (PM2.5) installed in their homes for a period of 30 days. These devices will allow data acquisition in real-time with a 3G internet connection. During this period, personalised feedback will be provided to, and discussed with, the smoker along with target-setting and exploration of suitable methods of behaviour change. Personalised feedback will be given via text messages to mobile phones, email messages and through telephone calls. A final home visit will gather data on changes made while some participants (10-20%) will take part in a further qualitative phone interview to gather data on their experience of the intervention.

Study 4. Health effects of SHS exposure in outdoor smoking areas in patients with COPD and asthma (WP5)

This is a clinical research study, led by TobaccoFree Research Institute Ireland, aiming to assess the acute respiratory health effects that result from short-term SHS exposure among patients with asthma and chronic obstructive pulmonary disease (COPD). In many European countries, the introduction of smoke-free laws has prompted the proliferation of outdoor areas where smoking is permitted, and there exist places where non-smokers are still exposed to some levels of SHS. The health effects of such exposures are uncertain as to date there is only anecdotal evidence; some effects can be expected but it may be difficult to demonstrate unless in naturalistic, real-life conditions. This study will aim to involve 60 patients (volunteers) from three European countries: the Czech Republic, Ireland, and Spain (20 patients in each participating country: 10 COPD and 10 asthma patients). The recruitment of such patients will be done with the cooperation of patients' organisations in these countries which are affiliated with the European Lung Foundation. Participants will be trained to keep a diary record of any noted changes and medication usage and perform pre and post-peak flow, spirometry, and carbon monoxide measurements. Such patients will wear personal monitors to continuously measure exposure to particulate matter (PM1, PM2.5, PM10) with continuous geolocalisation monitoring with AirSpeck mobile wireless air quality monitors and a RESpeck monitor to measure breathing rate and depth to detect any acute changes in breathing during or following exposure to SHS at entertainment facilities. These novel measurements will determine the individual level of SHS exposure with spatially-resolved estimation of personal dosage of PM and the identification of acute respiratory effects from such exposure. There is also a recording of each breath sound which can be recognised and matched with time, location and level of exposure with identification of any lags in time that may occur.

Study 5. Impact of short-term second-hand exposure to e-cigarette aerosols (SHA) on the respiratory system (WP6)

This study, led by the Hellenic Cancer Society (Greece), is aimed at characterizing exposure to e-cigarette aerosols among healthy non-smoker volunteers. An experimental study with cross-over design will be implemented in a laboratory. Three trial arms will be performed (no exposure vs. low e-cigarette aerosol exposure vs. high e-cigarette aerosol exposure) that will be differentiated by the e-cigarettes' battery power outputs. The study sample will consist of 40 adult volunteers that will be randomized to the sequence of three exposures to e-cigarette aerosol. In total, 120 person-exposures will take place, leading to 240 preand postmeasurements. Recruitment will take place in Athens (Greece). Exposures will last 30 minutes and will take place in a standardised exposure chamber.99. Kougias M, Vardavas CI, Anagnostopoulos N, et al. The acute effect of cigarette smoking on the respiratory function and FeNO production among young smokers. Exp Lung Res. 2013;39:359-64. Before and after exposure to aerosols originated from e-cigarette use, the lung function of each participant will be assessed through impulse oscillometry to assess respiratory system impedance and resistance, exhaled nitric oxide levels and 8-isoprostane concentration in the exhaled breath condensate as a marker of oxidative stress.1010. Vardavas CI, Anagnostopoulos N, Kougias M, et al. Short-term pulmonary effects of using an electronic cigarette. Chest. 2012;141:1400-6.

Study 6. Second-hand exposure to emissions from electronic cigarettes: personal and environmental assessment in confined spaces (WP8)

This WP, led by the Institut Català d'Oncologia (Spain), comprises three sub-studies to address three complementary objectives. Firstly, a systematic review of the published studies on passive exposure to e-cigarette aerosols will be performed. Secondly, environmental and bystanders' exposure to e-cigarette aerosols in controlled conditions in a car and a room will be investigated through an experimental study which will involve two volunteers exposed to SHA and an e-cigarette user to produce it. Airborne nicotine and PM2.5 will be measured for environmental exposure and nicotine, cotinine and tobacco-specific nitrosamines in saliva for personal exposure assessment. Thirdly, a crosssectional study will be conducted to investigate environmental and bystanders' exposure to SHA in real-life conditions at homes of e-cigarette users, in four European countries (Greece, Italy, Spain, and the UK). Based on the differences detected in a previous pilot study1111. Ballbè M, Martínez-Sánchez JM, Sureda X, et al. Cigarettes vs. e-cigarettes: passive exposure at home measured by means of airborne marker and biomarkers. Environ Res. 2014;135:76-80. and standard assumptions, this study will aim to include 250 participants. Airborne nicotine and PM2.5 will be measured during one week and saliva and urine samples will be collected for the determination of nicotine, cotinine and tobacco-specific nitrosamines. Airborne nicotine samples will be analysed by gas chromatography/mass spectrometry;66. Lopez MJ, Nebot M, Albertini M, et al. Secondhand smoke exposure in hospitality venues in Europe. Environ Health Perspect. 2008;116:1469-72.,1212. Fu M, Valverde A, Ortega G, et al. Exposure to second-hand smoke in primary health care centres in Catalonia, Spain (2006). Environ Res. 2009;109:775-8. while saliva and urine analysis will be performed using high-resolution chromatography/mass spectrometry;1313. Pérez-Ortuño R, Martínez-Sánchez JM, Fu M, et al. Assessment of tobacco specific nitrosamines (TSNAs) in oral fluid as biomarkers of cancer risk: a population-based study. Environ Res. 2016;151:635-41.-1414. Pérez-Ortuño R, Martínez-Sánchez JM, Fernández E, et al. High-throughput wide dynamic range procedure for the simultaneous quantification of nicotine and cotinine in multiple biological matrices using hydrophilic interaction liquid chromatography-tandem mass spectrometry. Anal Bioanal Chem. 2015;407:8463-73. and PM2.5 will be measured by means of an optical portable counter.1515. Fernández E, Ballbè M, Sureda X, et al. Particulate matter from electronic cigarettes and conventional cigarettes: a systematic review and observational study. Curr Environ Heal Reports. 2015;2:423-9.

Study 8. Attributable mortality and morbidity to SHS in Europe (WP9)

The objectives of this WP, led by the Istituto per lo Studio, la Prevenzione e la Rete Oncologica (Italy), are: 1) to review the methods used in the literature, with special focus on Europe, to calculate attributable mortality and morbidity to SHS and the results published to date for EU countries; 2) to develop algorithms of calculation of attributable mortality and morbidity to SHS; and 3) to update attributable mortality and morbidity to SHS for EU countries based on SHS exposure prevalence collected in the WP3.

In order to estimate attributable mortality and morbidity to SHS, mortality and morbidity data (asthma, COPD, lung cancer, stroke, ischaemic heart disease, breast cancer and diabetes in adults; low birth weight, lower respiratory infections, otitis media, asthma and sudden infant death syndrome in children) will be collected from 28 EU countries on SHS-related diseases, along with information on prevalence of SHS exposure in EU countries. For attributable mortality and morbidity estimates, data on the prevalence of SHS exposure will be used from two sources: information collected in the WP3 of this project and from Eurobarometer surveys. Finally, sensitivity analyses of attributable mortality and morbidity to SHS will be conducted.

Study 9: Economic impact of SHS on morbidity and mortality and return on investment of interventions aiming at reducing SHS exposure (WP10)

This study, led by the Universidad Politécnica de Cartagena (Spain), will produce economic models for the analysis of the return on investment of policies aimed at reducing SHS exposure in EU countries. Available return on investment models for smoking cessation interventions (http://www.equipt.eu) will be considered. Nevertheless, these models consider the effects of SHS exposure by assuming that each successful quit contributes a fractional reduction in the disease burden associated with SHS, they do not include policies specifically aimed at reducing SHS other than curbing smoking prevalence. The information on SHS exposure in European countries obtained in the WP3 and the epidemiological evidence on attributable mortality and morbidity to SHS obtained in the WP9 will be combined with data on the cost consequences of disease to obtain country-specific versions of the return on investment models. The models will consider the lag between exposure and effect and therefore will use appropriate shortand medium-term horizons (2, 5, and 10 years) and long-term horizons (20 years and lifetime). With these models, the economic burden caused by SHS exposure and the return on investment of some interventions will be estimated. Different perspectives (health system, overall public sector and wider society) will be adopted. The model outcomes will comprise not only standard cost-effectiveness and cost-utility ratios but also a fully disaggregated list of health outcomes and resource use consequences so that the budgetary impact of implementation at local, regional and national scale will be appraised.

Supportive WP: Instruments' calibration (WP7)

This WP, led by the Fondazione IRCCS Istituto Nazionale dei Tumori (Italy), will investigate the best methods and procedures for real-time measurement of SHS and SHA using optical particle counters. All devices of the project Partners used in WP4, WP5, WP6 and WP8 (Dylos DC1700, SidePak AM150, and AirVisual Pro) will be tested and individually calibrated through comparison with one Beta Attenuation Monitor (BAM-1020).

The Dylos DC1700 is an optical particle counter instrument that counts the small and large particles present in the surrounding environment. The TSI SidePak AM510 Personal Aerosol Monitor is a laser photometer that measures a variety of particle sizes (PM1, PM2.5, PM10). The AirVisual Pro is a low-cost optical particle counter, measuring PM2.5, PM10, carbon dioxide, temperature and relative humidity. All these devices are portable and stationary, capable to operate and memorise the data with or without connection to the internet.

For calibration, comparison of different measurements will be performed by the generation of exposures using a range of cigarettes and e-cigarettes in a real-life environment in a room of 48 m3. The BAM-1020 will be operated and the optical particle counters will be calibrated in parallel for the time necessary to simulate concentration changes in order to verify the accuracy and precision of the instruments within the whole range of measurements specified by the manufacturers and to compensate for coincidence losses.

Conclusion

The TackSHS project involves a comprehensive and innovative approach to develop a scientific understanding of second-hand exposure to smoke from cigarettes and aerosols from e-cigarettes. For the first time, this project will consider the integration of data on SHS exposure from a validated, homogenous survey, as an instrument for the subjectively perceived exposure by wide populations in several EU countries, together with its objective assessment using environmental and biological markers. Whilst this is the core objective of the TackSHS project, additional WPs will address specific questions regarding exposure to SHS and SHA, including its impact on health and its economic burden in specific populations and patients with chronic lung and respiratory diseases.

At the societal level, we aim to raise awareness of the risks from SHS exposure and their associated health burden. The project will also provide new evidence to further inform the debate about the scale of risk from SHA exposure. TackSHS team will also invest considerable effort in disseminating the obtained results, not only to the scientific community, policy makers and stakeholders, but also to patient and consumer organisations at the national and European level.

The initial publication plan includes 20 papers with the main findings, considered as priority publications. Further publications, with results at the country level and combining the results from different studies will be produced after the initial primary publications. In addition, a comprehensive report, as well as policy briefs, will be launched in the final conference and distributed to stakeholders, including policymakers, patients, the scientific community and the general public.

Acknowledgements

We thank Ms. Cristina Rajo, formerly at the Research Support Office of the Catalan Institute of Oncology, for her valuable help throughout the process for the grant application and negotiation. We also thank Ana Navas-Acién, Dan Smith, Armando Peruga and James Repace for accepting being members of the Scientific Advisory Board, and Fèlix Bosch for accepting being the External Ethics Advisor of the project.

In memory of Dr. Manel Nebot (1957-2012) and Dr. Giovanni Invernizzi (1948-2013), whose work and friendship guided us in this and other projects.

Appendix A   Supplementary data

Supplementary data associated with this article can be found, in the online version, at doi:10.1016/j.gaceta.2019.07.002

References

  • 1
    IARC Working Group on the Evaluation of Carcinogenic Risks to Humans. Tobacco smoke and involuntary smoking. Lyon: International Agency for Research on Cancer; 2004. vol. 83
  • 2
    Junker MH, Danuser B, Monn C, et al. Acute sensory responses of nonsmokers at very low environmental tobacco smoke concentrations in controlled laboratory settings. Environ Health Perspect. 2001;109:1045-52.
  • 3
    Oberg M, Jaakkola MS, Woodward A, et al. Worldwide burden of disease from exposure to second-hand smoke: a retrospective analysis of data from 192 countries. Lancet. 2011;377:139-46.
  • 4
    Chapman S. E-cigarettes: the best and the worst case scenarios for public health an essay by Simon Chapman. BMJ. 2014;349:g5512.
  • 5
    Glasser AM, Collins L, Pearson JL, et al. Overview of electronic nicotine delivery systems: a systematic review. Am J Prev Med. 2017;52:e33-66.
  • 6
    Lopez MJ, Nebot M, Albertini M, et al. Secondhand smoke exposure in hospitality venues in Europe. Environ Health Perspect. 2008;116:1469-72.
  • 7
    Gallus S, Lugo A, La Vecchia C, et al. Pricing Policies and Control of Tobacco in Europe (PPACTE) project. Eur J Cancer Prev. 2014;23:177-85.
  • 8
    Semple S, Apsley A, Azmina Ibrahim T, et al. Fine particulate matter concentrations in smoking households: just how much secondhand smoke do you breathe in if you live with a smoker who smokes indoors? Tob Control. 2015;24:e205-11.
  • 9
    Kougias M, Vardavas CI, Anagnostopoulos N, et al. The acute effect of cigarette smoking on the respiratory function and FeNO production among young smokers. Exp Lung Res. 2013;39:359-64.
  • 10
    Vardavas CI, Anagnostopoulos N, Kougias M, et al. Short-term pulmonary effects of using an electronic cigarette. Chest. 2012;141:1400-6.
  • 11
    Ballbè M, Martínez-Sánchez JM, Sureda X, et al. Cigarettes vs. e-cigarettes: passive exposure at home measured by means of airborne marker and biomarkers. Environ Res. 2014;135:76-80.
  • 12
    Fu M, Valverde A, Ortega G, et al. Exposure to second-hand smoke in primary health care centres in Catalonia, Spain (2006). Environ Res. 2009;109:775-8.
  • 13
    Pérez-Ortuño R, Martínez-Sánchez JM, Fu M, et al. Assessment of tobacco specific nitrosamines (TSNAs) in oral fluid as biomarkers of cancer risk: a population-based study. Environ Res. 2016;151:635-41.
  • 14
    Pérez-Ortuño R, Martínez-Sánchez JM, Fernández E, et al. High-throughput wide dynamic range procedure for the simultaneous quantification of nicotine and cotinine in multiple biological matrices using hydrophilic interaction liquid chromatography-tandem mass spectrometry. Anal Bioanal Chem. 2015;407:8463-73.
  • 15
    Fernández E, Ballbè M, Sureda X, et al. Particulate matter from electronic cigarettes and conventional cigarettes: a systematic review and observational study. Curr Environ Heal Reports. 2015;2:423-9.

  • The TackSHS project investigators: Catalan Institute of Oncology (ICO), Bellvitge Biomedical Research Institute (IDIBELL), Spain: Esteve Fernández, Yolanda Castellano, Marcela Fu, Montse Ballbè, Beladenta Amalia, Olena Tigova; Public Health Agency of Barcelona (ASPB), Spain: María José López, Xavier Continente, Teresa Arechávala, Elisabet Henderson; Istituto di Ricerche Farmacologiche Mario Negri IRCCS (IRFMN), Italy: Silvano Gallus, Alessandra Lugo, Xiaoqiu Liu, Cristina Bosetti, Enrico Davoli; Istituto DOXA, Worldwide Independent Network/Gallup International Association, Italy: Paolo Colombo; University of Stirling (UNISTIR), UK: Sean Semple, Rachel O'Donnell, Ruaraidh Dobson; TobaccoFree Research Institute Ireland (TFRI), Ireland: Luke Clancy, Sheila Keogan, Shashsa Li, Elizabeth Breslin, Hannah Byrne; Hellenic Cancer Society George D. Behrakis Research Lab (HCS), Greece: Panagiotis Behrakis, Anna Tzortzi, Constantine Vardavas, Vergina Konstantina Vyzikidou, Stephanie Teloniatis, Gerasimos Bakelas, George Mattiampa; Fondazione IRCCS Istituto Nazionale dei Tumori (INT), Italy: Roberto Boffi, Ario Ruprecht, Cinzia De Marco, Alessandro Borgini, Chiara Veronese, Martina Bertoldi, Andrea Tittarelli; Istituto per lo Studio, la Prevenzione, e la Rete Oncologica (ISPRO), Italy: Giuseppe Gorini, Giulia Carreras, Barbara Cortini, Simona Verdi, Alessio Lachi, Elisabetta Chellini; Polytechnic University of Cartagena (UPCT), Spain: Ángel López Nicolás, Marta Trapero-Bertran, Daniel Celdrán Guerrero; European Network on Smoking and Tobacco Prevention (ENSP), Belgium: Cornel Radu-Loghin, Dominick Nguyen, Polina Starchenko; Fundación para la Investigación Biomédica del Hospital Universitario La Princesa (IISP), Spain: Joan B. Soriano, Julio Ancochea, Tamara Alonso, María Teresa Pastor, Marta Erro, Ana Roca, Patricia Pérez.
  • Funding

    This project has received funding from the European Union Horizon 2020 research and innovation programme under grant agreement No 681040. The Tobacco Control Unit (ICO) is partially supported by the Ministry of Universities and Research, Government of Catalonia (2017SGR139). E. Fernández was partially supported by the Instituto de Salud Carlos III, Government of Spain (INT16/00211 and INT17/00103), co-funded by the European Regional Development Fund (FEDER). A. Lugo was supported by an AIRC fellowship for Italy. The work of S. Gallus was partially funded by the Italian League Against Cancer (LILT, Milan).

Publication Dates

  • Publication in this collection
    19 June 2020
  • Date of issue
    Jan-Feb 2020

History

  • Received
    28 June 2019
  • Accepted
    08 July 2019
  • Published
    23 Sept 2019
Sociedad Española de Salud Pública y Administración Sanitaria (SESPAS) Barcelona - Barcelona - Spain
E-mail: gs@elsevier.com