Evaluating the Effectiveness of France’s Indoor Smoke-Free Law 1 Year and 5 Years after Implementation: Findings from the ITC France Survey

Geoffrey T. Fong; Lorraine V. Craig; Romain Guignard; Gera E. Nagelhout; Megan K. Tait; Pete Driezen; Ryan David Kennedy; Christian Boudreau; Jean-Louis Wilquin; Antoine Deutsch; François Beck

doi:10.1371/journal.pone.0066692

Abstract

France implemented a comprehensive smoke-free law in two phases: Phase 1 (February 2007) banned smoking in workplaces, shopping centres, airports, train stations, hospitals, and schools; Phase 2 (January 2008) banned smoking in hospitality venues (bars, restaurants, hotels, casinos, nightclubs). This paper evaluates France’s smoke-free law based on the International Tobacco Control Policy Evaluation Project in France (the ITC France Project), which conducted a cohort survey of approximately 1,500 smokers and 500 non-smokers before the implementation of the laws (Wave 1) and two waves after the implementation (Waves 2 and 3). Results show that the smoke-free law led to a very significant and near-total elimination of observed smoking in key venues such as bars (from 94–97% to 4%) and restaurants (from 60–71% to 2–3%) at Wave 2, which was sustained four years later (6–8% in bars; 1–2% in restaurants). The reduction in self-reported smoking by smoking respondents was nearly identical to the effects shown in observed smoking. Observed smoking in workplaces declined significantly after the law (from 41–48% to 18–20%), which continued to decline at Wave 3 (to 14–15%). Support for the smoke-free laws increased significantly after their implementation and continued to increase at Wave 3 (p<.001 among smokers for bars and restaurants; p<.001 among smokers and p = .003 for non-smokers for workplaces). The findings demonstrate that smoke-free policies that are implemented in ways consistent with the Guidelines for Article 8 of the WHO Framework Convention on Tobacco Control (WHO FCTC) lead to substantial and sustained reductions in indoor smoking while also leading to high levels of support by the public. Moreover, contrary to arguments by opponents of smoke-free laws, smoking in the home did not increase after the law was implemented and prevalence of smoke-free homes among smokers increased from 23.2% before the law to 37.2% 5 years after the law.

Citation: Fong GT, Craig LV, Guignard R, Nagelhout GE, Tait MK, Driezen P, et al. (2013) Evaluating the Effectiveness of France’s Indoor Smoke-Free Law 1 Year and 5 Years after Implementation: Findings from the ITC France Survey. PLoS ONE 8(6): e66692. https://doi.org/10.1371/journal.pone.0066692

Editor: Chris Bullen, The University of Auckland, New Zealand

Received: February 4, 2013; Accepted: May 8, 2013; Published: June 21, 2013

Copyright: © 2013 Fong et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: Funding for this study was provided by l’Institut national de prévention et d’éducation pour la santé (Inpes), l’Institut national du cancer (INCa), the U.S. National Cancer Institute (P01 CA138389); Canadian Institutes of Health Research (79551 and 115216); and the Ontario Institute for Cancer Research. G.T.F. was supported by a Senior Investigator Award from the Ontario Institute for Cancer Research and a Prevention Scientist Award from the Canadian Cancer Society Research Institute. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

The public health harms associated with exposure to second-hand smoke have been well documented including premature death, lung cancer, heart disease, and coronary obstructive pulmonary disease (COPD) [1]–[4]. Comprehensive smoke-free laws, if well-designed and implemented with strong enforcement measures, have been shown to greatly reduce or eliminate second-hand smoke in public venues [5]–[8]. Article 8 of the WHO Framework Convention on Tobacco Control (FCTC), which France ratified in 2004, obligates Parties to adopt effective measures to provide protection from exposure to second-hand smoke. Guidelines for Article 8 recognize the importance of monitoring and evaluation of smoke-free policies including assessing support for smoke-free policies and enforcement of and compliance with smoke-free policies [9].

Smoke-free policies were implemented in two phases in France. Phase 1 was implemented in February 2007 in workplaces, shopping centres, airports, train stations, hospitals, and schools. In January 2008, the ban was extended in Phase 2 to hospitality venues (cafés, bars, restaurants, hotels, casinos, and nightclubs). Media campaigns were held in France prior to the launch of each phase of the ban to inform the public about the forthcoming policies and to provide education about the health effects associated with exposure to second-hand smoke.

The International Tobacco Control Policy Evaluation Project in France (the ITC France Project) was created in 2006 to evaluate France’s smoke-free legislation as well as other tobacco control policies implemented under the FCTC including health warning labels, price and taxation policies, tobacco advertising and promotion bans, cessation strategies, and education campaigns [10]. The ITC France Project is part of the International Tobacco Control Policy Evaluation Project (the ITC Project) – an international research collaboration across more than 20 countries whose primary objective is to evaluate the psychosocial and behavioural effects of FCTC policies. The ITC Project is conducting large-scale prospective cohort surveys of tobacco users and non-users in countries inhabited by more than half of the world’s smokers [11]–[13]. For description of the conceptual model and objectives of the ITC Project, see Fong et al. (2006) [14]; for description of the survey methods, see Thompson et al. (2006) [15].

Three waves of a cohort survey of a nationally representative sample of smokers and non-smokers living in continental France have been completed between 2006 and 2012. The ITC France Wave 1 Survey was conducted just before the Phase 1 smoking ban was implemented in workplaces and other public venues in February 2007. The cohort was recontacted for the Wave 2 Survey after Phase 2 of the smoking ban. The Wave 3 Survey was conducted approximately 5 years after the ban in hospitality venues and 6 years after the workplace ban to provide an evaluation of the longer term impacts of the smoking ban and other policies.

The effectiveness of the smoking ban in France has been reported in the literature based on ITC France Wave 1 (pre-ban) and Wave 2 (post-ban) data [16]–[18]. However, the long-term effectiveness of smoke-free legislation in France has not yet been reported. Moreover, the post-ban effects from the perspective of non-smokers have not been reported before, as other studies have compared France with other countries that did not include a sample of non-smokers in their ITC Survey [16]–[17]. Long-term evaluations of smoke-free legislation in other European countries have largely focused on measuring second-hand smoke levels [19]–[20]. Cross-sectional population-based surveys have assessed the short- and medium-term effects of smoke-free legislation and support for future smoke-free policies [21]–[23].

This paper reports the results of the ITC France Survey evaluation of the 2007–2008 smoking ban across a variety of indoor public venues at one pre-implementation and two post-implementation time points. We report the impact of the ban on observed smoking and self-reported smoking behaviour in workplaces, restaurants, and bars and pubs; public support for comprehensive smoking bans in several public places; and the prevalence of smoking restrictions at home.

Methods

Ethics Statement

Prospective respondents were contacted via telephone (see below) and information was provided by the interviewer using a script built into the computer assisted telephone interview (CATI) program regarding the topic of the survey, the research institutions involved; prospective respondents were informed that all responses would be confidential. Respondents gave their consent verbally and the CATI script required the interviewer to enter the consent in the computer program before proceeding to the survey. As typical of telephone surveys, written consent was not obtained. However, prior to beginning the survey, the respondent was informed that he/she was free to decline to answer any question, and to terminate the survey at any time. The respondent was asked whether he/she could complete the survey at this time or at another more convenient time. All respondents were mailed compensation of a 10€ cheque (smokers for the 50-minute interview) or 8€ (non-smokers for the 30-minute interview) by mail after the survey interview (this was increased to 20€ at Wave 2 and Wave 3). Because of the cohort design, at Wave 2 and Wave 3, we recontacted all respondents from the previous wave by mail to inform them that they would be contacted by phone in the near future to invite them to participate in the next wave of the survey. When reached by phone, these recontact respondents were again read the information and consent script, and verbal consent was again obtained. The survey and research protocol was reviewed and cleared for ethics at each of the three survey waves by the Human Research Ethics Committee at the University of Waterloo, which waived the need for written informed consent from the participants.

Respondents and Design

The ITC France Survey is a national longitudinal survey of adult (≥18 years of age) smokers and non-smokers. Smokers are those who have smoked more than 100 cigarettes in their life and smoke at least monthly. The CATI survey follows a random digit dialing (RDD) sampling design and covers continental France. To compensate for respondents lost to attrition, new respondents were randomly selected at Waves 2 and 3 using the same RDD sampling design and interview protocol as in Wave 1.

The questions used in the ITC France Survey were all adapted from the conceptual model and questionnaire of the ITC Four Country Survey.¹⁴ The process for translation of the English survey into French was guided by the translation protocol described by International Agency for Research on Cancer (IARC) which calls for discussion of translation among bilingual persons knowledgeable about the survey content.¹² The ITC France team researchers in Paris met this qualification.

Wave 1 of the ITC France Survey was conducted by the survey firm Atoo between December 2006 and February 2007 with a cooperation rate of 75.3%. Wave 2 was conducted from September to November 2008 by the Institut de sondage Lavialle (ISL). Wave 3 was conducted from September to December 2012 by the firm BVA. The complete survey methodology can be found on the ITC Project website [24].

Variables

Observed smoking in bars and restaurants was measured among those who had visited in the last 6 months with the questions “The last time you visited, were people smoking inside the café, bar or pub/restaurant?”. The response options were “yes/no”. Smoking behaviour in bars and restaurants was assessed with the question “Did you smoke at all at the bar/restaurant during your last visit, either indoors or outdoors?” Respondents who answered “yes” were asked whether they smoked inside the bar/restaurant, outside, or both.

Observed smoking in workplaces was measured among those who were employed outside the home in indoor workplaces with the question “In the last 30 days, have people smoked in indoor areas where you work?”. The response options were “yes/no”. Smoking behaviour in workplaces was measured with the question “In the last 30 days, have you smoked in indoor areas at work?” (yes/no).

Support for smoke-free law in bars and restaurants was assessed with the question “Do you support or oppose the French total ban on smoking inside cafés, bars and pubs/restaurants?” with options “strongly support/support/oppose/strongly oppose”. Support for a smoke-free law in cars with children was assessed with the question “Do you support or oppose a French total ban on smoking in cars with children with them?” with the same response options. Support for bans in other places was assessed with the question “For each of the following public places, please tell me if you think smoking should be allowed in all indoor areas, only in some indoor areas, or not allowed indoors at all.” Overall support for the smoking ban was measured with “Overall, would you say that the ban on smoking in restaurants, cafés and bars, and other public places is a good thing or a bad thing?” (very bad/bad/good/very good). Support for a ban in outdoor eating areas of restaurants was measured with the question “Do you think that smoking should be allowed in all outdoor eating areas, in designated outdoor eating areas such as smoking terraces, or not allowed in outdoor eating areas at all?” (yes/no). Support for a ban on smoking in cars with children was measured with “Do you support or oppose a French total ban on smoking in cars with children in them?”(strongly support/support/oppose/strongly oppose). Home smoking bans were measured with “Which of the following best describes smoking inside your home?” (anywhere inside/some rooms/never allowed anywhere/not allowed except under special circumstances).

Analyses

Sampling weights were rescaled to population totals based on the prevalence of smoking in France. These inflated weights were then rescaled to the total number of smokers and non-smokers in the sample. Logistic regression models for longitudinal data (generalized estimating equations or GEE) were used to analyze differences in the measure of interest across waves. An unstructured within-group correlation matrix was used in the modeling to account for within-subject correlation. All of the models simultaneously controlled for gender, age at recruitment (categorized as 18–24, 25–39, 40–55, and 55+), wave, and smoking status (smoker vs. non-smoker). It has been documented that respondents who are newly recruited may vary in their responses compared to those who have completed one prior wave, who may vary from those who have completed two prior waves, and so on [25]–[27]. This variation in responses has been found in the ITC Surveys as well [28]. Therefore, time-in-sample, the number of times a respondent has participated in the survey, was also included in all of the models as a time-varying quantity over time to adjust for time-in-sample effects. An interaction term between wave and smoking status was also included in order to obtain separate model-based estimates for smokers and non-smokers adjusted for the covariates listed above. All p-values provided are adjusted for multiple comparisons using the Benjamini and Hochberg (1995) [29] method. Models were initially conducted including former smokers as an additional smoking status group; it was found that the responses of former smokers did not significantly differ from those of smokers. Thus, for all analyses presented here, former smokers were grouped with smokers. All analyses were run in SAS 9.2.

Results

A total of 2260 (1735 smokers and 525 non-smokers) respondents completed Wave 1 of the ITC France Survey. A total of 2219 (1540 smokers, 164 former smokers, and 515 non-smokers) respondents completed Wave 2. Of these 2219 respondents, 1231 were from the cohort smoker sample and 414 were from the cohort non-smoker sample, resulting in an overall retention rate of 72.8%. The Wave 2 replenishment sample consisted of 473 smokers and 101 non-smokers. The cooperation rate among the Wave 2 replenishment sample was 80.5%. At Wave 3, a total of 2204 (1420 smokers, 297 former smokers, and 487 non-smokers) completed the ITC France Survey. Of these 2204 respondents, 1198 were from the cohort smoker sample and 390 were from the cohort non-smoker sample, which included 17 respondents who were non-smokers at Wave 2 and became smokers at Wave 3. There were 502 smokers and 114 non-smokers in the Wave 3 replenishment sample. The cooperation rate among the Wave 3 replenishment sample was 80.7%.The overall retention rate at Wave 3 was 71.6%. Note that 95% confidence intervals are presented in parentheses throughout the results.

Observed Smoking and Smoking Behaviour in Key Venues

Restaurants.

Among smokers, observed smoking in restaurants declined from 70.8% (63.1–77.5) before the law (Wave 1) to 2.0% (1.2–3.4) at first post-ban survey (Wave 2)reported by smokers and reported by non-smokers), 8 months after the law was implemented (p<.001). Observed smoking in restaurants among non-smokers also declined from 60.4% (50.8–69.3) at Wave 1 to 3.0% (1.4–6.2) at Wave 2 (p<.001). This very low prevalence of restaurants with smoking was sustained at the second post-ban survey (Wave 3) to 0.7% (0.4–1.4) among smokers and 2.1% (0.9–4.8) among non-smokers); this decline among smokers (from 2.0% (1.2–3.4) to 0.7% (0.4–1.4)) was statistically significant (p = .040). The slight decline from 3.0% (1.4–6.2) to 2.1% (0.9–4.8) among non-smokers was not statistically significant (p = .550).

These findings are presented in Figure 1.

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Figure 1. Noticing smoking inside restaurants.

Percentage of smokers and non-smokers who noticed smoking inside restaurants among those who have visited these venues in the last 6 months, by wave.

https://doi.org/10.1371/journal.pone.0066692.g001

We also examined self-reported smoking behaviour in restaurants. At Wave 1, 76.0% (67.4–82.9) of smokers smoked indoors or indoors and outdoors in a restaurant at last visit. This percentage decreased to 1.4% (0.7–3.0) at Wave 2 (p<.001) and was sustained at Wave 3 to 1.8% (1.0–3.4) (p = .622).

Bars.

Observed smoking in bars declined from 96.6% (95.1–97.7) at Wave 1 to only 3.5% (2.4–5.0) at Wave 2 among smokers (p<.001). Among non-smokers, observed smoking in bars also declined from 93.5% (90.0–95.8) at Wave 1 to 4.4% (2.5–7.6) at Wave 2 (p<.001). The prevalence of observed smoking in bars at Wave 3 slightly increased to 6.4% (4.9–8.4) for smokers and 7.9% (4.8–12.7) for non-smokers. This slight increase was significant among smokers (p = 0.024), but not significant among non-smokers (p = .161).

These findings are presented in Figure 2.

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Figure 2. Noticing smoking inside bars, pubs, and cafés.

Percentage of smokers and non-smokers who noticed smoking inside bars, pubs, and cafés among those who have visited these venues in the last 6 months, by wave.

https://doi.org/10.1371/journal.pone.0066692.g002

Our analysis of self-reported smoking in bars found that at Wave 1, 95.5% (93.4–96.9) of smokers smoked inside or inside and outside a bar at last visit. This percentage decreased to 1.8% (1.0–3.2) at Wave 2 (p<.001). At Wave 3, 6.4% (4.5–9.2) of smokers reported smoking inside or outside a bar at last visit. This was significantly different from Wave 2 (p<.001) and Wave 1 (p<.001).

Workplaces.

Observed smoking in workplaces also declined significantly from 47.8% (42.9–52.8) for smokers and 41.1% (33.9–48.7) for non-smokers at Wave 1 to 20.0% (16.9–23.6) and 17.9% (13.2–23.9), respectively, at Wave 2 (p<.001 for both smokers and non-smokers). There was a further decline at Wave 3 to 14.5% (11.7–17.7) among smokers and 13.5% (9.1–19.6) among non-smokers, however the slight decrease was not significant for smokers (p = .056) and non-smokers (p = .340). The sample used in the analysis of observed smoking in the workplace included respondents who reported that smoking is never allowed in any indoor area, smoking is allowed in some inside areas (i.e., designated smoking rooms), and smoking is allowed in any indoor area. The presence of designated smoking rooms is a possible confounder, thus we also examined observed smoking in workplaces among those respondents who reported that smoking was not allowed in any indoor area of their workplace. For these workplaces, observed smoking also declined significantly from 18.6% (14.3–24.0) for smokers and 21.6% (14.2–31.5) for non-smokers at Wave 1 to 12.0% (9.5–15.0) and 9.7% (6.1–15.0), respectively, at Wave 2 (p = .023 for smokers; p = .019 for non-smokers). The slight decline at Wave 3 to 6.7% (4.9–9.1) among smokers was significant (p = .019), however the decline to 6.0% (3.2–10.7) among non-smokers was not significant (p = .352). These findings are presented in Figure 3. It should be noted that although the prevalence of smoking in workplaces is higher than the prevalence of smoking in public venues (e.g., restaurants, bars), the question for workplaces asked whether there was any smoking in the past 30 days, whereas the question for restaurants, bars, and other public places asked whether there was any smoking at last visit. It would be expected that the prevalences would be higher for workplaces all things equal because of the longer catchment period.

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Figure 3. Noticing smoking at the workplace.

Percentage of smokers and non-smokers who noticed smoking at the workplace in the last 30 days among those who reported that smoking is not allowed in any indoor area of their workplace, by wave.

https://doi.org/10.1371/journal.pone.0066692.g003

The analysis of self-reported smoking indoors in workplaces showed a similar trend. At Wave 1 39.6% (34.5–45.0) of smokers who worked outside the home in indoor workplaces smoked indoors regardless of their workplace smoking policy. This decreased to 14.1% (11.2–17.6) at Wave 2 (p<.001) and 11.8% (9.1–15.2) (p = .339) at Wave 3. Among those who reported a complete indoor workplace smoking ban at each wave, indoor smoking prevalence was low at Wave 1 (7.0% (4.5–10.8)) and decreased further at Wave 2 (4.6% (3.1–6.9)) and Wave 3 (3.3% (2.0–5.4)). However, the reductions at Wave 3 were not significant compared to Wave 1 (p = .104).