COPD-related morbidity and mortality after smoking cessation: status of the evidence

N. S. Godtfredsen, T. H. Lam, T. T. Hansel, M. E. Leon, N. Gray, C. Dresler, D. M. Burns, E. Prescott, J. Vestbo
European Respiratory Journal 2008 32: 844-853; DOI: 10.1183/09031936.00160007

Abstract

The evidence base for the benefit of quitting smoking as regards morbidity and mortality outcomes in patients with moderate-to-severe chronic obstructive pulmonary disease (COPD) is limited.

The present article is a review of the existing literature. A systematic literature search in medical databases was performed until March 2006, and subsequently until September 1, 2007. The outcomes examined were COPD-related morbidity and mortality (including all-cause mortality) in COPD patients in connection with smoking cessation.

A total of 21 and 27 published articles on morbidity and mortality, respectively, were identified and reviewed. For both outcomes, only a few of the studies included patients with severe COPD. Most of the studies reported a beneficial effect of smoking cessation compared with continued smoking, whereas a few found no improvement. Methodological problems, including small study sizes, poor data quality, possibility of reverse causality and incomplete ascertainment of cause of death, limit interpretation of some of the studies.

The evidence as a whole supports the conclusion that, even in severe chronic obstructive pulmonary disease, smoking cessation slows the accelerated rate of lung function decline and improves survival compared with continued smoking.

Chronic obstructive pulmonary disease (COPD), which is considered an inflammatory disease with pulmonary and systemic components, is predominantly found in patients with a history of cigarette smoking and has an enormous and increasing global health impact 1. According to the World Health Organization (WHO), ∼80 million people worldwide have moderate-to-severe COPD. In 2005, three million deaths due to the disease were reported, and the WHO predicts that, by the year 2030, COPD will have become the third leading cause of death 2. Previously, COPD has been regarded as a progressive irreversible disease with a poor prognosis, but, in the current international guidelines (Global Initiative for Chronic Obstructive Lung Disease (GOLD) and American Thoracic Society/European Respiratory Society), COPD is defined as a modifiable and treatable disease 3, 4. Nevertheless, apart from long-term oxygen treatment in COPD patients with severe hypoxaemia and smoking cessation in patients with mild-to-moderate lung function impairment, to date, no treatment has convincingly been able to influence the accelerated lung function decline or increased mortality characterising this disease 5.

The effect of smoking cessation on outcomes, such as respiratory symptoms, lung function, airway hyperresponsiveness and inflammation, has recently been reviewed 6.

The clinical course of COPD, determined as a continuous excessive loss of ventilatory capacity, is an important and well-established outcome measure. The long-term benefit of sustained and, to a lesser extent, intermittent smoking cessation as regards forced expiratory volume in one second (FEV1) in patients with mild-to-moderate COPD has been convincingly demonstrated in the Lung Health Study (LHS) 79. At the 11-yr follow-up, 38% of the continuing smokers had an FEV1 of <60% of the predicted normal value compared to 10% of sustained quitters 8. However, for patients with clinically significant disease, i.e. usually severe COPD, the impact of quitting smoking on health-related outcomes, such as hospital admission due to exacerbations with or without respiratory infection or mortality due to COPD, has not been thoroughly examined. The US Surgeon General’s Report from 1990 on the health benefits of smoking cessation evaluated the effect of smoking cessation on FEV1 decline and COPD mortality in the general population and COPD patients 10. At that time, however, there were only three published studies assessing smoking cessation and FEV1 decline in COPD patients, and a further three studies of mortality among COPD patients.

The aim of the present review is to present and discuss the currently available evidence of reduced risk of COPD-related morbidity and mortality following smoking cessation. Given the large differences in both the tobacco epidemic and the natural history of COPD between Western countries and Asia, results from the four Chinese cohort studies that examined the effect of quitting smoking on all-cause mortality and mortality due to COPD are also presented.

MATERIALS AND METHODS

The present review is based on a contribution to the International Agency for Research on Cancer’s 11th Handbook of Cancer Prevention, the first in a series on Tobacco Control entitled Reversal of Risk After Quitting Smoking 11. An international working group of experts met in Lyon (France) in March 2006 to revise earlier drafts, discuss and form conclusions concerning the effects of quitting smoking on the risk of developing COPD, cardiovascular disease and cancer. A systematic literature search was performed until March 12, 2006 in PubMed, EMBASE and personal databases for articles in English containing the following keywords: COPD, smoking cessation, quitting smoking, ex-smoking, former smoking, mortality, death, morbidity, hospitalisation, health status, prognosis, and lung function (including decline in FEV1). Additional searches were performed regularly until September 1, 2007, and a few further studies were identified from the reference lists of the included articles.

Study limitations

For the present review, only concrete end-points, such as FEV1 decline, hospital admission due to COPD exacerbation, all-cause mortality and mortality due to COPD, were chosen. A number of studies with identical outcomes were, however, not readily comparable for a variety of reasons.

For instance, it seems fair to state that many of the early studies of smoking cessation did not control adequately for smoking habits, i.e. they did not calculate cumulative exposure in terms of pack-years or measure duration of smoking or time since smoking cessation. Regarding the studies with a morbidity outcome, it is worth noting that negative results (no effect of smoking cessation) only occurred in the few studies that were cross-sectional or had the shortest duration of follow-up. However, in the majority of studies, measuring an absolute decrease in lung function expressed as annual loss in millilitres, the internal validity was intact, whereas the decline rate could not be compared across studies. In the studies with a mortality outcome, the problems with a short follow-up became even more crucial since reverse causality (increased mortality due to quitting smoking in response to pre-existing illness) was introduced. This was evident in the Chinese studies, in which the additional fact that the smoking attributable risk of COPD is not as large as in Western countries seemed to play a role in the results. Furthermore, in these types of research, clinical trials can be subject to selection bias and population-based studies imply a risk of residual confounding, i.e. differences between ex-smokers and continuing smokers in baseline risk of study outcome. These issues are discussed further in the Discussion section.

RESULTS

Morbidity

A total of 21 articles (17 studies) on either COPD patients or subjects with airway obstruction not attributed to asthma were identified 8, 1231. The outcomes examined were FEV1 decline, hospitalisation due to COPD and self-reported respiratory illness. All of the studies are listed in table 1, with comments where necessary. Where applicable, the percentage reduction in FEV1 decline in ex-smokers compared with continuing smokers is displayed in figure 1.

Fig. 1—
Fig. 1—

Forced expiratory volume in one second (FEV1) decline expressed as a percentage of the decline in 100% of continuing smokers in those studies for which this measure was available. All but one of these studies show a relative reduction in FEV1 decline.

View this table:
Table 1—

Effects of smoking cessation on chronic obstructive pulmonary disease(COPD) morbidity

Clinically based studies

In the 1990 US Surgeon General’s report, only three studies concerning the effect of smoking cessation on FEV1 decline in patients with established COPD were evaluated 1214. Postma et al. 14 studied a group of 81 patients with moderate-to-severe COPD followed for 2–21 yrs. The 22 patients who stopped smoking at enrolment or during the study experienced a change (Δ) in FEV1 of -49±7 mL·yr−1, which is faster than the mean decline in never-smokers in the general population, whereas the sustained smokers declined with a ΔFEV1 of -85±5 mL·yr−1. Another study followed 56 males with emphysema for 3–13 yrs in order to assess ΔFEV1 in smokers and ex-smokers 13. Of the 19 ex-smokers, two-thirds had stopped smoking <2 yrs before study entry. Duration of smoking and cumulative tobacco consumption were equal in the two groups. ΔFEV1 was -15±6.7 mL·yr−1 in the ex-smokers and -57.7±6.0 mL·yr−1 in the continuing smokers. In contrast, the Intermittent Positive-Pressure Breathing (IPPB) Trial did not find any differences in FEV1 decline between ex- and current smokers in a group of 985 patients with moderate-to-severe COPD 12.

Fletcher and Peto 15 stratified their sample comprising 792 working males according to presence of mild airway obstruction, and found ΔFEV1 values of -37, -62 and -80 mL·yr−1 in quitters, light smokers and heavy smokers, respectively. In a small smoking cessation trial lasting 30 months, Buist et al. 16 found that subjects with impaired lung function at baseline showed greater improvement in percentage predicted FEV1 following smoking cessation than subjects with normal lung function at baseline. However, this analysis was based on only seven participants, and possible asthma was not ruled out (data not shown in table 1).

Since the 1990 report, only a few additional studies in clinical settings have emerged. In the LHS, a landmark study of smoking cessation in mild-to-moderate COPD, there was no difference between the quitters and continuing smokers with respect to hospitalisation due to respiratory disease 17. The authors attributed this result to the short follow-up and the few cases of hospital admission due to a respiratory condition. However, an earlier article from the same study reported that, compared with current smokers, ex-smokers exhibited fewer episodes of self-reported lower respiratory tract illness, and that the rate of FEV1 decline was negatively affected by lower respiratory tract illness in smokers alone 18. Recently, a prospective study from Crete in a group of elderly outpatients with moderate-to-severe COPD found accelerated FEV1 decline in the 44 continuing smokers compared with the 58 ex-smokers 19. A further two studies have assessed smoking habits and risk of hospital admission for COPD exacerbation. A French study of 64 patients with moderate-to-severe COPD found, on univariate analysis, that the risk of hospital admission for an exacerbation of COPD did not differ between ex- and current smokers 20. In a case–control design, the Risk Factors of COPD Exacerbation Study (EFRAM) found that current smoking was negatively associated with hospitalisation compared to ex-smoking 21, an unexpected finding, which the authors interpreted as a probable ill-quitter (smokers who quit because they become ill) effect.

Population-based studies

In the Honolulu Heart Program, separate analyses were performed in 216 males with impaired lung function, determined to either be in the lowest baseline FEV1 tertile or have a low z-score 22. The 17 males who quit within the first 2 yrs of the 6-yr study exhibited a slower decline in FEV1 than those who continued to smoke (ΔFEV1 -1.8 versus -31.4 mL·yr−1), whereas this was not the case in the 47 males who quit 0–4 yrs before follow-up (ΔFEV1 -25.1 versus -31.4 mL·yr−1). The study also indicated that participants in the lower or middle FEV1 tertile benefited more from quitting than those with the best lung function. More recently, the 30-yr follow-up data from the Finnish cohorts of the Seven Countries Study confirmed that quitting smoking during the study was associated with a slower FEV1 decline across all FEV1 tertiles compared with continuing smokers 23. A recently published paper from the Obstructive Lung Disease in Northern Sweden (OLIN) studies analysed FEV1 decline in a cohort with respiratory symptoms 24. Lung function decline in persistent ex-smokers did not differ significantly from that in never-smokers, but male quitters, re-starters and persistent smokers of both sexes showed a faster decline and at a mutually similar rate.

The Atherosclerosis Risk in Communities study analysed risk factors for and outcomes of rapid FEV1 decline in a large cohort from the USA 25. Current smokers showed a greater risk of rapid decline at the 3-yr spirometric follow-up compared with never-smokers, whereas former smokers showed the same risk as never-smokers. The authors repeated the analysis in another smaller cohort aged ≥65 yrs and found similar results (data not shown in table 1) 26. Conversely, the University of California at Los Angeles study did not find any difference in FEV1 decline between male quitters and continuing smokers with airflow obstruction, but female quitters with obstruction exhibited a slower decline than continuing smokers 27. However, it is not clear whether this subset analysis was controlled for cumulative tobacco exposure. The same trend was found among males and females in the lowest FEV1/forced vital capacity (FVC) quartile in the Tucson study, which had a longer duration of follow-up, but, again, the level of adjustment in the statistical models was not explicit 28.

A study from Copenhagen (Denmark) pooling three population-based studies analysed changes in smoking habit and risk of a first hospital admission due to COPD and found a gradient of relative risk (RR) with increasing tobacco exposure 29. Compared with continuing smokers, the RR estimates were 0.30 (95% confidence interval 0.18–0.50) for ex-smokers prior to study entry, 0.40 (0.29–0.55) for those smoking <15 cigarettes·day−1 at baseline who quit during the study and 0.66 (0.47–0.93) for those smoking >15 cigarettes·day−1 at baseline who quit during the study. Smokers belonging to the lowest FEV1 tertile also benefited from quitting smoking. Recently, other results from the OLIN studies (data not shown in table 1) and the Copenhagen City Heart Study confirmed that the risk of acquiring COPD according to either British Thoracic Society or GOLD criteria decreased with increasing time since smoking cessation 30, 31.

Mortality

The present review identified 27 articles (24 studies) on smoking habits and mortality 12, 17, 3256, of which only six included exclusively subjects with COPD. The studies are listed in table 2. Figure 2 displays the RR of mortality due to COPD in ex-smokers compared with continuing smokers, and figure 3 shows the risk of all-cause mortality in ex-smokers compared with persistent smokers.

Fig. 2—
Fig. 2—

Relative risk (RR)/hazard ratio (HR)/mortality rate (MR) ratio of mortality due to chronic obstructive pulmonary disease after smoking cessation (▪) compared with continuing smoking (▴; RR 1.0).

Fig. 3—
Fig. 3—

Risk of all-cause mortality after smoking cessation expressed as a percentage of the risk in 100% of continuing smokers. The majority of these studies show a reduction in risk. #: females alone.

View this table:
Table 2—

Effects of smoking cessation on all-cause and chronic obstructive pulmonary disease (COPD) mortality

Since poor lung function is an independent predictor of all-cause mortality 57 and there are well-known difficulties in ascertainment of COPD as the principal cause of death 58, it was decided to include articles with mortality due to both all causes and COPD as outcomes. The 1990 US Surgeon General’s report evaluated studies of the effect of smoking cessation on mortality from all causes and COPD mortality in the general population and COPD patients. In these studies, the absolute reductions in mortality risk after quitting smoking ranged 32–84% compared with continuing smokers, and were highly dependent upon duration of smoking and amount smoked 10. A number of the studies analysed COPD mortality in ex-smokers by time since quitting smoking. Even in apparently healthy quitters, the risk of dying due to COPD remained higher than in continuing smokers for up to 10 yrs following tobacco abstinence, and mortality risk was also permanently elevated compared with never-smokers 32. With respect to mortality in patients already diagnosed with COPD, the report stated that no conclusions could be made due to the limited evidence available.

Clinically based studies

Of the four studies included in the 1990 report, only the two studies with a substantial duration of follow-up, the Utah study of Kanner et al. 33 and the Dutch study of Postma et al. 34, suggested increased survival probability in COPD patients who quit smoking. The IPPB Trial found similar mortality rates in current- and ex-smokers; however, the follow-up lasted only 3 yrs. Recently, the LHS published its 14.5-yr mortality results 35. Mortality due to respiratory disease other than cancer constituted 7.8% of all deaths, and mortality rates due to these diseases were significantly lower in the intervention than in the usual care group. Furthermore, respiratory disease mortality was lowest in sustained quitters, highest in continuing smokers and intermediate in intermittent quitters. Finally, a study from Boston (MA, USA) of 139 patients aged <53 yrs with very severe COPD, who were followed for up to 8 yrs, showed that cumulative tobacco consumption and active smoking after enrolment were associated with poorer survival 36, whereas ex-smoking at study entrance implied better survival.

Population-based studies

After 40 yrs of follow-up in male UK doctors, Doll et al. 37 found that mortality rates due to COPD in former smokers lay between those of never- and current smokers. Similar results were found in the study of US veterans, the Whitehall Study, a large Swedish study, the Multiple Risk Factor Intervention Trial, the Honolulu Heart Program and a large study from Washington County 32, 3842. A large Norwegian study that followed a cohort of males and females initially aged 35–49 yrs for 13 yrs showed that mortality rates due to respiratory disease were almost equal in never- and ex-smokers 43. By contrast, the study from Finland, a Spanish study of males aged ≥65 yrs and the Copenhagen City Heart Study found similar COPD mortality rates in quitters and continuing smokers 4446. However, in the latter study, this was only seen in females, and there were few deaths from COPD in any of the studies. Results from a pooled analysis of population studies in Denmark showed an increase in mortality rates due to respiratory disease with fewer years since quitting and a greater amount smoked 47. However, only all-cause mortality rates were significantly lower in ex-smokers than in current smokers, as was the case in the Finnish study.

Four studies have analysed mortality specifically in relation to lung function and smoking habits. The Busselton Health Study from Australia analysed mortality per 10% decrease in FEV1 and found increased all-cause mortality in male ex-smokers (highest) and current smokers compared with never-smokers 48. Analyses of overall mortality in females and of respiratory disease mortality in both sexes were nonsignificant, most probably due to lack of power. A small cohort study from Sweden found quite similar cardiovascular mortality rates in ex- and current smokers by FEV1 decline tertile, but the smoking groups were not compared with each other 49. A study in a subset of the census population in Washington County (OR, USA) comprising 884 males found elevated all-cause and COPD mortality rates across all smoking strata in males with an FEV1 of <65% pred, with the rates for ex-smokers lying between those of never- and current smokers 42. A recent study from the First National Health and Nutrition Examination Survey, with a long duration of follow-up, found that the all-cause mortality rate in former smokers did not differ significantly from that in never-smokers, whereas it was increased in current smokers 50.

Chinese studies

There are few mortality studies from China 5154, and all are population-based. There are no studies addressing COPD morbidity. Study participants were all aged ≥60 yrs, follow-up was generally short, and only one recent study was large (56,167 subjects). All studies showed that COPD mortality rates were higher in ex- than never- and current smokers, but the large cohort study from elderly health centres in Hong Kong followed for 3.2–5.0 yrs found that RRs of all-cause mortality in ex-smokers lay between those of never- and current smokers 54.

DISCUSSION

Morbidity

With ∼20 published papers specifically addressing smoking cessation and some aspect of COPD morbidity as outcome since the mid-1970s, the evidence, on which smoking cessation recommendations in COPD patients are based, is truly not proportionate to the degree of morbidity caused by smoking. Furthermore, only half of the studies have analysed loss of lung function as the primary outcome, and these studies vary considerably with respect to definition and severity of COPD, duration of smoking cessation and methodology in general. Some studies have employed a proxy for COPD, i.e. they did not define the disease but rather analysed subjects with respiratory symptoms or those with the lowest baseline FEV1; however, these measures are not necessarily appropriate as disease markers. Despite the study dissimilarities, they nearly all show significantly attenuated FEV1 decline in ex-smokers or quitters compared with continuing smokers, suggesting a clear benefit of smoking cessation, even in the few studies that included patients with more severe disease. Some exceptions were found in three of the earliest studies from the USA 12, 27, 28, in two of which a favourable effect of smoking cessation on lung function loss was found only in females 27, 28. It is not clear, though, whether detailed adjustment for smoking habits in males and females was performed in these studies. With hospital admission for COPD exacerbation or analysis of development of severe/very severe COPD (GOLD stage 3–4), it must be assumed, apart from the possible inaccuracies in disease coding on discharge records, that these events occur in patients with severe disease. After 5 yrs of follow-up in the LHS and 2.5 yrs in a small study from France, and cross-sectionally in the Spanish EFRAM, there were no differences in risk of hospitalisation due to COPD between current and ex-smokers 17, 20, 21. In contrast, the population-based studies from Denmark and Sweden, with longer duration of follow-up, showed lower risk of these outcomes after quitting smoking compared to that found in continuing smokers 29, 30, but the results were highly dependent upon the duration of smoking cessation.

Findings from the morbidity studies illustrate the complexities in assessing the potential benefits of quitting smoking in COPD patients. Smoking cessation in mild-to-moderate disease can prevent progression of disease severity; however, it is not known what characterises smokers with different stages of COPD who choose to stop smoking compared with those who continue. Possible biases towards not finding a beneficial effect of smoking cessation include so-called reverse causality (ill-quitter or healthy smoker effect). In cohort studies, residual confounding and changes in smoking status during long-term follow-up can affect the associations between exposure and outcome. Furthermore, several recent bronchial biopsy studies have shown that airway inflammation persists in ex-smoking COPD patients 59, which is likely to affect disease course. In contrast, the effect of smoking cessation can be overestimated in hospital admission or incidence studies if current smokers are more likely than ex-smokers to obtain a discharge diagnosis of COPD or to undergo spirometry. Finally, it is difficult to conduct a large cohort study primarily aimed at smoking cessation intervention in patients with severe COPD due to the high rate of cessation in these populations, except in populations in whom smoking cessation intervention is seldom practised, such as in China. The largest study of severe COPD patients presented in this review, the IPPB Trial, included patients with a pre-bronchodilator FEV1 of <60% pred, but without chronic respiratory failure. The investigators attributed their null results with respect to smoking status, FEV1 decline and mortality to the ill-quitter effect and the short duration of follow-up 12. Since the early 1990s, efforts in treatment of COPD have, among other initiatives, concentrated on inhaled bronchodilators and/or inhaled corticosteroids (ICSs), making it more complicated to disentangle the effects of smoking cessation and pharmacological therapy in the many randomised trials that have been conducted in this area. The newly published Towards a Revolution in COPD Health (TORCH) trial 60, which had approximately the same inclusion criteria and duration as study of Anthonisen et al. 12, but with >6,000 patients, stratified the survival analyses according to baseline smoking status, possibly to avoid interaction between smoking status and pharmacological therapy. Of the study population, 43% were current smokers at baseline, and change in FEV1 was assessed every 24 weeks by post-bronchodilator spirometry in the four treatment arms, but smoking status at the follow-up visits was not taken into account in these analyses.

Mortality

From table 2, it appears that the vast majority of the mortality studies have been performed in healthy populations. Eight of the retrieved papers analysed all-cause mortality alone, nine studies had mortality due to COPD as the sole outcome and seven studies analysed both outcomes. With a few exceptions (studies with short follow-up and the Chinese studies), the results indicate that mortality rates due to all causes and COPD decline progressively after smoking cessation compared with continuing smoking, but that mortality risk in ex-smokers is still elevated in comparison with never-smokers, even after many years of abstinence from smoking. The most comprehensive study in this respect was the large study of male UK doctors, which published results from 50 yrs of observation in 2004 55. Survival analyses were carried out for all-cause mortality for never-smokers, continuing smokers and ex-smokers by age at stopping smoking. Evidence of reverse causality was present when comparing mortality ratios (RR) for equal-age groups of quitters and continuing smokers since mortality risk was higher in quitters than in current smokers. However, by 1 yr after quitting, rates were already lower than in continuing smokers. For smokers in the oldest age group (75–84 yrs; longest duration of follow-up), the following annual mortality rates were found: 51.7, 53.1, 69.1, 78.9, and 112.2 per thousand males for never-smokers, smokers quitting at age 35–44, 45–54 and 55–64 yrs, and continuing smokers, respectively. The authors concluded that, for males born around 1920, smoking cessation at age 50 yrs halved the risk of premature death, and quitting at age 30 yrs conveyed the same risk as found in lifelong nonsmokers. Survival analyses were not performed for mortality due to COPD.

The Chinese studies deserve special comment as they all found higher rates of COPD mortality in ex- than current smokers. In all studies, the number of COPD deaths was small, and three of the studies had a follow-up of <10 yrs. It is also highly probable that these studies are especially subject to reverse causality due to the early stage of the tobacco epidemic in China and the higher prevalence of COPD in never-smokers compared with that found in Western countries. Furthermore, these studies and the other studies presented with mortality due to COPD or other respiratory causes can all be subject to the biases discussed previously, and underreporting or misclassification of COPD on death certificates is likely to influence the associations between smoking cessation and mortality. Data from the Copenhagen City Heart Study 61 has previously been reported, in which only 25% of subjects with severe COPD at baseline had this disease registered on their death certificate, and, conversely, 50% of those with COPD as the primary cause of death exhibited a normal FEV1/FVC at baseline. It is well known that COPD patients die primarily due to respiratory failure, cardiovascular disease and lung cancer, and it seems that there are some links between these comorbid conditions and COPD mortality beyond cigarette smoke, which complicate the studies of mortality in COPD epidemiology 62.

Most of the recent research on mortality and COPD has focused on ICSs. A pooling of seven randomised studies (∼5,000 patients) found that ICS reduced COPD mortality by 27% relative to placebo, although none of the studies separately reached significance in favour of ICSs 63. The beneficial effect, however, was particularly noticeable in ex-smokers and females, and it is assumed that ICSs may potentially work better in ex-smokers than current smokers in COPD, through largely unknown mechanisms 64. Surprisingly, the TORCH trial showed no survival benefit in patients randomised to ICSs alone.

Conclusions

Complete estimation of the effect of smoking cessation per se in patients with severe COPD is still difficult due to the limited data and methodological challenges. In studies of morbidity, rate of FEV1 decline is the most widely used outcome measure, but may not be sufficient to fully describe the effect of quitting smoking on COPD as a disease entity. Studies on mortality due to COPD (usually combined with other respiratory causes) are impeded by difficulties in ascertaining the cause of death and because of reverse causality, especially if the duration of follow-up is short. Nevertheless, on the basis of the available evidence, the following can be concluded.

In smokers aged >35 yrs with mild-to-moderate COPD, smoking cessation initially increases the FEV1, and, subsequently, the rate of FEV1 decline in sustained quitters reverts to the age-related decline seen in never-smokers in the background population. However, the deficit in percentage predicted FEV1 at the time of smoking cessation is not fully recovered.

The majority of studies in patients with more severe disease confirm an attenuated rate of FEV1 decline following smoking abstinence compared with continuing smoking, and two studies suggest a greater benefit in females who quit smoking.

The few large observational studies with a long follow-up period suggest that smoking cessation decreases the RR (relative to continued smoking) of incident COPD and hospital admission with a COPD exacerbation. The risk reduction varies with duration of smoking cessation and cumulative tobacco exposure (pack-years of smoking).

Data from the USA and Europe indicate that smoking cessation leads to decreased mortality due to COPD and all causes compared with continued smoking.

In earlier studies, mortality rates due to COPD were paradoxically elevated in ex-smokers compared with current smokers for up to 10 yrs after smoking cessation, but decreased thereafter. Many recent studies have not been of sufficient size or strength to clarify this issue, and reverse causality can also lead to underestimation of the benefits of cessation, even in studies that have shown some benefits. The available data show a permanently increased risk of morbidity and mortality due to COPD in ex-smokers compared with never-smokers.

Further research is needed, especially in China and other populations in whom the tobacco epidemic is at an early stage and in whom the chronic obstructive pulmonary disease prevalence in nonsmokers is higher than that found in developed countries.

Support statement

This study was supported by the Danish Ministry of Health (Copenhagen, Denmark).

  • Received November 27, 2007.
  • Accepted May 25, 2008.

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COPD-related morbidity and mortality after smoking cessation: status of the evidence
N. S. Godtfredsen, T. H. Lam, T. T. Hansel, M. E. Leon, N. Gray, C. Dresler, D. M. Burns, E. Prescott, J. Vestbo
European Respiratory Journal Oct 2008, 32 (4) 844-853; DOI: 10.1183/09031936.00160007
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