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Note: The Overview section summarizes the published evidence on this topic. The rest of the summary describes the evidence in more detail.
Other PDQ summaries containing information related to lung cancer prevention include the following:
Who Is at Risk?
Lung cancer risk is largely a function of older age combined with extensive cigarette smoking history. Lung cancer is more common in men than women and in those of lower socioeconomic status. Patterns of lung cancer according to demographic characteristics tend to be strongly correlated with historical patterns of cigarette smoking prevalence. An exception to this is the very high rate of lung cancer in African American men, a group whose very high lung cancer death rate is not explainable simply by historical smoking patterns.[
In nonsmokers, important lung cancer risk factors are exposure to secondhand smoke, exposure to ionizing radiation, and occupational exposure to lung carcinogens, such as asbestos. Radiation exposures relevant to the general population include environmental exposure to radon and radiation exposures administered in the medical care setting, particularly when administered at high doses, such as radiation therapy to the chest or breast.[
Factors associated with increased risk of lung cancer
Cigarette smoking
Starting with the 1964 Surgeon General's Report and followed by each subsequent Surgeon General's Report that has included a review of the evidence on smoking and lung cancer, an enormous body of scientific evidence clearly documents that cigarette smoking causes lung cancer, and that cigarette smoking is the major cause of lung cancer.
Based on solid evidence, cigarette smoking causes lung cancer. The risks of lung cancer associated with cigarette smoking are dose-dependent and increase markedly according to the number of cigarettes smoked per day and the number of years smoked. On average, current smokers have approximately 20 times the risk of lung cancer compared with nonsmokers.
Magnitude of Effect: Increased risk, very large.
Study Design: Numerous prospective cohort and case-control studies, combined with quasi-experimental evidence showing population-level smoking prevalence predicts the population-level burden of lung cancer. |
Internal Validity: Good. |
Consistency: Good. |
External Validity: Good. |
Exposure to secondhand smoke
Based on solid evidence, exposure to secondhand smoke is an established cause of lung cancer.
Magnitude of Effect: Increased risk, small magnitude. Compared with nonsmokers not exposed to secondhand smoke, nonsmokers exposed to secondhand smoke have approximately a 20% increased risk of lung cancer.
Study Design: Prospective cohort and case-control studies. |
Internal Validity: Good. |
Consistency: Good. |
External Validity: Good. |
Radiation exposure
Based on solid evidence, exposure to radiation increases lung cancer incidence and mortality. Cigarette smoking greatly potentiates this effect.
Magnitude of Effect: Increased risk that follows a dose-response gradient, with smaller increases in risk for low levels of exposure and greater increases in risk for high levels of exposure.
Study Design: Cohort and case-control studies. |
Internal Validity: Fair. |
Consistency: Good. |
External Validity: Good. |
Occupational exposure to lung carcinogens
Based on solid evidence, workplace exposure to asbestos, arsenic, beryllium, cadmium, chromium, and nickel increases lung cancer incidence and mortality.
Magnitude of Effect: Increased risk, large magnitude (more than fivefold). Risks follow a dose-response gradient, with high-level exposures associated with large increases in risk. Cigarette smoking also potentiates the effect of many of these lung carcinogens so that the risks are even greater in smokers.
Study Design: Cohort and case-control studies. |
Internal Validity: Good. |
Consistency: Good. |
External Validity: Good. |
Air pollution
Based on solid evidence, exposure to outdoor air pollution, specifically small particles, increases lung cancer incidence and mortality.
Magnitude of Effect: Increased risk; compared with the lowest exposure categories, those in the highest exposure categories have approximately a 40% increased risk of lung cancer.
Study Design: Cohort and case-control studies. |
Internal Validity: Good. |
Consistency: Good. |
External Validity: Good. |
Factors of uncertain association with risk
Dietary factors
Based on equivocal evidence, the observed inverse associations between lung cancer and dietary factors, such as fruit and vegetable consumption, are difficult to disentangle from cigarette smoking.
Magnitude of Effect: Inverse association, moderate magnitude, but difficult to determine if true cause-effect association or due to confounding by cigarette smoking.
Study Design: Numerous cohort and case-control studies, and meta-analyses. |
Internal Validity: Fair. |
Consistency: Fair. |
External Validity: Good. |
Physical activity
Based on equivocal evidence, the observed inverse associations between lung cancer and higher levels of physical activity are difficult to disentangle from cigarette smoking.
Magnitude of Effect: Inverse association, moderate magnitude, but difficult to determine if true cause-effect association or due to confounding by cigarette smoking.
Study Design: Numerous cohort and case-control studies, and meta-analyses. |
Internal Validity: Fair. |
Consistency: Fair. |
External Validity: Good. |
Interventions Associated With Decreased Risk of Lung Cancer
Smoking avoidance
Based on solid evidence, cigarette smoking causes lung cancer and therefore, smoking avoidance results in decreased mortality from primary lung cancers.
Magnitude of Effect: Decreased risk, substantial magnitude.
Study Design: Cohort and case-control studies. |
Internal Validity: Good. |
Consistency: Good. |
External Validity: Good. |
Smoking cessation
Based on solid evidence, long-term sustained smoking cessation results in decreased incidence of lung cancer and of second primary lung tumors.
Magnitude of Effect: Decreased risk, moderate magnitude.
Study Design: Cohort and case-control studies. |
Internal Validity: Good. |
Consistency: Good. |
External Validity: Good. |
Eliminating secondhand smoke
Based on solid evidence, exposure to secondhand smoke causes lung cancer and therefore, preventing exposure to secondhand smoke results in decreased incidence and mortality from primary lung cancers.
Magnitude of Effect: Decreased risk, small magnitude.
Study Design: Cohort and case-control studies. |
Internal Validity: Good. |
Consistency: Good. |
External Validity: Good. |
Reducing or eliminating occupational exposure to lung carcinogens
Based on solid evidence, occupational exposures such as asbestos, arsenic, nickel, and chromium are causally associated with lung cancer. Reducing or eliminating workplace exposures to known lung carcinogens would be expected to result in a corresponding decrease in the risk of lung cancer.
Magnitude of Effect: Decreased risk, with a larger effect, the greater the reduction in exposure.
Study Design: Cohort and case-control studies. |
Internal Validity: Good. |
Consistency: Good. |
External Validity: Good. |
Reducing or eliminating exposure to radon
Based on solid evidence, indoor exposure to radon increases lung cancer incidence and mortality, particularly among cigarette smokers. In homes with high radon concentrations, taking steps to prevent radon from entering homes by sealing the basement would be expected to result in a corresponding decrease in the risk of lung cancer.
Magnitude of Effect: Increased risk that follows a dose-response gradient, with small increases in risk for levels experienced in most at-risk homes to greater increases in risk for high-level exposures.
Study Design: Cohort and case-control studies. |
Internal Validity: Fair. |
Consistency: Good. |
External Validity: Fair. |
Interventions Associated With an Increased Risk of Lung Cancer
Beta-carotene supplementation in current smokers
Based on solid evidence, high-intensity smokers who take pharmacological doses of beta-carotene have an increased lung cancer incidence and mortality that is associated with taking the supplement.
Magnitude of Effect: Increased risk, small magnitude.
Study Design: Two randomized controlled trials (RCTs) with consistent results. |
Internal Validity: Good. |
Consistency: Good. |
External Validity: Good. |
Interventions That Do Not Decrease Risk of Lung Cancer
Beta-carotene in nonsmokers
Based on solid evidence, nonsmokers who take pharmacological doses of beta-carotene do not experience significantly different lung cancer incidence or mortality compared with taking a placebo.
Magnitude of Effect: No substantive effect.
Study Design: RCT. |
Internal Validity: Good. |
Consistency: Good. |
External Validity: Fair. |
Vitamin E (Tocopherol)
Based on solid evidence, taking vitamin E supplements does not affect the risk of lung cancer.
Magnitude of Effect: Strong evidence of no association.
Study Design: RCTs. |
Internal Validity: Good. |
Consistency: Fair. |
External Validity: Good. |
References:
Lung cancer has a tremendous impact on the health of the American public, with an estimated 234,580 new cases and 125,070 deaths predicted in 2024 in men and women combined.[
Lung cancer incidence and mortality are highest in Black men compared with other racial and ethnic groups in the United States.[
Surgical treatment or radiation therapy is the treatment of choice for early stages of cancer.[
The hypothesis has been proposed that women may be more susceptible than men to smoking-caused lung cancer. However, the results of studies that compared the association between smoking and lung cancer in men and women using appropriate comparisons do not support this hypothesis.[
The results of the Multi-Ethnic Cohort Study indicated that for a given degree of cigarette smoking, African American individuals had a higher risk of lung cancer than other racial and ethnic groups.[
References:
The epidemic of lung cancer in the 20th century was primarily due to increases in cigarette smoking, the predominant cause of lung cancer. The threefold variation in lung cancer mortality rates across the United States more or less parallels long-standing state-specific differences in the prevalence of cigarette smoking. For example, average annual age-adjusted lung cancer death rates for 1996 to 2000 were highest in Kentucky (78 deaths per 100,000 individuals), where 31% of residents were current smokers in 2001. Lung cancer death rates were lowest in Utah (26 deaths per 100,000 individuals), which had the lowest prevalence of cigarette smoking (13%).[
References:
Understanding the biology of carcinogenesis is crucial to the development of effective prevention and treatment strategies. Two important concepts in this regard are the multistep nature of carcinogenesis and the diffuse field-wide carcinogenic process. Epithelial cancers in the lung appear to develop in a series of steps extending over years. Epithelial carcinogenesis is conceptually divided into three phases: initiation, promotion, and progression. This process has been inferred from human studies identifying clinical-histological premalignant lesions (e.g., metaplasia and dysplasia). The concept of field carcinogenesis is that multiple independent neoplastic lesions occurring within the lung can result from repeated exposure to carcinogens, primarily tobacco. Patients developing cancers of the aerodigestive tract secondary to cigarette smoke also are likely to have multiple premalignant lesions of independent origin within the carcinogen-exposed field. The concepts of multistep and field carcinogenesis provide a model for prevention studies.[
References:
Factors Associated With Increased Risk of Lung Cancer
Cigarette smoking
The most important risk factor for lung cancer (and for many other cancers) is cigarette smoking.[
The development of lung cancer is the culmination of multistep carcinogenesis. Genetic damage caused by chronic exposure to carcinogens, such as those in cigarette smoke, is the driving force behind the multistep process. Evidence of genetic damage is the association of cigarette smoking with the formation of the DNA adducts in human lung tissue. A strong link between tobacco smoke and lung carcinogenesis has been established by molecular data.[
Secondhand tobacco smoke
Secondhand tobacco smoke is also an established cause of lung cancer.[
Family history
A positive family history of lung cancer is a risk factor for lung cancer. The results of a meta-analysis of epidemiological studies indicated that those with a positive family history of lung cancer were at approximately twice the risk of lung cancer compared with those with no affected relatives.[
Human immunodeficiency virus (HIV) infection
HIV infection has been observed to be statistically associated with an increased lung cancer risk; for example, the results of a meta-analysis of 13 studies indicated HIV-infected individuals had a 2.6-fold higher risk of lung cancer than non-HIV-infected individuals (standard incidence ratio, 2.6; 95% confidence interval [CI], 2.1–3.1).[
Other environmental causes of lung cancer
Occupational exposures to lung carcinogens
Several environmental exposures other than tobacco smoke are causally associated with lung cancer, but the proportion of the lung cancer burden due to these exposures is small compared with cigarette smoking. Many lung carcinogens have been identified in studies of high occupational exposures. Considered in total, occupational exposures have been estimated to account for approximately 10% of lung cancers.[
Radiation exposure
Based on studies of populations exposed to high doses of radiation, lung cancer has been determined to be one of the cancers that is causally associated with exposure to ionizing radiation.[
An important early source of data about radiation exposure came from studies of atomic bomb survivors in Japan; these studies demonstrated that a single high-dose exposure to gamma rays is sufficient to increase the risk of lung cancer in a dose-dependent fashion.[
The association between radiation exposure and lung cancer has implications for the general population in countries such as the United States, where computed tomography (CT) scans are relatively common and may contribute to an excess of cancer at the population level.[
Because they deposit concentrated energy in tissue, particles (e.g., alpha particles) produce more biological damage at an equivalent dose than radiation (e.g., x-rays).[
Estimates of the proportion of lung cancer deaths attributable to indoor exposure to radon vary by method of estimation and by the levels of radon exposure in a country, but the median estimates are 26% for lifelong nonsmokers (range, 13%–50%) and 10% for ever smokers (range, 7%–13%).[
Air pollution
Although early evidence from case-control and cohort studies did not support an association between air pollution and lung cancer, the evidence now points to a genuine association.[
Factors of Uncertain Association With Risk
Dietary factors
Studies of dietary factors have yielded intriguing findings, but because the diets of smokers tend to be less healthy than those of nonsmokers, it is challenging to separate the influence of dietary factors from the effects of smoking. When considering the relationships between lung cancer and dietary factors, confounding factors related to cigarette smoking cannot be dismissed as a possible explanation.
While the focus has been on fruit and vegetable consumption and micronutrients, a wide range of dietary and anthropometric factors have been investigated. Anthropometric measures have been studied, indicating a tendency for leaner persons to have increased lung cancer risk relative to those with greater body mass index.[
Physical activity
A meta-analysis of leisure-time physical activity and lung cancer risk revealed that higher levels of physical activity protect against lung cancer.[
Studies of physical activity yield findings consistent with an inverse association, but because physical activity behaviors differ between smokers and nonsmokers, it is difficult to infer that there is a direct relationship between physical activity and lung cancer risk.
Lung cancer in never smokers
In countries where cigarette smoking is common, about 10% to 20% of lung cancer cases occur in never smokers.[
References:
Smoking Avoidance and Cessation
Substantial harm to public health accrues from addiction to cigarette smoking. Compared with nonsmokers, smokers experience a dose-dependent increase in the risk of developing lung cancer (and many other malignancies).[
Approximately 85% of all lung cancer deaths are estimated to be attributed to cigarette smoking. Substantial benefits accrue to the smoker by quitting smoking. For more information, see Cigarette Smoking: Health Risks and How to Quit. Avoidance of tobacco use is the most effective measure to prevent lung cancer. The preventive effect of smoking cessation depends on the duration and intensity of prior smoking and upon time since cessation. Compared with the risk in persistent smokers, a 30% to 60% reduction in lung cancer mortality risk has been noted after 10 years of cessation.[
The benefits of tobacco control at the population level provide strong quasi-experimental evidence that reducing population-level exposure to cigarettes has resulted in population-level declines in the occurrence of lung cancer. Reduced tobacco consumption, resulting from decreases in smoking initiation and increases in smoking cessation, led to a decline in overall age-adjusted lung cancer mortality among men since the mid-1980s, consistent with reductions in smoking prevalence among men since the 1960s.[
Smoking cessation guidelines
Nicotine dependence exposes smokers in a dose-dependent fashion to carcinogenic and genotoxic elements that cause lung cancer.[
Pharmacotherapy for smoking cessation
Many pharmacotherapies for smoking cessation, including nicotine replacement therapies (e.g., gum, patch, spray, lozenge, and inhaler) and other smoking cessation pharmacotherapies (e.g., varenicline and bupropion), result in statistically significant increases in smoking cessation rates compared with placebo. Based on a synthesis of the results of 110 randomized trials, nicotine replacement therapy treatments, alone or in combination, improve cessation rates over placebos after 6 months (relative risk, 1.58; 95% confidence interval, 1.50–1.66).[
Population-level interventions
In addition to individually focused cessation efforts, a number of tobacco control strategies at the community, state, and national level have been credited with reducing the prevalence of smoking. Strategies include the following:[
Smoke-free workplace legislation
A review of more than 50 studies found that smoke-free workplace legislation was consistently associated with reduced secondhand smoke exposure, whether measured in reduced time of exposure (71%–100% reduction) or prevalence of persons exposed to secondhand smoke (22%–85% reduction), with particularly marked reductions among hospitality workers.[
Preventing Occupational Exposure to Lung Carcinogens
After cigarette smoking and exposure to secondhand smoke, occupational exposure to lung carcinogens, such as asbestos, arsenic, nickel, and chromium, is the most important contributor to the lung cancer burden. When occupational exposure to lung carcinogens are all considered together, 9% to 15% of all lung cancer deaths can be attributed to occupational exposure to lung carcinogens.[
References:
Beta-Carotene Supplementation in Smokers
Results of the National Cancer Institute (NCI) Alpha-Tocopherol, Beta-Carotene Cancer Prevention (ATBC) trial were first published in 1994.[
In 1996, the results of the U.S. Beta-Carotene and Retinol Efficacy Trial (CARET) were published.[
The overall findings from the ATBC [
References:
Chemoprevention
Studies have examined whether it is possible to prevent cancer development in the lung using chemopreventive agents. Chemoprevention is defined as the use of specific natural or synthetic chemical agents to reverse, suppress, or prevent carcinogenesis before the development of invasive malignancy. So far, agents tested for efficacy in lung cancer chemoprevention have been micronutrients, such as beta-carotene and vitamin E.
Beta-carotene supplementation in nonsmokers
Two other randomized controlled trials of beta-carotene were carried out in populations that were not at excess risk of lung cancer. The Physicians' Health Study was designed to study the effects of beta-carotene and aspirin in cancer and cardiovascular disease. The study was a randomized, double-blind, placebo-controlled trial begun in 1982 involving 22,071 male physicians aged 40 to 84 years. After 12 years of follow-up, beta-carotene was not associated with overall risk of cancer (relative risk [RR], 0.98) or lung cancer among current (11% of study population) or former (39% of study population) smokers.[
In the Women's Health Study (WHS) approximately 40,000 female health professionals were randomly assigned to 50 mg beta carotene on alternate days or placebo. After a median of 2.1 years of beta-carotene treatment and 2 additional years of follow-up, there was no evidence that beta-carotene protected against lung cancer, as there were more lung cancer cases observed in the beta-carotene (n = 30) than placebo (n = 21) group.[
Vitamin E supplementation
The Heart Outcomes Prevention Evaluation (HOPE) trial began in 1993 and continued follow-up as the HOPE-The Ongoing Outcomes (HOPE-TOO) through 2003. In this randomized, placebo-controlled trial, patients aged 55 years or older with vascular disease or diabetes were assigned to 400 IU vitamin E or placebo. With a median follow-up of 7 years, the group randomly assigned to vitamin E had a significantly lower lung cancer incidence rate (1.4%) than the placebo group (2.0%) (RR, 0.72; 95% confidence interval [CI], 0.53–0.98).[
Looking at the vitamin E results for the ATBC, HPS, and HOPE-TOO studies combined, the summary odds ratio was 0.97 (95% CI, 0.87–1.08),[
References:
The PDQ cancer information summaries are reviewed regularly and updated as new information becomes available. This section describes the latest changes made to this summary as of the date above.
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