Evidence-based Medicine (EBM) Resources in Current Therapies
Compiled by: Constantine Kaniklidis, medical researcher
European Association for Cancer Research (EACR)

Advancing cancer research — from basic research to prevention, treatment and care


Smoke Watch: Secondhand Smoke (SHS) and Smoking Cessation

Secondhand Smoke

"While smokers may have the right to smoke, nonsmokers should have the right to be protected from harm resulting from the action of smokers"

Proffessor Adi Gazdar, M.D.,
W. Ray Wallace Distinguished Chair in Molecular Oncology Research,
Department of Pathology,
Southwestern Medical School

Secondhand smoke is considered to be a combination of:

sidestream smoke (smoke released from burning end of cigarette), plus exhaled
mainstream smoke (smoke exhaled by the smoker).

Sidestream smoke is generated at lower temperatures and under different conditions than mainstream smoke, and therefore contains higher concentrations of many of the toxins found in cigarette smoke, and at least 250 of these chemicals in secondhand smoke are known to be toxic or carcinogenic (including formaldehyde, benzene, vinyl chloride, arsenic, ammonia, and hydrogen cyanide), according to estimates from the National Toxicology Program, with over 50 of these known and classified to be carcinogenic:

  • Polynuclear aromatic hydrocarbons (PAHs) (such as Benzo[a]pyrene)
  • N-Nitrosamines (such as tobacco-specific nitrosamines)
  • Aromatic amines (such as 4-aminobiphenyl)
  • Aldehydes (such as formaldehyde)
  • Miscellaneous organic chemicals (such as benzene and vinyl chloride) and
  • Inorganic compounds
    (such as those containing metals like arsenic, beryllium, cadmium, lead, nickel and radioactive polonium-210)

so when nonsmokers are exposed to secondhand smoke, they are in fact inhaling many of the same carcinogens inhaled by smokers themselves

Major Conclusions of the 2006 Surgeon General Report on Secondhand Smoke:



The Health Consequences of Involuntary Exposure to Tobacco Smoke: A Report of the Surgeon General.
U.S. Department of Health and Human Services,
Centers for Disease Control and Prevention,
National Center for Chronic Disease Prevention and Health Promotion,
Office on Smoking and Health, 2006.

(Also available: Executive Summary).

 

  • Exposure:

    • Millions of Americans are exposed to secondhand smoke.
    • There is no risk-free level of exposure to secondhand smoke:
      even small amounts of secondhand smoke exposure can be harmful to people’s health:

      • Short exposures to secondhand smoke, such as even a short time in a smoky room, can cause blood platelets to become stickier, damage the lining of blood vessels, decrease coronary flow velocity reserves, and reduce heart rate variability, potentially increasing the risk of a heart attack.

      • Secondhand smoke contains many chemicals that can quickly irritate and damage the lining of the airways. Even brief exposure can result in upper airway changes in healthy persons, triggering respiratory symptoms, including cough, phlegm, wheezing, and breathlessness, and can lead to more frequent and more asthma attacks in children who already have asthma, and children exposed to secondhand smoke are also at an increased risk for acute respiratory infections, ear problems, and severe asthma.

      • A smoke-free environment is the only way to fully protect nonsmokers from the dangers of secondhand smoke.
      • Separating smokers from nonsmokers, cleaning the air, and ventilating buildings cannot eliminate exposure of nonsmokers to secondhand smoke:
      • Conventional air cleaning systems can remove large particles, but not the smaller particles or the gases found in secondhand smoke.
      • ASHRAE (American Society of Heating, Refrigerating and Air-Conditioning Engineers, the preeminent U.S. authority on ventilation issues, has concluded that ventilation technology cannot be relied on to control health risks from secondhand smoke exposure.


  • Health Hazards of Exposure:

    • Secondhand smoke (SHS) has been designated as a known human carcinogen by the U.S. EPA, the National Toxicology Program and the International Agency for Research on Cancer (IARC), with several compounds in tobacco smoke identified by IARC as known human carcinogens (Group 1). In addition, the National Institute for Occupational Safety and Health has concluded that secondhand smoke is an occupational carcinogen.

    • SHS exposure causes disease and premature death in non-smokers:

      • Exposure of adults to secondhand smoke has immediate adverse effects on the cardiovascular system and causes coronary heart disease and lung cancer.
      • Breathing secondhand smoke for even a short time can have immediate adverse effects on the cardiovascular system and interferes with the normal functioning of the heart, blood, and vascular systems in ways that increase the risk of a heart attack.

    • Secondhand Smoke Exposure in the Home:
      • The home is a major location of secondhand smoke exposure for adults and the place where children are most exposed to secondhand smoke.
      • Secondhand smoke exposure in the home has been consistently linked to a significant increase in both heart disease and lung cancer risk among adult nonsmokers.
      • Eliminating smoking in indoor spaces is the only way to fully protect nonsmokers from secondhand smoke exposure.
      • Smoke-free rules in homes and vehicles can reduce secondhand smoke exposure among children and nonsmoking adults.


  • Risk of Exposure:

    • Nonsmokers exposed to secondhand smoke at home or at work increase their risk of developing heart disease by 25 - 30 percent.
    • Nonsmokers exposed to secondhand smoke at home or at work increase their risk of developing lung cancer by 20 - 30 percent.

Testing for Exposure to Secondhand Smoke

  • Currently, as observed by Georg Matt at San Diego State University and colleagues (Matt GE, Wahlgren DR, Hovell MF, et al. Measuring environmental tobacco smoke exposure in infants and young children through urine cotinine and memory-based parental reports: empirical findings and discussion. Tob Control. 1999 Autumn;8(3):282-9), there is no means by which the harmful components of ETS can be directly measured in the organs of interest (like the lungs). Therefore, indirect measures of secondhand smoke exposure have been developed,

  • Cotinine is the major metabolite (that is, breakdown (by-)product) of nicotine in th body, being generated from nicotine metabolically in the liver and then released into the bloodstream, and so analyzing the cotinine level in either the blood, saliva, or urine provides a reliable objective quantitative measure exposure to nicotine; and although nicotine itself is rapidly metabolized (short half-life), cotinine is metabolized and eliminated at a much slower rate, thus extending the window of detection for several days, typically 48 - 96 hours (Curvall M, Elwin CE, Kazemi-Vala E, Warholm C, Enzell CR. The pharmacokinetics of cotinine in plasma and saliva from non-smoking healthy volunteers. Eur J Clin Pharmacol. 1990;38(3):281-7. Simoni M, Baldacci S, Puntoni R, et al. Plasma, salivary and urinary cotinine in non-smoker Italian women exposed and unexposed to environmental tobacco smoking (SEASD study). Clin Chem Lab Med. 2006 May;44(5): 632-638).

  • Serum (blood), salivary or urinary levels of cotinine therefore most closely reflect the effective ingested dose of nicotine absorbed from secondhand smoke (both saliva and cotinine levels have been shown to be highly correlated with blood levels, and so allow these simpler and more accessible test to substitute for a serum assay, as demonstrated by Neil Benowitiz at UCSF (in Benowitz NL. Biomarkers of environmental tobacco smoke exposure. Environ Health Perspect. 1999 May;107 Suppl 2:349-55), who concluded that "cotinine levels provide valid and quantitative measures of average ongoing human ETS [environmental tobacco smoke] exposure over time".

  • Although the amount of cotinine may not be directly related to the amount of the disease-causing constituents, such as benzo(a)pyrene, to which a non-smoker was exposed (California Environmental Protection Agency Office of Environmental Health Hazard Assessment (OEHHA). Health Effects of Exposure to Environmental Tobacco Smoke), cotinine is nonetheless a surrogate marker of other toxins produced by the burning of tobacco such as benzene, formaldehyde, and others, and thus assesses assess cumulative exposure over days, as demonstrated by Jaakkola & Jaakkola (Jaakkola MS, Jaakkola JJ. Assessment of exposure to environmental tobacco smoke [pdf]. Eur Respir J. 1997 Oct;10(10):2384-97) who concluded that cotinine measurement was suitable for assessment of cumulative doses over short exposure periods of several days duration, serving as serve as a measure for the combined but not separate toxic components of secondhand smoke exposure (Benowitz NL. Biomarkers of environmental tobacco smoke exposure. Environ Health Perspect. 1999 May;107 Suppl 2:349-55. Also Hovell MF, Zakarian JM, Wahlgren DR, Matt GE, Emmons KM. Reported measures of environmental tobacco smoke exposure: trials and tribulations. Tob Control. 2000;9 Suppl 3:III22-8).

  • TobacAlert (from Nymox) is a leading over-the-counter home test for urinary cotinine levels, one whose instructions explicitly recognize its use for the detection of recent second hand smoke exposure. In urine, cotinine values between 11 ng/mL and 30 ng/mL are taken to be associated with light active smoking or secondhand exposure, while levels in active smokers typically achieve 500 ng/mL or above.


Evidence-based Research on Secondhand Smoke (SHS)

  • Secondhand Smoke and Cardiovascular Disease

    SHS Adverse Cardiovascular Impact
    The adverse cardiovascular impact of secondhand smoke has been supported in cohort and case control studies which find a 30% excess risk of fatal and non-fatal coronary heart disease in nonsmokers exposure to secondhand smoke (Law & Wald, Prog Cardiovasc Dis (2003): Environmental tobacco smoke and ischemic heart disease). And both epidemiological and laboratory data indicates that the risk of acute myocardial infarction and coronary heart disease associated with exposure to tobacco smoke is non-linear at low doses, increasing rapidly with relatively small doses such as those received from secondhand smoke - or actively smoking one or two cigarettes a day (Pechacek et al., BMJ (2004): How acute and reversible are the cardiovascular risks of secondhand smoke?), and even such small exposures significantly and rapidly increase platelet aggregation and induce other adverse arterial and hemodynamic changes (and the activation and aggregation of platelets, and consequent formation of a thrombus or clot obstructing arterial blood supply to part of the heart are established precipitants of acute myocardial infarction). Furthermore, the ATTICA study found that concentrations of known biomarkers of inflammation such as white blood cells, C reactive protein, homocysteine, fibrinogen, and oxidized LDL cholesterol in subjects exposed to secondhand smoke are similar to those observed in active smokers, with increase in overall inflammation, a precursor of atherosclerotic plaque (Panagiotakos et al., Am J Med (2004): Effect of exposure to secondhand smoke on markers of inflammation: the ATTICA study; see also Valkonen & Kuusi, Circ (1998): Passive Smoking Induces Atherogenic Changes in Low-Density Lipoprotein) who found that exposure of nonsmokers to secondhand smoke breaks down serum antioxidant defense, leading to a cascade of accelerated lipid peroxidation, LDL modification, and accumulation of LDL cholesterol in human macrophages, and these processes may be the pathophysiological basis for the epidemiological evidence of increased CHD risk among passive smokers.

    Sensitivity to Low Exposure
    The lowness of the exposure level needed to induce significant adverse cardiovascular events is suggested in the research of Otsuka et al. who found that just 30 minutes of exposure to a typical dose of secondhand smoke induces changes in arterial endothelial function (in terms of coronary flow velocity reserve (CFVR)) in exposed nonsmokers of a magnitude similar to those measured in active smokers (Otsuka et al. JAMA (2004): Acute Effects of Passive Smoking on the Coronary Circulation in Healthy Young Adults), thus inducing coronary circulation endothelial dysfunction. And as concluded, the cardiovascular system (platelet and endothelial function, arterial stiffness, atherosclerosis, oxidative stress, inflammation, heart rate variability, energy metabolism, and increased infarct size) is astonishingly sensitive to the toxins in secondhand smoke, given that the effects of even brief (minutes to hours) passive smoking are often nearly as large (averaging 80% to 90%) as chronic active smoking (Barnoya & Glantz, Circ (2005): Cardiovascular Effects of Secondhand Smoke - Nearly as Large as Smoking). The ultra-sensitivity is highlighted by the observation that despite the fact that the dose of smoke delivered to active smokers is 100 times or more that delivered to a passive smoker, the relative risk of coronary heart disease (CHD) is barely different, being 1.78 for smokers, and still 1.31 for passive smokers (Law et al., BMJ (1997): Environmental tobacco smoke exposure and ischaemic heart disease: an evaluation of the evidence).

    Underlying Mechanisms
    The underlying mechanisms of these adverse cardiovascular impacts of secondhand smoke are complex, and includes activation of platelet activity (increased platelet aggregability), endothelial dysfunction, increased arterial stiffness, lowered HDL, proinflammatory and pro-infection activity, atherosclerosis progression, increased infarct size, increased oxidative stress and decreased antioxidant defense, mitochondrial DNA damage, heart rate variability (HRT), insulin resistance, and decreased energy production in the heart muscle, and a decrease in the parasympathetic output to the heart. Some of the these, and other mechanisms are elaborated on below:
    1. polycyclic aromatic hydrocarbons (PAHs) in cigarette smoke, already recognized as potential environmental procarcinogens, and recently shown to induce acceleration of atherogenesis (Kurzee & Ramos, Circ Res (2001): Constitutive and Inducible Expression of Cyp1a1 and Cyp1b1 in Vascular Smooth Muscle Cells - Role of the Ahr bHLH/PAS Transcription Factor).
    2. adverse increase in carotid intimal thickening, via increased arterial expression of inducible nitric oxide synthase (iNOS), mediated at least in part by aryl hydrocarbon receptor (AhR) signaling (Anazawa et al., Arterioscler Thromb Vasc Biol (2005): Effect of Exposure to Cigarette Smoke on Carotid Artery Intimal Thickening - The Role of Inducible NO Synthase); inactivation of nitric oxide, possibly related to acute endothelial dysfunction, may be an underlying mechanism in the adverse cardiovascular sequelae of secondhand smoke (on secondhand smoke and endothelial dysfunction, see also Maresh et al., Physiol Genomics (2005): Tobacco smoke dysregulates endothelial vasoregulatory transcripts in vivo), and Celermajer et al., N Eng J Med (1996): Passive Smoking and Impaired Endothelium-Dependent Arterial Dilatation in Healthy Young Adults) who found that passive smoking was associated with dose-related impairment of endothelium-dependent dilatation in otherwise healthy young adults, suggesting early arterial damage).
    3. free radicals, inducing oxidative stress, that may modulate the expression of both acute and chronic phenotypes of smoking-induced vascular disease (see McNamara & Fitzgerald's (Circ Res (2001): Smoking-Induced Vascular Disease - A New Twist on an Old Theme) thoughtful commentary on this and related issues); see also the review of Raupach et al. (Sur Heart J (2006): Secondhand smoke as an acute threat for the cardiovascular system: a change in paradigm); as observe, the acute vascular responses to tobacco smoke may be secondary in part to oxidative stress, which can generate reactive oxygen species (ROS) such as superoxide anion, and these ROS may react with nitric oxide to form peroxynitrite, an eNOS activity uncoupler.
    4. atherosclerosis-mediated tissue damage following ischemia or myocardial infarction, by virtue of accelerated atherosclerotic lesion development consequent to the increased platelet activity stimulated by secondhand smoke (Glantz & Parmley, JAMA (1995): Passive smoking and heart disease. Mechanisms and risk).
    5. secondhand smoke induces altered cardiac autonomic function: heart rate variability (HRV) in healthy people has been shown to decrease by 12% after 2 hours of breathing secondhand smoke in an airport lounge, with HRV being an established predictor of cardiac death or arrhythmic events after myocardial infarction (Pope et al., Environ Health Perspect (2001): Acute Exposure to Environmental Tobacco Smoke and Heart Rate Variability).

  • SHS and Respiratory Disease (Lung Cancer and COPD (Chronic Obstructive Pulmonary Disease))

    Even as of the beginning of 2004, over 50 studies (Veneis et al., J Natl Cancer Inst (2004): Tobacco and Cancer: Recent Epidemiological Evidence) have shown that there is a clear dose-response relationship consistent with a causal association between exposure to secondhand smoke and the development of lung cancer among never smokers (and urinary levels of nicotine, cotinine, 4-(methylnitrosamino)-1-(3-pyridyl)-butanol (NNK), a tobacco-specific carcinogen, and its glucuronide (NNAL-Gluc) are elevated in nonsmoking women exposed to secondhand smoke compared to those who were not exposed), as found by the early review of Hackshaw et al. (BMJ (1997): The accumulated evidence on lung cancer and environmental tobacco smoke) who concluded that based on epidemiological and biochemical evidence on exposure to secondhand tobacco smoke, coupled with the supporting evidence of tobacco specific carcinogens in the blood and urine of exposed nonsmokers provides compelling confirmation that "breathing other people’s tobacco smoke is a cause of lung cancer", also confirmed in the Veneis JNCI review (see above). And the recent review of Thomas et al. (Chest (2005): Lung Cancer in Women - Emerging Differences in Epidemiology, Biology, and Therapy) found that secondhand (environmental) smoke accounts for approximately 3,000 lung cancer deaths each year in the United States among nonsmokers, confirming the findings of the seminal EPIC study (Veneis et al. BMJ (2005): Environmental tobacco smoke and risk of respiratory cancer and chronic obstructive pulmonary disease in former smokers and never smokers in the EPIC prospective study) which had previously found that secondhand smoke (or ETS: environmental tobacco smoke) is a significant risk factor for both lung cancer and other respiratory diseases.

    From an updated meta-analysis by IARC the risk is approximately 25% greater than expected for women (based on data from 46 studies that included 6257 lung cancer case subjects) and 35% greater than expected for men (IARC Monographs V. 83 (2004): Tobacco Smoke and Involuntary Smoking [pdf]). See also the editorial commentary (BMJ (2005): Evidence is unfavourable for passive smoking) which cites correlations of secondhand smoke with cancer of the lung, pharynx, and larynx, as well as chronic obstructive pulmonary disease or emphysema, stroke, ischaemic heart disease, and all cause mortality, and the editorial of Ichiro Kawachi (BMJ (2005): More evidence on the risks of passive smoking), and E Cetti (Thorax (2005): Further evidence on the dangers of exposure to second hand tobacco smoke) who speculates that given the overwhelming weight of the evidence, it may now or soon be possible to reclassifying secondhand smoke-related deaths as "poisoning". And it has been independently established that secondhand smoke is associated with chronic obstructive pulmonary disease: as Eisner at al. concluded in their recent study (BMC Pulm Med (2006): Directly measured secondhand smoke exposure and COPD health outcomes), "There is no question that cigarette smoking is the dominant risk factor for COPD and is the most important factor driving the progression of airflow obstruction. Our results implicate SHS exposure as another important factor influencing disease severity and health status in this health condition".

    Furthermore, Adi Gazdar (Cancer Cell (2003): Environmental tobacco smoke, carcinogenesis, and angiogenesis - A double whammy?) observes that given that it has been established (Zhu et al., Cancer Cell (2003): Second hand smoke stimulates tumor angiogenesis and growth) that secondhand smoke promotes tumor growth, tumor angiogenesis, and an increase in growth factors and cells known to contribute to tumor angiogenesis, suggesting that the oncogenic effects of secondhand smoke are mediated in part by angiogenic effects of nicotine (and remember that the concentration of nicotine in sidestream smoke is greater than its concentration in mainstream smoke), then it can be concluded that not only is secondhand smoke harmful, but it is associated with many diseases other than cancer, and that given all the evidence it must be held that "while smokers may have the right to smoke, nonsmokers should have the right to be protected from harm resulting from the action of smokers".

    Finally, more recently, Peng Yin and colleagues (Lancet (2007): Passive smoking exposure and risk of COPD among adults in China: the Guangzhou Biobank Cohort Study) measured passive smoking at home and at the workplace in terms of density and the duration of exposure, finding that four subjects who were highly exposed to passive smoking, defined as more than 40 hours per week for more than 5 years, were 48% more likely to present with COPD (Chronic Obstructive Lung Disease) than were unexposed subjects. The accompanying Lancet commentary by Ana Menenez and Pedro Hallal (Lancet (2007): Role of passive smoking on COPD risk in non-smokers) conclude that "These results suggest that future anti-smoking policies should, in addition to targeting active smoking, also consider addressing passive smoking" and that these "findings, added to what is already known about the harmful effects of passive smoking, suggest that urgent strategies to reduce this exposure are needed".


  • SHS and Diabetes

    We have already observed above that increased insulin resistance is recognized to increase the heart disease risk, and the IRAS study showed that exposure to secondhand smoke can lead to an increase in insulin resistance (Henkin et al., Ann Epidemiol (1999): Cigarette Smoking, Environmental Tobacco Smoke Exposure and Insulin Sensitivity: The Insulin Resistance Atherosclerosis Study), and more recently another related adverse effect secondhand smoke has been found, namely an increased risk of glucose intolerance: Houston et al. (BMJ (2006): Active and passive smoking and development of glucose intolerance among young adults in a prospective cohort: CARDIA study) in their 15 year prospective study found that both active and passive smokers are more likely than nonsmokers to develop clinically relevant glucose intolerance or diabetes, with the association of such exposure with diabetes being greatest among white men and women. See also the accompanying editorial by Panagiotakos & Pitsavos (BMJ (2006): Passive smoking's role in diabetes) who notes that never smokers with secondhand smoke exposure experienced 35% higher risks of developing glucose intolerance than never smokers without passive exposure, concluding that sensibly that given the current state of matters, "most nonsmokers wish not to be exposed to tobacco smoke against their will".

  • Other Health Hazards Evidenced in the Report of the Surgeon General 2006

    The Report of the Surgeon General 2006 (see above) also presents methodologically compelling evidence and on that basis concludes that:

    • secondhand smoke exposure could increase the risk for sudden infant death syndrome (SIDS),
    • there is a causal relationship between secondhand smoke exposure from parental smoking and lower respiratory illnesses in infants and children
    • there is a causal relationship between parental smoking and middle ear disease in children, including acute and recurrent otitis media and chronic middle ear effusion
    • there is a causal relationship between parental smoking and cough, phlegm, wheeze, and breathlessness among children of school age
    • there is a causal relationship between parental smoking and ever having asthma among children of school age
    • there is a causal relationship between secondhand smoke exposure from parental smoking and the onset of wheeze illnesses in early childhood
    • there is a causal relationship between maternal smoking during pregnancy and persistent adverse effects on lung function across childhood
    • there is a causal relationship between exposure to secondhand smoke after birth and a lower level of lung function during childhood.

  • Other Health Hazards Independently Evidenced



Smoking Cessation

  • Nicotine Replacement Therapy (NRT)

    The main advantage of the passive-mode nicotine transdermal patch over the other active-mode NRT formulations is higher compliance: the patient applies the patch in the morning, rather than actively using one of the other NRT products throughout the day; compliance with the patch was 82% compared with gum (38%), spray (15%), and inhaler (11%), although these are derived from the clinical trial settings often higher than actual practice in the field (Hajek et al., Arch Intern Med (1999): Randomized Comparative Trial of Nicotine Polacrilex, a Transdermal Patch, Nasal Spray, and an Inhaler); note that nicotine transdermal patches deliver their nicotine more slowly than the active-mode NRT formulations, but nicotine plasma concentrations can become higher during the day on the nicotine patch use (especially if the patient fails to use the active mode NRT product as often as recommended).

    Although there may be individual variation in responses to the different forms of NRT, it appears that all are equally efficacious, and approximately double the smoking quit rate compared with placebo (Hughes et al., JAMA (1999): Recent Advances in the Pharmacotherapy of Smoking and Silagy et al., Cochrane Database System Rev (2004): Nicotine replacement therapy for smoking cessation; also A Molyneux, BMJ (2004): Nicotine replacement therapy - ABC of smoking cessation, Srivastava et al., BMJ (2006): Smoking cessation - ABC of chronic obstructive pulmonary disease, and Kolawoles et al., Am Family Physician (2006): Interventions to Facilitate Smoking Cessation; also Ford & Shilliday provide excellent smoking cessation guidance specifically oriented to the diabetic patient (Clin Diabetes (2006): Smoking and Diabetes: Helping Patients Quit)). One clinical practice point to note however is that nicotine patches may not always adequately protect against acute craving provoked by smoking-related stimuli, and for this reason patients who experience powerful breakthrough cravings not adequately controlled by transdermal nicotine alone, or withdrawal symptoms, may find it useful to supplement with one of the active-mode acute therapies (as per the PHS Report: Treating Tobacco Use and Dependence - Clinical Practice Guideline, cited above). In addition, with these acrive-mode acute-dosing products, both the amount and timing of doses can be titrated by the user whether used as the primary NRT, or as an as-needed supplement to the nicotine transdermal patch.

    Warning: It appears from field experience that underdosing may be the single greatest clinical challenge for successful use of these products: patients often commit a not uncommon therapeutic mistake by only using active-mode acute products in response to craving, rather than regularly throughout the day, but continuous use is essential to reduce overall cravings and prevent withdrawal symptoms from accumulating.

  • Clinical Summary: Comparison Of Smoking Cessation Therapies:


    • (source: Kolawoles et al., Am Family Physician (2006): Interventions to Facilitate Smoking Cessation)

  • Emerging Therapies:


    A number of additional agents are being studies for their potential use in smoking cessation: (1) rimonaban is a unique cannabinoid receptor agonist showing promise both in smoking cessation and independently for weight control, and given that many smokers who quit show a tendency to gain weight, this dual-mode agent may be of particular benefit, decreasing the likelihood of relapse during a quit attempt during which weight gain is a disincentive; (2) varenicline, a partial agonist of nicotinic receptors, that has also shown benefit in achieving and sustaining smoking abstinence; (3) there are currently three antinicotine vaccines in various stages of clinical trials (TA-NIC, NicVAX, and Nicotine-Qbeta), designed to induce antibodies against the nicotine molecule preventing the drug from reaching neural receptors that produce the normal effects of smoking; (4) some antidepressants besides bupropion may be of value (in particular, nortriptyline and doxepin), as well as the noradrenergic agonist clonidine.



    In conclusion, smoking cessation interventions are receiving considerable intensive research interest at this time, and new developments may help to transform the therapeutic landscape in the near future.



Consumer Resources:

  • Smokefree.gov
    (from Health and Human Services)
    Provides authoritative information and professional assistance for people trying to quit smoking.

  • Treating Tobacco Use and Dependence
    (from the Agency for Healthcare Research and Quality (AHRQ))
    A clinical practice guideline issued in June 2000 by the Public Health Service (PHS) providing evidence-based information on first-line pharmacologic therapies and counseling for patients trying to quit smoking.

  • Tobacco Information and Prevention Source (TIPS)
    (from the Centers for Disease Control and Prevention (CDC))
    Publications, data and statistics, educational materials, public health information campaigns, and more from the Office on Smoking and Health.

  • Involuntary Smoking Database
    A searchable database of research abstracts of the key articles on secondhand smoking and disease outcomes that are cited in the 2006 Surgeon General’s Report (see above), reflecting the most recent findings in the scientific literature, along with qualitative data, and quantitative data charted graphically.

  • Smoke-free Homes Program
    A resource from the Environmental Protection Agency (EPA) promoting a smoke-free environment at home.

  • Tobacco Cessation - You Can Quit Smoking Now!
    Provides up to date information and extensive resource links to help people quit smoking, and to help health care professionals treat tobacco use and dependence.

  • Smoking Cessation
    Extensive collection of categorized resource links on smoking cessation, from MedlinePlus.

  • Products To Help You Stop Smoking
    Clear illustrated guide to each of the smoking cessations products (all the nicotine replacement therapies (NRTs) and the antidepressant bupropion.

  • Quit Smoking Action Plan
    An easy-to-follow three-step plan for quitting smoking from the American Lung Association, each step illustrated with detailed charts.

  • SLATI: State Legislated Actions on Tobacco Issues
    Unique comprehensive and searchable database of smoking laws, tobacco laws and public smoking policy, including a state-by-state clickable map., from the American Lung Association.

  • Smoking Cessation
    Collection of government resources on quitting smoking from the National Institute of Health (NIH).

  • New York State Smokers’ Quitline
    1-866-NY-QUITS (1-866-697-8487)
    A service of NYS, the quitline is staffed by trained Quitline Specialists to help with smoking quit plans, and provides information for NYS residents about local stop smoking programs at various hospitals and other centers, and will also provide a free starter kit of nicotine patches, gum or lozenges for eligible NYS smokers.

  • New York State Smokers' Quitsite
    Comprehensive site providing extensive resources for NYS residents to help quit smoking.



Best Strategy for Quitting Smoking: A Survival Guide

STEP ONE: Start with the Nicotine Transdermal Patch

    This form of nicotine replacement therapy is the easiest to deal with, applied anywhere between waist and neck (like upper arm or shoulder). According to studies, the most effective is the NicoDerm CQ patch, (21 mg/24 hours) which comes in 7-, 14-, and 21-mg / per day dose strengths, intended to be worn for 24 hours.

    • Which Strength To Choose?
      The rule with the NicoDerm CQ patch is that if you're a smoker who uses more than 10 cigarettes a day:

      • start with the 21-mg/day patch for the first 6 weeks
      • after that, switch to the 14-mg/day strength for 2 weeks
      • then after the eight week, use the 7-mg dose for another 2 weeks, thus ending the smoking cessation process after 10 weeks.


    • How Many Hours Per Day To Wear?

      • This patch is designed to be worn for 24 hours, but you can remove it after 16 hours, before bedtime, if you find your sleep is disturbed.
      • If you can tolerate it, and most people can, wear throughout the day, because it will control cravings, not only during the morning hours (so-called morning craving), but also throughout the day, and the full-day approach yields greater reductions in anxiety, irritability, and restlessness.

STEP TWO: While On the Patch, Supplement with "Rescue" Nicotine Gum for Breakthrough Cravings

  • How To Get Over Breakthrough Cravings

    • The nicotine patch is designed to work smoothly throughout the 24-hour day, but occasionally you might get an especially strong "breakthrough craving" sometime during the day, so a good trick is to use the nicotine gum as a rescue aid to get over the intense craving.

    • And remember, such breakthrough cravings are often triggered situationally, as by seeing someone else smoke, or when emotionally upset, or a stressful meeting or encounter, and many smokers find these episodes of sudden craving difficult to resist, so instead of giving in, let the nicotine gum get you over the craving, no matter how often this may happen.

  • How Many Hours Per Day To Chew?
    Here's the rule:

    • For smokers who use less than 25 cigarettes per day, use the 2-mg dose of the nicotine gum
    • For smokers who regularly smoke more than 25 cigarettes per day, use the 4-mg dose.
    • When in doubt, or if your a very heavy smoker or experience very intense cravings, use the 4-mg dose which will be more effective.

STEP THREE: For Highly Dependent Smokers, Add Bupropion (Wellbutrin / Zyban) to the Nicotine Patch

  • If you're a very heavy smokers (two or more packs a day), or if you know you're very dependent because you've already tried quitting and failed or relapsed after a while, then a very effective trick is to combine both the nicotine patch plus the antidepressant called bupropion (brand names: Wellbutrin, Zyban); this is a prescription product that's been found very effective by itself for quitting smoking, but the combo with the patch is amazingly effective for "hard" cases.

  • The dose is 150 mg per day for three days, then twice per day for seven to 12 weeks, as needed.


SUMMARY of the Three Step Quit Smoking Program

    • The Program:
      • Use the nicotine patch, and supplement it as needed with the nicotine gum to get over any breakthrough cravings;
      • if you are very dependent, then speak to you doctor about adding Wellbutrin / Zyban.

    • This three step program for quitting takes about 10 - 12 weeks, and represents the best advice for the most effective regimen,
      based on the best evidence to date.

    • To learn more about which part of this program (nicotine patch, nicotine gum, and antidepressant, if needed),
      check out the consumer resources above, and of course if you're going to need the antidepressant (a prescription-only product),
      check with doctor to make sure it's appropriate for you and your health condition.

 
 

Copyright © 2009. Constantine Kaniklidis