Stigma, Guilt, and Shame

Stigma, implicit bias, and nihilism are corrupting influences which reduce an active smoker’s interest in the pursuit of tobacco dependence treatment across the entire lung cancer care spectrum. In fact, the stigma associated with lung cancer differentiates LCS process from all other screening. Many smokers blame themselves and also accept the blame of others for their smoking-related cancer diagnosis or their elevated risk. Studies have identified that patients with lung cancer often feel stigmatized because lung cancer tends to be associated with previous smoking.

Among patients diagnosed with lung cancer, internalized stigma such as self-blame, guilt, and regret, has been associated with increased depressive symptoms, delays in medical help-seeking, and lower QOL. ^, These factors can lead to unnecessary delay in enrolling in screening programs and diagnosis, engagement in clinical trials, and reluctance to comply with tobacco dependence treatment. ^, Recognizing the importance of identifying lung cancer stigma, Ostroff and colleagues developed the Lung Cancer Stigma Inventory, a reliable and valid assessment of 3 facets of stigma in lung cancer care settings: internalized stigma (directing negative societal attitudes toward oneself), perceived stigma (negative appraisal and devaluation from others), and constrained disclosure (discomfort in sharing one’s lung cancer status with others).

Acceptance and Commitment Therapy for Lung Cancer Stigma, a patient-focused cognitive behavioral intervention to reduce the self-blame, guilt, and inhibited disclosure is currently being studied. An urgent need exists for development and testing of additional psychosocial interventions that target lung cancer stigma as well as educational materials for clinicians and the general public to address stigma and implicit bias toward smokers. These materials should include information on how common smoking was in the days when many of those eligible for screening started smoking, describe the aggressive media campaigns by the tobacco industry to white-wash the attendant health risks, and delineate how tobacco control policies, in an effort to reduce the social acceptability of smoking, denormalized smoking and stigmatized smokers through positioning smoking as an environmental health issue (secondhand smoke), legislating smoke-free public areas and workplaces, and portraying smoking as a personal choice ultimately leading to a horrible death. Clinicians should approach smokers with sensitivity when discussing smoking status and actively engage in efforts to minimize the stigma associated with continued smoking, especially after the diagnosis of cancer.

Low Socioeconomic Status Barriers

SES is strongly associated with smoking status, the most important risk factor for lung cancer. Smoking prevalence in low SES and other vulnerable populations such as those with mental health illness and substance use disorders has declined at negligible rates compared with the general population. Low SES remains a risk factor for lung cancer diagnosis and mortality even after adjustment for smoking behavior and area-level measures of SES are associated with lung cancer risk in current and shorter-term former smokers only in this population. Conversely, an increase in SES over time was related to a decrease in mortality from respiratory disease, but not from lung cancer. The lack of financial resources or the ability to make healthy financial choices directly undermine the goals of early detection of lung cancer. Patients with lung cancer who do not receive therapy are more likely to be older, not white, male, and unmarried, to have no insurance or public insurance other than Medicare, to live in a low SES neighborhood, to have been seen at a non-National Cancer Institute cancer center hospital or hospital serving lower SES patients, and to have larger tumors. Therefore, SES significantly mediates racial/ethnic cancer survival disparities for several cancers including lung cancer.

Studies demonstrate that patient navigators, laypersons from the community who guide patients through the health care system to connect them with services they may have difficulty accessing, are a promising approach to promote smoking cessation and reduce disparities in cancer screening, diagnosis, and treatment. Among smokers residing in public housing, a smoking cessation intervention delivered by peer health advocates trained in motivation interviewing, basic tobacco treatment skills, and patient navigation increased tobacco abstinence at 12 months. In the LCS setting, a patient navigation program implemented in community health centers increased LDCT screening among high-risk current smokers.

Financial incentives promotes tobacco treatment engagement and smoking cessation in low SES populations. A randomized trial of low income smokers in the primary care setting showed that patient navigation combined with financial incentives increased 12-month tobacco abstinence. Incentives for stopping smoking has not been tested among patients undergoing LCS. A clinical trial in the LCS setting is underway to test the effectiveness of 4 approaches to help patients stop smoking, including an approach that delivers payments for successfully quitting.

Clinician and System Barriers

Clinicians’ experiences and views on smoking cessation services and perceived organizational constraints in settings considered teachable moments (LCS programs and cancer diagnosis) influence change in smoking behavior. ^, In the LCS setting, studies suggest that smokers with a screen-detected pulmonary nodule are more likely to quit smoking than those with normal results, and that discussing a screen-detected nodule is an opportunity to initiate a conversation about the desire to quit smoking. ^, Yet research suggests that physicians often missed this opportunity, expressing concern about overwhelming patients by discussing smoking cessation during delivery of abnormal results. Similarly, in the cancer diagnosis context, clinicians avoid talking about smoking because of competing priorities and concerns of implying and/or exacerbating patients’ guilt of smoking, even though patients often expected some conversation on smoking cessation. Barriers include time constraints, lack of awareness about smoking cessation services, and perceptions of responsibility for talking about smoking cessation. Thus, despite improved survival in patients with cancer who quit cigarettes, ^, many opportunities to promote smoking cessation are missed. ^,

Tobacco cessation treatment pathways for patients with cancer have been developed that outline individualized treatment plans. However, within the lung cancer care continuum, tobacco treatment needs to be a team effort. Whether patients are interacting with a provider in the LCS setting, pulmonologists during diagnosis, and/or medical, radiation, and surgical oncologists during treatment, the unique challenges including stigma and cancer-related distress should be addressed. Strategies should include providing clinical evidence on the adverse effects of smoking on treatment outcomes and informing patients about the benefits of stopping smoking on side effects, treatment outcomes, and reduction in likelihood of recurrence. In addition, system-level changes are needed to promote tobacco treatment across lung cancer care. Such changes include incorporating reminders into practice systems, allocating resources for the development of tobacco treatment programs embedded in the cancer care setting, and gaining competency in treating tobacco dependence either online ( https://www.cdc.gov/tobacco/campaign/tips/partners/health/index.html ) or by attending specialized training in tobacco treatment ( http://ctttp.org/accredited-programs/ ).

A recently recognized systemic barrier to tobacco treatment is the issue of structural stigma. The unintended effects of public policies and social norms aimed to reduce smoking can sometimes have adverse effects on health care access and availability of tobacco dependence treatment. For example, the recent United States Department of Housing and Urban Development policy to expand smoke-free public housing needs to be intimately tethered to reliable tobacco treatment services to avoid homelessness and destabilization of families. Clinicians need to be cognizant of the upstream social determinants of health that affect a smoker’s engagement with the health system and how stigmatization of smoking validates discrimination by potential employers (eg, employers absorb a higher net cost of more than $6000 per year when they hire a smoker rather than a nonsmoker, reinforcing a low SES status and reducing access to medical care). There has been a call for medical education to include training in “structural competency,” in which knowledge about diseases is combined with analysis of social systems so that the structural determinants of stigma and health can be addressed.

Understanding Nicotine Addiction

Tobacco dependence is a chronic relapsing disease that is sustained by nicotine addiction. Exogenous nicotine acts on nicotinic acetylcholine receptors (nAChRs) to activate brain dopamine release resulting in the rewarding effects of smoking cigarettes. By engaging with nicotinic receptors in distinct locations (ventral tegmental area [VTA]), nicotine generates a powerful, but incorrect survival signal. In addition, nicotine promotes learned associations (eg, exposure to people, places, or things previously associated with smoking cigarettes) that become persistent over time, placing people at risk for lifelong relapse.

Opt-Out Approaches

Studies suggest that only about 30% of current smokers are ready to quit within the next 30 days. Proactive approaches to offering guideline-recommended tobacco treatment to all smokers regardless of readiness to quit and allowing patients to refuse treatment (“opt-out”) have been shown to have both a high acceptance rate and to increase smoking abstinence. Among participants who quit smoking cigarettes, almost half stated that during initial assessment they were not ready to stop smoking cigarettes, underscoring the importance of engaging all smokers with tobacco treatment, regardless of motivation to quit smoking.

Pharmacotherapy

Pharmacotherapy effectively reduces withdrawal symptoms, and the combination of medication with counseling is more effective than either intervention alone in promoting smoking abstinence. The 7 US Food and Drug Administration (FDA)-approved medications for tobacco treatment include: (1) 5 types of nicotine replacement therapy (NRT) (over the counter: nicotine lozenges, gum and patches; prescription only: nicotine inhalers and nasal spray); (2) bupropion; and (3) varenicline.

Nicotine replacement therapy

NRT, an agonist at the nicotinic cholinergic receptors, delivers nicotine safely and prevents withdrawal symptoms. NRT is a nonaddictive, safe alternative to smoking because there is a much slower release and absorption of nicotine into the blood compared with the immediate nicotine peaks produced by cigarettes. Combination therapy with a transdermal nicotine patch (which delivers continuous dosing to provide steady levels of nicotine with peak blood levels of nicotine at 2–4 hours) and the nasal spray, inhaler, gum, or lozenge (delivers “as-needed” dosing in response to acute cravings; blood levels of nicotine peak 5 to 10 minutes after taking the nasal spray or inhaler and 20 minutes after using the gum or lozenge) is more effective in promoting prolonged abstinence, with a risk ratio of 1.34 compared with use of any single product. The FDA recommends 12 weeks of treatment with NRT, although treatment specialists often extend duration based on patient factors such as cigarette cravings and confidence to remain quit ( Table 1 ). No harm was reported in a randomized clinical trial with extended NRT use.

Table 1

FDA-approved pharmacotherapy to treat tobacco dependence: nicotine replacement therapy

Nicotine transdermal patch
Standard dosage • >10 cigs/d: 21 mg/d × 4–6 wk 14 mg/d × 2 wk 7 mg/d × 2 wk • ≤10 cigs/d: 14 mg/d × 6 wk 7 mg/d × 2 wk Duration: 8–10 wk	Dosing modifications • Pretreatment: Consider precessation treatment with nicotine patch before quit date • Higher dosage: >40 cigs/d: consider 42 mg/d • Combination + extended therapy: Consider >13 wk nicotine patch + short acting NRT as needed	Adverse events • Sleep disturbances, local skin reactions, and headache Precautions • Recent MI within 2 wk, serious arrhythmias, unstable angina • Adolescents <18 y • Pregnancy and breastfeeding
Nicotine lozenge: blood levels of nicotine peak at 20 min
Standard dosage • 1st cig <30 min after waking: 4 mg • 1st cig >30 min after waking: 2 mg Weeks 1–6: 1 lozenge q 1–2 h Weeks 7–9: 1 lozenge q 2–4 h Weeks 10–12: 1 lozenge q 4–8 h • Max = 20 lozenges/d Duration: up to 12 wk	Dosing modifications • Combination + extended therapy: consider >13 wk transdermal patch + gum as needed	Adverse events • Cough, nausea, hiccups, heartburn, flatulence, insomnia, and headache Precautions • Recent MI within 2 wk, serious arrhythmias, unstable angina • Adolescents <18 y Pregnancy and breastfeeding
Nicotine gum: blood levels of nicotine peak at 20 min
Standard dosage • 1st cig <30 min after waking: 4 mg • 1st cig >30 min after waking: 2 mg Weeks 1–6: 1-piece q 1–2 h Weeks 7–9: 1-piece q 2–4 h Weeks 10–12: 1-piece q 4–8 h • Max = 24 pieces/d • Duration: up to 12 wk	Dosing modifications • Combination + extended therapy: consider >13 wk transdermal patch + gum as needed	Adverse events • Hiccups, dyspepsia, excess salivation; side effects from incorrect chewing (mouth and jaw soreness, nausea/vomiting) Precautions • Recent MI within 2 wk, serious arrhythmias, unstable angina • Adolescents <18 y • Pregnancy and breastfeeding
Nicotine inhaler blood: levels of nicotine peak at 5–10 min
Standard dosage • 6–16 cartridges/d Initially use 1 cartridge q 1–2 h as needed and at least 6 cartridges per day • Max = 16 cartridges/d • Prescription only • Duration 3–6 mo	Dosing modifications • Combination + extended therapy: consider >13 wk transdermal patch + ad lib inhaler	Adverse events • Rhinitis, mouth/throat irritation, cough, dyspepsia, hiccups, and headaches Precautions • Recent MI within 2 wk, serious arrhythmias, unstable angina • Adolescents <18 y • Pregnancy and breastfeeding
Nicotine spray: blood levels of nicotine peak at 5–10 min
Standard dosage • 8–40 doses/d One dose = 2 sprays (1 spray in each nostril) Initially use 1–2 doses/h and at least 8 doses/d • Max = 5 doses/h or 40 doses (80 sprays)/d • Prescription only • Duration 3–6 mo	Dosing modifications • Combination + extended therapy: consider >13 wk transdermal patch + nasal spray as needed	Adverse events • Rhinitis, sneezing, nasal/throat irritation, cough, and headache Precautions • Recent MI within 2 wk, serious arrhythmias, unstable angina • Adolescents <18 y • Pregnancy and breastfeeding

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