Abstract
Background: Precision interventions using biological data may enhance smoking treatment, yet are understudied among smokers who are disproportionately burdened by smoking-related disease.
Methods: We surveyed smokers in the NCI-sponsored Southern Community Cohort Study, consisting primarily of African-American, low-income adults. Seven items assessed attitudes toward aspects of precision smoking treatment, from undergoing tests to acting on results. Items were dichotomized as favorable (5 = strongly agree/4 = agree) versus less favorable (1 = strongly disagree/2 = disagree/3 = neutral); a summary score reflecting generalized attitudes was also computed. Multivariable logistic regression tested independent associations of motivation (precontemplation, contemplation, and preparation) and confidence in quitting (low, medium, and high) with generalized attitudes, controlling for sociodemographic factors and nicotine dependence.
Results: More than 70% of respondents endorsed favorable generalized attitudes toward precision medicine, with individual item favorability ranging from 64% to 83%. Smokers holding favorable generalized attitudes reported higher income and education (P < 0.05). Predicted probabilities of favorable generalized attitudes ranged from 63% to 75% across motivation levels [contemplation vs. precontemplation: adjusted odds ratio (AOR) = 2.10, 95% confidence interval (CI), 1.36–3.25, P = 0.001; preparation vs. precontemplation: AOR = 1.83, 95% CI, 1.20–2.78, P = 0.005; contemplation vs. preparation: AOR = 1.15, 95% CI, 0.75–1.77, P = 0.52] and from 59% to 78% across confidence (medium vs. low: AOR = 1.91, 95% CI, 1.19–3.07, P = 0.007; high vs. low: AOR = 2.62, 95% CI, 1.68–4.10, P < 0.001; medium vs. high: AOR = 0.73, 95% CI, 0.48–1.11, P = 0.14).
Conclusions: Among disproportionately burdened community smokers, most hold favorable attitudes toward precision smoking treatment. Individuals with lower motivation and confidence to quit may benefit from additional intervention to engage with precision smoking treatment.
Impact: Predominantly favorable attitudes toward precision smoking treatment suggest promise for future research testing their effectiveness and implementation.
Introduction
Racial, economic, and regional disparities remain in tobacco use, with minority, low-income, and Southern-dwelling smokers all bearing a disproportionate burden of smoking-related disease and mortality (1, 2). Precision medicine that tailors smoking treatment to individuals' genetic characteristics is a promising approach for reducing smoking-related disparities. However, it remains unclear whether precision approaches will be taken up and used among populations of smokers who are disproportionately burdened by tobacco (i.e., based on their race/ethnicity, income, region of the United States, or the intersection of these; refs. 1, 2).
Past work supports the efficacy of precision approaches in promoting smoking cessation (3–9). Lerman and colleagues (5) demonstrated that smokers with faster nicotine metabolism [assessed by the nicotine metabolite ratio (NMR), a genetically informed biomarker of hepatic nicotine metabolism] assigned to receive varenicline were twice as likely to quit smoking as those assigned to the nicotine patch. Among slower metabolizers, these treatments were equally effective, but side effects with varenicline were more pronounced. However, in that study, smokers were not informed of their NMR results, leaving open the question of how they might react to this information if it were incorporated into smoking treatment. Other work has demonstrated that smokers who received results from a commercially available test for a gene-based lung cancer risk score (Respiragene; refs. 7, 8) were more likely to undergo lung cancer screening, use nicotine replacement therapy, and quit smoking. Further enthusiasm for these specific precision approaches is bolstered by evidence of their acceptability among smokers (10–13).
However, for precision approaches to promote health equity, they must be broadly implementable, especially among groups suffering from tobacco-related disparities. Evidence-based treatments for smoking cessation are underutilized among disproportionately burdened smokers (14–16) for many reasons, including unfavorable attitudes toward some of these treatments (17–20). Research in other healthcare contexts shows racial/ethnic minorities have more concerns about genetic testing and precision medicine than Whites, believing genetic testing or precision medicine may be misused, lead to racial discrimination, or do more harm than good (21, 22). However, preliminary findings support the acceptability of precision approaches for smoking among minorities. Shields and colleagues (23) found that African-American smokers were more likely than White smokers to be willing to undergo genetic testing to be matched to optimal treatment. Another small study of primarily African-American smokers found that participants who had already expressed interest in receiving genetic risk results responded favorably to them and that quit attempts increased after receiving results (24). These preliminary findings support the hypothesis that precision approaches for smoking will be equitably taken up and utilized.
Another key step to successful clinical translation is understanding potential predictors of engagement in precision smoking treatment. Lack of motivation and confidence are known barriers to successful smoking cessation, and may be used by smokers or their providers as rationale to forego the use or offer of smoking treatments, respectively (25, 26). However, recent research and updated guidelines suggest that services should be offered to smokers across the motivational spectrum (27–29). Understanding whether smokers lacking motivation or confidence would be willing to use precision treatments could help researchers and clinicians identify strategies to increase engagement in this population of smokers.
We build on existing knowledge by concurrently examining attitudes toward two promising precision approaches (NMR, which can be leveraged to select pharmacotherapy, and Respiragene, gene-based risk testing, which can be leveraged to enhance motivation to make healthy behavior change) and behavioral changes based on these test results. We examined these attitudes among participants of the Southern Community Cohort Study (SCCS), a population of disproportionately burdened smokers. We hypothesized that precision smoking treatment would generally be viewed favorably, and that favorable attitudes would be more likely among motivated, confident smokers.
Materials and Methods
Study population
The SCCS is a prospective cohort study sponsored by the NCI and initiated in 2001 (30). The SCCS was established to identify causes of disparities in cancer and other health outcomes. The cohort includes approximately 85,000 adults throughout the southeastern United States that have been well-characterized by over 15 years of participation in the study. The cohort consists primarily of African-American, low-income adults, members of demographic groups that are traditionally underrepresented in health research. A majority of the cohort was recruited at community health centers, and nearly 25% of respondents currently reside in rural areas. The study also features a large biorepository with genetic data for approximately 90% of participants.
Participants
Participants were eligible for inclusion in this study's Precision Smoking Cessation Survey, conducted in 2017, if they were active SCCS participants residing in Tennessee or Mississippi and identified as current smokers in the SCCS Follow-up 3 survey, conducted between 2015 and 2018 (N = 1,407). A total of 988 responses to the Precision Smoking Cessation Survey were collected, yielding a response rate of 70%. Of these, 143 were excluded (72 had quit smoking since SCCS Follow-up 3; 31 lacked data on smoking status, and 40 did not respond to at least two thirds of the precision medicine items, a requirement for inclusion in the analysis) yielding an analytic sample of 845 smokers. Compared with smokers with complete data on attitudes toward precision medicine, those missing <1/3rd of data tended to have higher nicotine dependence, as defined by the Heaviness of Smoking Index [X2 (2, 870) = 15.23; P < 0.001]. Further exclusions based on missing data were made on an analysis-by-analysis basis (see Statistical Analyses). All participants provided written informed consent before enrollment in the SCCS. This study was conducted in accordance with recognized ethical guidelines (e.g., Declaration of Helsinki, CIOMS, Belmont Report, and U.S. Common Rule) and was approved by institutional review boards at Vanderbilt University, Meharry Medical College, and Tennessee State University (Nashville, TN).
Measures
Attitudes toward precision medicine.
Seven items assessed attitudes toward different aspects of precision treatment of smoking (Supplementary Table S1). Items were designed with iterative feedback from a Community Advisory Board consisting of current and former smokers to ensure the use of simple, understandable language. They were designed to capture attitudes toward both pharmacogenetics and gene-based lung cancer risk assessment, with a focus on clinically relevant behaviors (i.e., taking the tests, taking medication, getting lung cancer screening, and quitting smoking). At the time of survey construction, Respiragene was commercially available as a buccal swab, whereas NMR was often conducted via blood test; item wording reflects these test modalities. Items were rated on a 5-point scale (1 = strongly disagree and 5 = strongly agree), responses were dichotomized to reflect favorable (4 = agree and 5 = strongly agree) versus not favorable attitudes (1 = strongly disagree, 2 = disagree, and 3 = neutral).
While each individual item taps into a different aspect of precision smoking treatment, they theoretically also capture an underlying construct reflecting more generalized attitudes toward precision smoking treatment. To create a measure of generalized attitudes (see Statistical Analyses and Results), we first calculated the mean of all 7 items (mean = 3.77, SD = 0.95) and dichotomized mean total scores to correspond to the cutoffs used for the individual items reported above (<3.5 = not favorable and ≥3.5 = favorable), thus facilitating comparison between individual items and the summary statistic.
Motivation to quit.
Assessment of motivation to quit was guided by the two items from the transtheoretical model (31): “are you thinking of quitting cigarettes in the next 6 months?” (yes/no) and “are you planning to quit smoking in the next 30 days?” (yes/no), producing three groups (precontemplation = not yet thinking of quitting; contemplation = thinking about quitting in the next 6 months but not planning to quit in the next 30 days; preparation = planning to quit in the next 30 days).
Confidence in quitting.
A single item assessed confidence in quitting, “I am confident that I can quit smoking,” rated on a 5-point scale (1 = strongly disagree to 5 = strongly agree; refs. 32, 33). Responses were categorized into low (disagree and strongly disagree), medium (neutral), and high (strongly agree and agree) confidence levels.
Individual characteristics.
Sociodemographics.
Sociodemographic items included age, sex, race and ethnicity, and highest education completed (assessed at SCCS baseline, 2002–2009), annual household income and insurance status (assessed at SCCS follow-up, 2015–2018).
Nicotine dependence.
Nicotine dependence was calculated via the Heaviness of Smoking Index (HSI; ref. 34), a metric based on self-reported time to first cigarette (within 5 minutes, 6–30 minutes, 31–60 minutes, and after 60 minutes) and number of cigarettes smoked per day.
Lung cancer risk.
Predicted lung cancer risk for each respondent was calculated using the Tammemagi risk predictor, which incorporates age, education, race/ethnicity, body mass index, family history of lung cancer, personal history of cancer, diagnosis of chronic obstructive pulmonary disease, emphysema or chronic bronchitis, current smoking status, current cigarettes per day, and years smoked (35). These data were collected through participation in the SCCS baseline and follow-up surveys. This calculated risk score was included for descriptive purposes to better characterize the sample, but the study was not designed to inform participants of this information. Because respondents were not informed of their predicted lung cancer risk scores, it was not expected that the scores would be associated with attitudes toward precision smoking treatment. Thus, this variable is not included in hypothesis testing.
Statistical analyses
Statistical analyses were conducted using IBM SPSS Statistics 25 and Stata 15 SE. We conducted an exploratory factor analysis and examined interitem correlations to calculate a summary score reflecting generalized attitudes toward precision smoking treatment. Next, we tested whether generalized attitudes toward precision smoking treatment differed across demographic and smoking-related factors, using t tests for continuous variables and χ2 tests for both ordinal and nominal variables. These analyses used data from the full analytic sample (n = 845).
Multivariable logistic regression tested associations between motivation (precontemplation, contemplation, and preparation) and confidence in quitting (low, medium, and high) with generalized attitudes toward precision treatment of smoking, adjusting for sociodemographic characteristics (age, race, sex, education, and insurance) and nicotine dependence. The effects of these covariates were also explored. For each level of motivation and confidence, we calculated the average predicted probability of holding favorable generalized attitudes using the margins posttest in Stata. This test averages the estimates of each individual's probability of holding favorable generalized attitudes if all covariates are unchanged and the exposure variable is set to a given value (e.g., low confidence). Respondents with missing data on either confidence or motivation (n = 50) or on one or more covariates (n = 57) were excluded, resulting in a sample of 738 smokers for this analysis. Compared with those with complete data, smokers missing data tended to have lower levels of education [χ2(2, 823) = 10.91; P = 0.004] but were similar across other factors. Income was not included in this analysis due to the amount of missing data in this variable. However, including income as an additional covariate did not change the pattern of results from that reported below.
Results
Attitudes toward precision treatment
Factor analysis of the seven survey questions relating to attitudes toward precision treatment of smoking revealed that a single factor explained 61% of total variance in responses. In the unrotated factor matrix, factor loadings for the seven individual items on the first factor ranged from 0.43 to 0.93. Furthermore, interitem correlations revealed moderate to strong correlations across individual items (Table 1), and Cronbach's alpha of 0.89 supported scaling items to form a single construct.
Interitem correlations for each aspect of attitudes toward precision smoking treatmenta
Overall, 71% of smokers held favorable generalized attitudes toward precision smoking treatment (Fig. 1). For individual items, favorability of each aspect of precision treatment ranged from 64% to 83%. The blood test for pharmacotherapy selection based on nicotine metabolism was less likely to be rated favorably (item 2 = 64%, item 1 = 69%), whereas the saliva test for lung cancer risk was most likely to be rated favorably (item 5 = 79%, item 6 = 81%, and item 7 = 83%). Within these categories, responses were well distributed. The modal “favorable” response was “4 = agree” for each item, although approximately 1/3 to 1/2 of “favorable” responses indicated strong agreement. Within “not favorable” responses, strong disagreement was the most common response to items 1–4, while a neutral response was most common for items pertaining to the saliva testing for lung cancer risk (5–7).
Attitudes toward precision smoking treatment. Proportion of smokers endorsing favorable (vs. not favorable) generalized attitudes (top) and attitudes toward aspects of precision smoking treatment.
Baseline characteristics of the sample and relation to attitudes
Smokers recruited through the SCCS were predominantly African-American and low income. Approximately one third of the sample was considered at high risk of developing lung cancer on the basis of predicted lung cancer risk score (Table 2). Compared with respondents without favorable generalized attitudes toward precision smoking treatment, those with favorable attitudes tended to be younger, report higher income and education, have private insurance or Medicare, have lower nicotine dependence, and have higher motivation and confidence to quit smoking.
Sociodemographic characteristics, nicotine dependence (HSI), predicted lung cancer risk, and motivation and confidence across generalized attitudes toward precision treatment
Multivariable regression results
Association between motivation and attitudes.
Controlling for sociodemographic characteristics and nicotine dependence, the odds of endorsing favorable generalized attitudes were directly related to motivation to quit (Table 3). Compared with smokers in precontemplation, smokers in contemplation [adjusted odds ratio (AOR) = 2.10; 95% confidence interval (CI), 1.36–3.25; P = 0.001] and preparation (AOR = 1.83; 95% CI, 1.20–2.78; P = 0.005) had more favorable generalized attitudes. Smokers in contemplation did not significantly differ from those in preparation (AOR = 1.15; 95% CI, 0.75–1.77; P = 0.52). Adjusted predicted probabilities of endorsing favorable attitudes were ≥63% across all levels of motivation (see Fig. 2).
Results of regression analysis predicting generalized attitudes toward precision smoking treatment (n = 738)a,b
Associations of motivation and confidence with generalized attitudes toward precision smoking treatment. Predicted probabilities of having favorable generalized attitudes toward precision smoking treatment across levels of motivation (top) and confidence (bottom) are based on results of multivariable logistic regression adjusting for age, sex, race/ethnicity, education, insurance, and nicotine dependence (n = 738).
Association between confidence and attitudes.
Odds of endorsing favorable attitudes were also directly related to confidence in quitting (see Table 3). In adjusted models, compared with smokers with low confidence, those with medium (AOR = 1.91; 95% CI, 1.19–3.07; P = 0.007) and high (AOR = 2.62; 95% CI, 1.68–4.10; P < 0.001) confidence had more favorable generalized attitudes. Smokers with medium confidence did not significantly differ from those high in confidence (AOR = 0.73; 95% CI, 0.48–1.11; P = 0.14). Adjusted predicted probabilities of endorsing favorable attitudes were ≥59% across all levels of motivation (see Fig. 2).
Associations between demographic factors, nicotine dependence, and attitudes.
After adjustment, smokers who were younger (AOR = 0.96; 95% CI, 0.93–0.99; P = 0.02), had greater than a high school education (vs. less than high school; AOR = 1.61, 95% CI 1.03–2.54, P = 0.04), or had private insurance (AOR = 2.29; 95% CI 1.00–5.23; P = 0.05) remained more likely to hold favorable attitudes toward precision smoking treatment. In addition, African-Americans were 53% less likely than Whites to hold favorable attitudes (AOR = 0.47; 95% CI, 0.27–0.83; P = 0.009). There was no significant effect of nicotine dependence after adjustment for other variables in the model.
Discussion
Among over 800 low-income, southern-dwelling, predominantly minority smokers in the SCCS, 71% endorsed favorable attitudes toward precision approaches to smoking cessation. Smokers with greater motivation and confidence had over two times the odds of endorsing favorable attitudes than those at the lowest levels. Yet approximately 60% of those with the lowest levels of confidence and motivation still endorsed precision approaches, suggesting that intervention research and clinical implementation of precision approaches should be inclusive of smokers across the motivational and confidence spectrums. Similarly, despite less positive attitudes toward precision smoking treatment among older, African-American, and less highly educated smokers, endorsement remained generally high. Together, these findings provide evidence that precision smoking treatment will be well-received and could promote behavior change among disproportionately burdened smokers.
This study is the first to concurrently document the acceptability of NMR, a genetically informed biomarker for nicotine metabolism, Respiragene, a gene-based lung cancer risk assessment, and participants' hypothetical estimates of their own behavior change based on these tests results. Results add further evidence to the promise of using precision approaches for smoking treatment among disproportionately burdened groups (23, 24). The personalized nature of these approaches may increase their acceptability relative to other existing treatments such as counseling and medication, which tend to be viewed less favorably by members of disproportionately burdened groups (17–20). Data also support combining attitudes toward these varied aspects of precision treatment into a single measure of generalized attitudes toward precision smoking treatment, which will facilitate measurement and analysis of these and similar approaches in future work.
Results highlight the opportunity of integrating precision approaches into clinical care to improve health outcomes. For example, past work suggests that lung cancer screening is associated with 20% relative reduction in mortality (36), yet in 2016, only 1.9% of eligible smokers were screened, with screening rates in the Southern United States being among the lowest (37). Notifying patients of their lung cancer risk using Respiragene may motivate engagement in smoking treatment; 83% of respondents in our sample reported that they would be more likely to get lung cancer screening if their genetic test result suggested they were at high risk of lung cancer. Given that nearly one third of the sample is considered at high risk of developing lung cancer, this increased rate of lung cancer screening would likely result in lives saved. In addition, 64% of smokers in this sample said they would take medication based on results of a blood test, and matching patients to medication based on NMR status can double the efficacy of medication for faster metabolizers while minimizing side effects for slower metabolizers (5).
Integrating precision approaches with existing motivational and confidence building tools may increase the impacts of each. For example, motivational interviewing, a style of counselling aimed at increasing motivation by addressing patients' ambivalence toward behavior change, has been widely applied in clinical settings with small to moderate effects (38, 39). These data suggest a threshold effect of increased motivation and confidence, with more favorable attitudes among smokers with at least moderate (relative to low) levels of motivation and confidence, but no added benefit to being highly motivated or confident. It is possible that for smokers at the lowest levels of motivation and confidence, small increases in these factors may be enough to facilitate engagement in precision treatment. Incorporating precision approaches with motivational interviewing techniques may maximize impact on smoking cessation for all smokers, but especially those from disproportionately burdened groups who lack confidence or motivation. Yet another application of these tests lies in improving efficiency of care by reducing waste and cost. For example, a 2-fold greater efficiency of lung cancer screening can be achieved by using this gene-based approach to assessing lung cancer risk to identify who benefits most from lung cancer screening (40).
Although these data suggest that most smokers view precision smoking treatment favorably, additional support may be necessary to engage smokers who are older, African-American, and do not have a high school degree. Sources of resistance to precision treatment are likely to vary across these different aspects of identity, perhaps including perceived social norms, access, or privacy concerns. If precision approaches are to narrow health disparities, future work should examine means of further increasing their appeal to these groups of smokers. For example, to influence perceived social norms, these results may be disseminated to current smokers to demonstrate the social acceptability of precision smoking treatment among their peers. To ensure equity in access, future work should examine the acceptability and feasibility of implementing these approaches at the provider and system levels. Healthcare systems, particularly in community settings most likely to serve smokers from disproportionately burdened groups, may not have the infrastructure or resources in place to implement precision approaches. Providers may not be well informed about the efficacy of precision approaches or may believe some groups of patients will reject precision smoking treatment. Providers may also require additional education or training regarding culturally competent communication, which can address patients' concerns about privacy or the potential for harm.
Our study has several limitations. First, we did not assess actual behavior; thus, we cannot maintain that respondents will take the tests for nicotine metabolism or lung cancer risk, or that doing so will lead to improvements in lung cancer screening, cessation rates, or medication adherence. However, intentions such as those measured here can be powerful predictors of behavior (41). Next, items related to Respiragene specified a buccal smear (“saliva test”) and items related to NMR testing specified a blood test, confounding the type of test with the mode of testing. Higher observed favorability ratings for risk assessment versus pharmacogenetics are likely due to preferences for less invasive buccal smear over blood tests. As the field moves forward, these tests will likely be widely available using blood or buccal swab samples, suggesting pharmacogenetics will be viewed even more favorably than reported here. Next, while the sample of disproportionately burdened smokers is a strength, these results may not generalize to other high-risk groups, such as low-income African-Americans in large urban centers or immigrant groups lacking English proficiency, and future work should establish the likely acceptability of precision approaches among these groups.
Despite these limitations, results have broad implications for research and clinical settings. The study population is a significant strength. Participants were community smokers and members of social groups traditionally underrepresented in healthcare research and at high risk of suffering tobacco-related disparities. Understanding this group of smokers, their attitudes toward precision smoking treatment, and variation in attitudes associated with known barriers to cessation (e.g., motivation and confidence) lays the groundwork for intervention research to examine the efficacy of precision approaches for equitable treatment of smoking cessation. Furthermore, data were collected through the SCCS, which has characterized participants over more than 15 years. We leveraged previously collected data to accurately define smoking history and richly describe the sample (e.g., calculate predicted lung cancer risk) with minimal additional respondent burden. Furthermore, the SCCS offers a large biorepository that can be leveraged for future precision treatment approaches with Respiragene and the NMR. This work also has clinical implications in that knowledge of the acceptability of genetic testing to assess lung cancer risk and to support pharmacotherapy choice supports wide implementation of these approaches. Future work would also benefit from the use of hybrid trial designs, which integrate effectiveness and implementation outcomes (42). Implementation theories and frameworks like The Consolidated Framework for Implementation Research offer guidance regarding potential facilitators and barriers to the successful implementation of precision smoking treatment, such as an organization's readiness for change and available resources, patient and provider knowledge and attitudes, and the presence of individual champions or supportive opinion leaders (43). Intervention studies of precision smoking treatment would also be strengthened by the inclusion of implementation outcomes, such as reach among eligible patients, adoption by healthcare systems and individual providers, and the sustainability of precision smoking treatment as a component of standard care (44). As this research continues to clarify patient, provider, and system-level barriers and facilitators to precision smoking treatment, implementation science also offers strategies for addressing these barriers and increasing engagement (45).
Our collective findings suggest that precision smoking treatment is favorably viewed and likely to lead to behavior change among smokers who have historically been less successful at quitting and are at especially high risk of suffering and mortality from smoking-related disease. These data lay groundwork for future intervention research and support clinical implementation of precision approaches by clarifying the promise of these approaches in promoting health equity. Future research should focus on testing the comparative effectiveness, as well as cost effectiveness and cost efficiency, of precision approaches in promoting health behavior change, including lung cancer screening, medication adherence, and smoking cessation. Research should also focus on implementation strategies that support efficacy in community health settings to ensure equitable implementation and dissemination of precision smoking treatments.
Disclosure of Potential Conflicts of Interest
M. Sanderson is a consultant/advisory board member for University of Kentucky. R.F. Tyndale is a consultant/advisory board member for Quinn Emanuel, Apotex, Quitta, and Scientific advisory boards. R.P. Young has ownership interest (including stock, patents, etc.) in Synergenz BioScience Ltd. and is a consultant/advisory board member for Synergenz BioScience Ltd. H.A Tindle provided input into study design for clinical trial for Achieve Life Sciences and has provided expert testimony as principal investigator of NIH-supported studies that use manufacturer-donated medication for smoking cessation. No potential conflicts of interest were disclosed by the other authors.
Disclaimer
The content is solely the responsibility of the authors and does not necessarily represent the official views of the Agency for Healthcare Research and Quality.
Authors' Contributions
Conception and design: M. Sanderson, K. Gilliam, D.L. Friedman, R.F. Tyndale, R.P. Young, R.J. Hopkins, H.A. Tindle
Development of methodology: S. King, K. Gilliam, S. Warren Andersen, D.L. Friedman, R.P. Young, R.J. Hopkins, H.A. Tindle
Acquisition of data (provided animals, acquired and managed patients, provided facilities, etc.): W.J. Blot, K. Gilliam, E. Connors, M.K. Fadden, H.A. Tindle
Analysis and interpretation of data (e.g., statistical analysis, biostatistics, computational analysis): N. Senft, M. Sanderson, S. Kundu, D.L. Friedman, Q.S. Wells, R.F. Tyndale, H.A. Tindle
Writing, review, and/or revision of the manuscript: N. Senft, M. Sanderson, R. Selove, W.J. Blot, K. Gilliam, S.J. Sternlieb, S. Warren Andersen, D.L. Friedman, E. Connors, M.K. Fadden, M. Freiberg, Q.S. Wells, J. Canedo, R.F. Tyndale, R.P. Young, R.J. Hopkins, H.A. Tindle
Administrative, technical, or material support (i.e., reporting or organizing data, constructing databases): S. King, M. Steinwandel, H.A. Tindle
Study supervision: S. King, K. Gilliam, H.A. Tindle
Other (assisting with development of data collection survey; facilitated community advisory board subcommittee meeting in which survey instrument was discussed): R. Selove
Acknowledgments
This work was supported by the NCI (U54CA163072-09S1, to principal investigator H.L. Moses, sub-project 6540, principal investigator H.A. Tindle; U54CA163069, to principal investigator S.E. Adunyah, sub-project 6962, principal investigator M. Sanderson; and U54CA163066, to principal investigator B.A. Husaini, sub-project 6610, principal investigator R. Selove). This project was further supported by the Vanderbilt Center for Tobacco, Addiction, and Lifestyle (directed by H.A. Tindle). The Southern Community Cohort Study is funded by grant R01CA92447 (to principal investigators: W.J. Blot and W. Zheng) from the NCI at the NIH, including special allocations from the American Recovery and Reinvestment Act (3R01CA09244708S1). N. Senft was supported by the Agency for Healthcare Research and Quality under Award Number T32 HS026122. S. Warren Andersen is supported by R00CA207848, P30CA014520, and the University of Wisconsin-Madison, Office of Vice Chancellor for Research and Graduate Education with funding from the Wisconsin Alumni Research Foundation. The project was supported by CTSA award no. UL1 TR002243 from the National Center for Advancing Translational Sciences. We also acknowledge a Canada Research Chair in Pharmacogenomics (R.F. Tyndale).
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Footnotes
Note: Supplementary data for this article are available at Cancer Epidemiology, Biomarkers & Prevention Online (http://cebp.aacrjournals.org/).
Cancer Epidemiol Biomarkers Prev 2019;28:1345–52
- Received February 15, 2019.
- Revision received April 10, 2019.
- Accepted May 28, 2019.
- Published first June 3, 2019.
- ©2019 American Association for Cancer Research.
References
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