Abstract
Introduction:
Tobacco use is the leading preventable cause of morbidity and mortality worldwide. Since 2010, Thailand has implemented a multidisciplinary smoking cessation clinic, which provides smoking cessation services, but the effectiveness of the clinics was not formally evaluated. This study was conducted to assess the real-world effectiveness of this multidisciplinary smoking cessation program.
Methods:
We conducted a prospective, multicentre, observational study on Thai participants aged 13 years and older in 24 smoking cessation clinics across Thailand's 13 health regions. Each clinic offered smoking cessation interventions according to the well-established 5As model for smoking cessation (Ask, Advise, Assess, Assist, and Arrange). Outcomes of interest were continuous abstinence rates (CAR) at 3 and 6 months. Biochemical confirmation and self-reporting were used to assess the outcomes. Descriptive statistics (mean, SD, median, IQR, and percentage) were used to analyze the smoking cessation outcomes in both intention-to-treat and per-protocol analysis approaches.
Results:
Smokers receiving services from the Thai multidisciplinary smoking cessation clinics had CAR of 17.49 and 8.33% at 3 and 6 months, respectively. For those with cardiovascular disease (CVD) or cerebrovascular disease, CAR was found to be 26.36% at 3 months and 13.81% at 6 months. While participants with chronic obstructive pulmonary disease (COPD) had CAR ranging from 32.69% at 3 months to 17.31% at 6 months.
Conclusion:
The multidisciplinary team smoking cessation clinic was effective in assisting smokers in quitting smoking. The effectiveness of the clinic was more pronounced for smokers with CVD, cerebrovascular disease, or COPD. Findings from this study support a decision to include multidisciplinary smoking cessation clinics in the universal health care benefits package.
Key messages
Smoking cessation is a global priority and previous studies have shown that smoking cessation programs were beneficial in assisting smokers to quit smoking and reducing the number of smokers.
Since 2010, Thailand has implemented multidisciplinary smoking cessation clinics, but the efficacy of the clinics was measured based on retrospective self-reported data without biochemical confirmation. This prospective study measured the effectiveness of the clinics using both self-reported and biochemical outcomes.
Findings from this study demonstrated that the Thai multidisciplinary smoking cessation clinics were effective at assisting individuals to quit smoking and the results could inform the decision to add the multidisciplinary smoking cessation clinics to the universal health care benefits package.
Introduction
Tobacco use is the leading preventable cause of morbidity and mortality worldwide (1). Tobacco-related mortality accounts for 8.2 million deaths per year, with 7 million deaths occurring among tobacco users and 1.2 million deaths occurring as a result of second-hand smoke exposure. The number of smokers continues to grow; of these, approximately 80% live in low- and middle-income countries (LMIC) (1, 2). In Thailand, the prevalence of smoking among Thai adults aged 15 and older was 19.10% in 2017, according to the latest national survey. However, the prevalence of smokeless tobacco use was not provided because Thai law prohibits the importation and manufacture of smokeless tobacco products. Tobacco use has been shown to link to several non-communicable diseases, including cardiovascular disease (CVD), chronic obstructive pulmonary disease (COPD), cerebrovascular disease (e.g., stroke), and cancer, most notably lung cancer (1–6).
Smoking cessation is a global priority to reduce tobacco-related morbidity and mortality, (1, 2, 5). A systematic review and meta-analysis of randomized controlled trials (7) revealed that smoking cessation programs that relied solely on self-help strategies without providing face-to-face counseling were less effective than those that included face-to-face counseling, whereas programs that included brief advice intervention, defined as providing brief individual advice and information on how to quit smoking, were more effective. Additionally, smoking cessation programs that included behavioral change strategies, such as a series of meetings with smokers, were more effective than usual care and brief advice alone, with a success rate of over 3% to 9% and 4% to 5%, respectively.
Currently, only 26 countries, which account for one-third of the world's population, have national comprehensive cessation services with full or partial cost coverage (1). Thailand has established a multidisciplinary smoking cessation clinic, namely the SMART Quit Clinic Program (FAH-SAI Clinic), since 2010, which provides smoking cessation services through a multidisciplinary team, including education counseling, pharmacological treatment, as well as the prevention, monitoring, and empowerment of smokers. Multidisciplinary smoking cessation clinics currently operate in 552 locations throughout Thailand's 77 provinces. According to the published multidisciplinary smoking cessation clinics' annual report (8), the self-reported point prevalence of smoking cessation at 3, and 6 months was 33.9%, and 38.2%, respectively. However, this report was based on self-reported data without biochemical confirmation. Thus, this study sought to determine the real-world effectiveness of Thai multidisciplinary smoking cessation clinics based on continuous abstinence rates (CAR) at 3 and 6 months through a prospective cohort design with a biochemical validation of smoking status.
Methods
Study design
We conducted a multicentre prospective observational study without a control group since multidisciplinary smoking cessation clinics are considered the standard care for smokers in Thailand.
Study setting
This study focused on 24 multidisciplinary smoking cessation clinics across Thailand's 13 health regions. To ensure that the study samples represent geographical regions nationwide, we used a stratified random sampling based on the following criteria 1) the previous year's recruitment rate and the number of visits to each setting; and 2) multidisciplinary smoking cessation clinics were located using Thailand's 13 health regional strata. Our study sample consisted of individuals receiving smoking cessation services from 2 university hospitals, 10 tertiary hospitals, 11 secondary hospitals, and 1 private hospital. We estimated the required sample size based on a previous report by the Thai multidisciplinary smoking cessation clinics (8), which suggested the success rate for smoking cessation at 6 months of 38.2%. The sample size is calculated using the one group proportion formula at a two-tailed alpha level of 0.05 and an 80% power level. An additional 10% of cases were included to account for attrition. As a result, a minimum of 1,540 participants are required to ensure that we have sufficient statistical power to represent the outcomes in the population.
Study population
Inclusion criteria
We recruited individuals aged 13 years or older who are in the contemplation or action stage and first commence to smoking cessation program in the multidisciplinary smoking cessation clinics.
Exclusion criteria
Participants were excluded from the study if they have been diagnosed with any cancers or intellectual disabilities that impair their ability to complete the exhaled carbon monoxide (CO) testing at the time of eligibility screening.
Description of multidisciplinary smoking cessation clinics
Multidisciplinary smoking cessation clinics involve multidisciplinary health care providers, including physicians, nurses, nursing assistants, pharmacists, dentists, public health officers, psychologists, and practitioners of traditional Thai medicine. The clinics provide cessation services according to the well-established 5As model of smoking cessation (Ask, Advise, Assess, Assist, and Arrange). Specific interventions included 1) identifying, diagnosing, and documenting tobacco use status; 2) assessing the severity of a person's nicotine dependence; 3) counseling the patient to abstain from tobacco use; 4) patients who are willing to give up smoking are evaluated; 5) assisting patients in quitting smoking through counseling or pharmacological interventions; 6) establishing a schedule follow-up contacts. However, interventions and activities might vary slightly across settings, depending on the local context and human resource availability; for example, some settings provide home visits while others provide group counseling.
Outcome measures
The primary outcome of interest in this study was a continuous abstinence rate (CAR) at 3 and 6 months. We also reported a 7-day self-reported [prevalence abstinence rate (PAR)], and 7-day exhaled CO-confirmed point prevalence abstinence rate (CO-confirmed PAR), as well as smoking cessation outcomes for patients diagnosed with CVD or cerebrovascular disease, and COPD at 3, and 6 months.
This study used two outcome measurement methods (9, 10), including a self-reported questionnaire and a gold standard biochemical validation method, i.e., exhaled CO test. Each method assesses the prevalence of abstinence for 7-day abstinence (PAR) at 3 and 6 months. In comparison, the exhaled CO-confirmed 7-day point prevalence abstinence (CO-confirmed PAR) for exhaled CO methods was defined as exhaled CO concentrations are < 10 parts per million (ppm). All CO-oximeters used in this study were calibrated and validated prior to being used on subjects.
Participants were asked whether they had ever used any form of smoking in the past at two points in time (3 and 6 months). The 7-day point PAR is determined by the follow-up question “Have you used any smoking products (of any type) in the last 7 days?” Those who respond that they have not used smoking products in the last 7 days and have fixed CO concentrations in exhaled air < 10 ppm are considered to have quit at the follow-up visit. The continuous abstinence rate (CAR) is determined by the follow-up questions “When did you quit smoking?” and “Have you used any smoking products (of any type) since you quit?” The quit date will be noted, and those who respond that they have not used smoking products in any form since the quit date are considered to have quit (depending on the duration).
Statistical analysis
Baseline characteristics of the participants were described using descriptive statistics (mean, SD, median, IQR, and percentage). We analyzed the smoking cessation outcomes using both intention-to-treat and per-protocol analysis approaches. All data were analyzed using STATA version 14.
Ethics and dissemination
Thailand's Ethical Review Committee for Human Subjects Research has approved the protocol for this study, protocol number 24/2562 and document number 51/2019.
Patient and public involvement
Patients or the public were not involved in the design, conduction, reporting, or dissemination plans of our research.
Results
Sociodemographic, clinical characteristics, and smoking patterns of the participants
A total of 2,041 participants were included in this study. Socio-demographic, clinical, and smoking status of study participants are summarized in Table 1. The participants' mean age was 44.56 years (standard deviations; SD = 17.41), and 24.06% of participants were between the ages of 18 and 30 years (24.06%). Most participants were men (90.79%) and married (54.48 %). Most study participants worked in the labor sector, had a high school education, and earned an average monthly personal income of 8,211.36 Thai baht (230.21 US Dollars). Most participants (41.16%) were current-alcohol users, followed by non-users (37.48%). A majority of participants (75.94%) were covered under the universal coverage reimbursement scheme.
Table 1
| Variables | N = 2,041 | (%) |
|---|---|---|
| Age (Mean, SD) | 44.56 | 17.41 |
| Less than 18 | 67 | 3.28 |
| 18–30 | 491 | 24.06 |
| 31–40 | 275 | 13.47 |
| 41–50 | 395 | 19.35 |
| 51–60 | 354 | 17.34 |
| More than 60 | 417 | 20.43 |
| Not known | 42 | 2.06 |
| Sex | ||
| Male | 1,853 | 90.79 |
| Marital status | ||
| Married or living with partner | 1,112 | 54.48 |
| Occupation | ||
| Unemployed | 191 | 9.36 |
| Private employee | 178 | 8.72 |
| Laborer | 1,072 | 52.52 |
| Farmer | 197 | 9.65 |
| Other | 223 | 10.93 |
| Not Known | 180 | 8.82 |
| Education | ||
| ≤ High school | 1,603 | 78.54 |
| Vocational college, bachelor or higher | 268 | 13.13 |
| Not known | 170 | 8.33 |
| Alcohol intake | ||
| Current user | 840 | 41.16 |
| Ex-user | 400 | 19.60 |
| Non-user | 765 | 37.48 |
| Not known | 36 | 1.76 |
| Personal income (Bath/Month) (Mean, SD) | 8,211.36 | 11,239.20 |
| Personal income (US Dollars/Month) (Mean, SD) | 230.21 | 315.10 |
| Personal income (Bath/Month) (Median, p25-p75) | 6,000.00 | 3,000–10,000 |
| Personal income (US Dollars /Month) (Median, p25-p75) | 168.21 | 84.11–280.36 |
| Reimbursement scheme | ||
| National health security office: Universal coverage | 1,550 | 75.94 |
| Government | 113 | 5.54 |
| Social security office | 257 | 12.59 |
| Other | 64 | 3.14 |
| Not known | 57 | 2.79 |
| Comorbidities | ||
| No comorbidities | 1,019 | 49.93 |
| Hypertension | 444 | 21.75 |
| Cardiovascular diseases or cerebrovascular diseases | 243 | 11.90 |
| Diabetes mellitus | 182 | 8.92 |
| Emphysema or chronic obstructive pulmonary disease | 52 | 2.56 |
| Asthma | 48 | 2.35 |
| Other | 385 | 18.86 |
| Not known | 36 | 1.76 |
| Number of comorbidities (N= 2,005) | ||
| No comorbidities | 1,019 | 49.93 |
| 1 | 707 | 34.64 |
| ≥ 2 | 279 | 13.68 |
| Not known | 36 | 1.76 |
| Types of smoking | ||
| Cigarette | 1,311 | 64.23 |
| Hand-rolled, natural, light cigarette | 844 | 41.35 |
| E-cigarette | 15 | 0.73 |
| Not known | 36 | 1.76 |
| Mixed types smoking | 180 | 8.82 |
| Amount of cigarette per day | ||
| Average (Mean, SD) | 11.82 | 7.76 |
| Less than 6 | 544 | 26.65 |
| 6–10 | 709 | 34.74 |
| 11–20 and higher | 752 | 36.84 |
| Not known | 36 | 1.76 |
| Time to smoke after waking up | ||
| Less than 30 min | 1,188 | 58.21 |
| 60 min | 463 | 22.68 |
| 120 min | 329 | 16.12 |
| Not known | 61 | 2.99 |
| Exhaled carbon monoxide (ppm) (Mean, SD) | 7.93 | 5.54 |
| Exhaled carbon monoxide (ppm) (Median, p25-p50) | 7 | 4–11 |
| FTND (Mean, SD) | 4.20 | 2.26 |
| FTND (Median, p25-p50) | 4 | 3–6 |
| The severity of nicotine dependence | ||
| Very low dependence | 419 | 20.53 |
| Low dependence | 647 | 31.70 |
| Medium dependence | 263 | 12.89 |
| High dependence | 319 | 15.63 |
| Very high dependence | 172 | 8.43 |
| Not known | 221 | 10.83 |
Sociodemographic, clinical characteristics, and smoking pattern of the participants.
Half of the study participants had no comorbidity (49.93%). Of those with comorbidities, the most common comorbidity was hypertension (21.75%), followed by cardiovascular and cerebrovascular diseases (11.90%), diabetes mellitus (8.92%), and emphysema or chronic obstructive pulmonary disease (2.56%). The most frequently used smoking product was the cigarette (64.23%), followed by hand-rolled, natural, or light cigarettes, and mixed-type smoking accounted for 41.35 and 8.82%, respectively. The average number of cigarettes smoked per day was 11.82 (SD = 7.76), with the majority smoking between 11 and more than 20 cigarettes per day. Most study participants started smoking within 30 min after awakening. Our participants were classified as having low dependence, according to exhaled-CO, and the Fagerstrom Test for Nicotine Dependence (FTND) (Table 1).
Medication and intervention characteristics of the participants
Approximately two-thirds of the study participants (68.40%) received one form of smoking cessation medication (Table 2). We found that nicotine gum was the most commonly used standard monotherapy (80.81%), while a special mouth wash (11) was the most used non-standard monotherapy option (67.5%). Among study participants who received combination therapies, the primary regimen was nortriptyline-based combination therapies (49.77%), followed by nicotine replacement-based combination therapies (45.25%), and bupropion-based combination therapies (4.98%), whereas a special mouthwash in combination with Vernonia cinerea (L.) Less was used as the primary in the non-standard combination therapy subgroup (80.95%).
Table 2
| Variables | N = 2,041 | (%) |
|---|---|---|
| Receiving any medication | 1,396 | 68.40 |
| Receiving monotherapy (N= 902) | ||
| Receiving standard monotherapy (N= 99) | ||
| Nicotine gum | 80 | 80.81 |
| Nortriptyline | 16 | 16.16 |
| Other | 3 | 3.03 |
| Receiving non-standard monotherapy (N= 803) | ||
| Special mouthwash | 542 | 67.50 |
| Vernonia cinerea (L.) Less (Little ironweed) | 186 | 23.16 |
| Cytisine | 75 | 9.34 |
| Receiving combination therapies (N= 494) | ||
| Receiving one of standard combination therapy (N= 221) | ||
| Nortriptyline-based combination regimen | 110 | 49.77 |
| Nicotine-based combination regimen | 100 | 45.25 |
| Bupropion-based combination regimen | 11 | 4.98 |
| Receiving non-standard combination therapy (N= 273) | ||
| Special mouthwash with Vernonia cinerea (L.) Less | 221 | 80.95 |
| Cytisine-based combination regimen | 52 | 19.05 |
| Service users | ||
| Patients without caregiver | 1,692 | 82.90 |
| Patients with caregiver | 293 | 14.36 |
| Not known | 56 | 2.74 |
| Individual counseling | 1,671 | 81.87 |
| Group counseling | 128 | 6.27 |
| Individual counseling and group counseling | 181 | 8.87 |
| Not known | 61 | 2.99 |
| Types of Intervention | ||
| Brief advice in hospital/clinic | 1,787 | 87.56 |
| Rehabilitation camp | 188 | 9.21 |
| Other | 9 | 0.44 |
| Not known | 57 | 2.79 |
Medication and intervention characteristics of the participants.
Table 2 describes the characteristics of interventions used in this study. The study participants tended to self-refer to multidisciplinary smoking cessation clinics (82.9%) and received individual counseling as a primary intervention. Face-to-face brief advice in a hospital or clinic was the most frequently used method (87.56%), followed by rehabilitation camps (9.21%).
Smoking cessation outcomes
At 3 and 6 months, the intention to treat analysis found a continuous smoking abstinence rate (CAR) of 17.49 and 8.33%, respectively. We also found a decrease in 7-day self-reported PAR from 17.49 to 11.22% at 3 and 6 months, respectively. CO-confirmed PAR results, suggest a decrease in CO-confirmed PAR, accounting for 8.18 and 2.2% at 3 and 6 months, respectively.
Smoking cessation outcomes among patients with CVD or cerebrovascular disease and COPD
Results of smoking cessation rates for patients with CVD or COPD are also summarized in Table 3. At 3 months, intention to treat analysis revealed that 26.36, 26.36, and 5.44% of participants with cardiovascular disease or cerebrovascular disease, respectively, achieved CAR, PAR, and CO-confirmed PAR. By comparison, at 6 months, the smoking cessation outcomes for CAR, PAR, and CO-confirmed PAR were reduced to 13.81, 15.78, and 1.26%, respectively, in the intention to treat analysis.
Table 3
| Outcomes | 3 Months | 6 Months |
|---|---|---|
| N (%) | N (%) | |
| Intention to treat analysis | N= 2,041 | N= 2,041 |
| Per protocol analysis | N= 1,495 | N= 903 |
| Continuous smoking abstinence rate (CAR) | ||
| Intention to treat analysis | 357 (17.49) | 170 (8.33) |
| Per protocol analysis | 357 (23.88) | 170 (18.83) |
| Point prevalence abstinence rate (PAR) | ||
| 7-day self-reported point prevalence | ||
| Intention to treat analysis | 357 (17.49) | 229 (11.22) |
| Per protocol analysis | 357 (23.88) | 229 (25.36) |
| 7-day CO-confirmed point prevalence | ||
| Intention to treat analysis | 167 (8.18) | 45 (2.20) |
| Per protocol analysis | 167 (11.17) | 45 (4.98) |
| Participants who underwent an exhaled CO test (per protocol analysis) | 167/635 (26.30) | 45/165 (27.27) |
| Cardiovascular disease or cerebrovascular diseases: | ||
| Intention to treat analysis | N= 239 | N= 239 |
| Per protocol analysis | N= 133 | N= 79 |
| Continuous smoking abstinence rate (CAR) | ||
| CAR (Intention to treat) | 63 (26.36) | 33 (13.81) |
| CAR (per protocol) | 63 (47.37) | 33 (41.77) |
| Point prevalence abstinence rate (PAR) | ||
| 7-day self-reported PAR (Intention to treat) | 63 (26.36) | 37 (15.48) |
| 7-day self-reported PAR (per protocol) | 63 (47.37) | 37 (46.83) |
| 7-day CO-confirmed PAR (Intention to treat) | 13 (5.44) | 3 (1.26) |
| 7-day CO-confirmed PAR (per protocol) | 13 (9.77) | 3 (3.80) |
| Chronic obstructive pulmonary disease: | ||
| Intention to treat analysis | N= 52 | N= 52 |
| Per protocol analysis | N= 36 | N= 22 |
| Continuous smoking abstinence rate (CAR) | ||
| CAR (Intention to treat) | 17 (32.69) | 9 (17.31) |
| CAR (per protocol) | 17 (47.22) | 9 (40.91) |
| Point prevalence abstinence rate (PAR) | ||
| 7-day self-reported PAR (Intention to treat) | 17 (32.69) | 12 (23.08) |
| 7-day self-reported PAR (per protocol) | 17 (47.22) | 12 (54.54) |
| 7-day CO-confirmed PAR (Intention to treat) | 12 (23.08) | 4 (7.69) |
| 7-day CO-confirmed PAR (per protocol) | 12 (33.33) | 4 (18.18) |
Smoking cessation outcomes in overall participants, and smoking cessation outcomes among patients with CVD or cerebrovascular disease, and COPD.
The effectiveness of the clinics had a downward trend among participants with the chronic obstructive pulmonary disease when compared between 3 and 6 months. At 3 months, intention to treat analysis revealed that CAR, PAR, and CO-confirmed PAR were 32.69, 32.69, and 23.08, respectively. Additionally, at 6 months, the results were 17.31, 23.08, and 7.69, respectively.
Discussion
Findings from our study demonstrated that the Thai multidisciplinary smoking cessation clinics were effective at assisting individuals in quitting smoking. The 3-month smoking cessation outcomes observed in our study were consistent with earlier research (12). At 3 months, both CAR and PAR were approximately 17.5%. The CAR and PAR dropped at 6 months, at 8.3 and 11.2%, respectively, which was slightly lower than those in prior research (13–20). This present study showed that the CAR and CO-confirmed PAR at 6 months was lower than in other studies (12–16, 20). Previous studies (12, 15, 20) have reported that the CAR and PAR at 3 months ranged between 12 and 66.1%. Additionally, earlier research found that the CAR (17, 19) at 6 months ranged from 10.7 to 28%, and PAR (13, 14, 16, 20) at 6 months ranged between 17 and 66.7%. The same trend was observed when we compared our results with a previous Thai study (9), which found that smoking cessation at 6 months was 31.3% in the intervention group and 13.8% in the control group, and smoking cessation at 6 months with CO-confirmed was 26.6% in the intervention group and 11.3% in the control group.
The COVID-19 pandemic may account for the difference in the CAR and CO-confirmed PAR observed in this study and other studies. The exhaled-CO test was prohibited to prevent viral transmission. Additionally, the pandemic affected clinic follow-up, resulting in an increase in study dropouts (21, 22). Nevertheless, when we estimated CO-confirmed PAR based on a number of participants who underwent an exhaled-CO test, we discovered that the result was comparable to previous research (13, 14, 16, 20) which were 26.3 and 27.3% at 3 and 6 months, respectively. Another possible reason was a difference in study design. Previous studies used randomized controlled trials (RCTs), recruited only participants with specific diseases, and included continuous assistance from a trained family member, whereas this study used a prospective observational design to reflect the real-world implementation and effectiveness of the multidisciplinary team smoking cessation program. Additionally, this current study demonstrated that half of the participants receiving medication received non-standard pharmacological regimens such as special mouthwash or Vernonia cinerea (L.) Less (Little ironweed), while other RCTs used nicotine replacement therapy (NRT), bupropion, or varenicline as a standard pharmacological regimen. Thus, the difference between smoking cessation medical regimens may affect the smoking cessation outcomes.
When compared to continued smoking, smoking cessation has been shown to be effective at reducing CVD-related morbidity and mortality (23–27), as well as slowing the accelerated rate of lung function decline and improving survival in patients with COPD (28, 29). The majority of studies in patients with CVD and COPD reported a 6-month or longer continuous abstinence rate. There was considerable variation in the continuous abstinence rate, and we discovered that the results of the present study were comparable to those of previous research (18, 26, 29). However, it should be noted that only 11.9 and 2.56% of participants with cardiovascular or cerebrovascular disease or COPD, respectively, were included in this study.
The effect of a multidisciplinary smoking cessation clinic was evaluated in this study using a prospective observational design that reflects the real-world outcomes of smoking cessation programs, particularly their effectiveness in low- and middle-income countries with limited human resources and budgets. Additionally, this study divided outcomes into self-reported, and biochemical confirmation. Moreover, one of the strengths of the Thai multidisciplinary smoking cessation clinic is the number of clinics that cover all provinces of Thailand. Given Thailand's five-year national NCDs prevention and control plan (2017–2021) to decrease the prevalence of tobacco use in the population, the result of this study could support a decision to add multidisciplinary smoking cessation clinics to part of the official national health program.
Several limitations of the current study should be noted. First, CAR at 1 year is regarded as the gold standard, but we were unable to utilize this result due to the COVID-19 pandemic. In this study, only CAR at 3 and 6 months was reported. The pandemic also affected clinic follow-up; at 6 months, more than half of the participants had not been followed. This important limitation must be considered when interpreting the results of this study. Second, our study was subject to temporal ambiguity and confounding bias due to the observational nature of this study. Nonetheless, we attempted to reduce this type of bias by employing a prospective data collection method. Third, because multidisciplinary smoking cessation clinics are considered standard care for smokers, it was infeasible to include a comparison group of smokers who did not receive smoking cessation services. In addition, each multidisciplinary smoking cessation clinic may offer unique services or activities, depending on their contexts and available resources. This variation could influence the effectiveness of the program. Our study attempted to address this variation by stratified random sampling criteria that took previous setting performance and health regional strata in the sampling method.
Conclusion
In conclusion, the multidisciplinary team smoking cessation clinics were effective at assisting Thai smokers with or without comorbidities (CVD, cerebrovascular disease, or COPD) in quitting smoking. Our study results support the inclusion of multidisciplinary smoking cessation clinics in the universal health care benefits package. In addition, future research should examine the long-term effects of smoking cessation programs, such as CAR at 1 year, to corroborate the long-term efficacy of smoking cessation programs.
Funding
This work was supported by National Alliance for Tobacco Free Thailand, grant number 61-00-1344-01/2561.
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Statements
Data availability statement
The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.
Ethics statement
The studies involving human participants were reviewed and approved by Thailand's Ethical Review Committee for Human Subjects Research has approved the protocol for this study, protocol number 24/2562 and document number 51/2019. Written informed consent to participate in this study was provided by the participants' legal guardian/next of kin.
Author contributions
CC, NC, KT, and SL conceived this paper. CC, NC, and KT developed protocols. CC developed a clinical recruitment strategy. CC developed a data management tool and analysis plan. All authors contributed to the article and approved the submitted version.
Acknowledgments
We acknowledge the support provided by the Investigators of all participating institutions. We thank all the participants in this study and the project staff.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
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Summary
Keywords
smoking, smoking cessation, tobacco, program evaluation, health policy
Citation
Chaisai C, Thavorn K, Wattanasirichaigoon S, Rungruanghiranya S, Thongphiew A, Dilokthornsakul P, Lee SWH and Chaiyakunapruk N (2022) The impact of Thai multidisciplinary smoking cessation program on clinical outcomes: A multicentre prospective observational study. Front. Public Health 10:965020. doi: 10.3389/fpubh.2022.965020
Received
09 June 2022
Accepted
25 July 2022
Published
24 August 2022
Volume
10 - 2022
Edited by
Sathish Thirunavukkarasu, Emory University, United States
Reviewed by
Kavumpurathu Raman Thankappan, Central University of Kerala, India; Mary Chandrika Anton, Sree Balaji Medical College and Hospital, India
Updates
Copyright
© 2022 Chaisai, Thavorn, Wattanasirichaigoon, Rungruanghiranya, Thongphiew, Dilokthornsakul, Lee and Chaiyakunapruk.
This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Nathorn Chaiyakunapruk nathorn.chaiyakunapruk@utah.eduKednapa Thavorn kthavorn@ohri.ca
This article was submitted to Public Health Policy, a section of the journal Frontiers in Public Health
Disclaimer
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