The association between cigarette smoking and serum thyroid stimulating hormone, thyroid peroxidase antibodies and thyroglobulin antibodies levels in Chinese residents: A cross-sectional study in 10 cities
Authors:
Yan Zhang aff001; Lixin Shi aff001; Qiao Zhang aff001; Nianchun Peng aff001; Lulu Chen aff002; Xiaolan Lian aff003; Chao Liu aff004; Zhongyan Shan aff005; Bingyin Shi aff006; Nanwei Tong aff007; Shu Wang aff008; Jianping Weng aff009; Jiajun Zhao aff010; Weiping Teng aff005
Authors place of work:
Department of Endocrinology, Affiliated Hospital of Guizhou Medical University, Guiyang, China
aff001; Department of Endocrinology, Union Hospital, Tongji Medical College, Huazhong University of Science and Technology, Wuhan, China
aff002; Department of Endocrinology, Peking Union Medical College Hospital, Beijing, China
aff003; Department of Endocrinology, Jiangsu Province Hospital on Integration of Chinese and Western Medicine, Nanjing, China
aff004; Department of Endocrinology and Metabolism, Key Laboratory of Thyroid Diseases in Liaoning Province, The First Hospital of China Medical University, Shenyang, China
aff005; Department of Endocrinology, First Affiliated Hospital of Medical College of Xi’an Jiaotong University, Xi’an, China
aff006; Department of Endocrinology, West China Hospital, Sichuan University, Chengdu, China
aff007; Department of Endocrinology, The Ruijin Hospital of Shanghai Jiaotong University, Shanghai, China
aff008; Department of Endocrinology, The Third Affiliated Hospital of Sun Yat-sen University, Guangzhou, China
aff009; Department of Endocrinology, The Provincial Hospital Affiliated to Shandong First Medical University, Jinan, China
aff010
Published in the journal:
PLoS ONE 14(11)
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pone.0225435
Summary
Objectives
Although several studies have shown that cigarette smoking is associated with thyroid stimulating hormone (TSH), thyroid peroxidase antibody (TPOAb) and thyroglobulin antibody (TgAb), the exact relationship between smoking and thyroid function is controversial. As little is known about the effects of smoking on TSH, TPOAb and TgAb in Chinese residents. This study aimed to evaluate the association between cigarette smoking and TSH, TPOAb and TgAb in ten-city residents of China.
Study design
This was a population-based cross-sectional study.
Methods
In this cross-sectional study, 15,181 subjects from ten major cities of China were investigated. Data regarding demographic characteristics, smoking status and consumption of iodine status were collected using in-person interviews based on a self-designed structured questionnaire. Serum concentrations of TSH, TPOAb and TgAb were measured using electrochemiluminescence immunoassays. Univariate analysis and multivariate linear stepwise regression analyses were used to analyze the data.
Results
The regular smokers had lower concentrations of TSH, TPOAb and TgAb than occasional smokers, former smokers and never smokers. Multivariate analysis demonstrated that regular smoking was associated with the decreased concentrations of TSH (β = -0.178), TPOAb (β = -0.287) and TGAb (β = -0.453) after adjusting other factors. Furthermore, daily smoking number was significantly associated with the decreased level of TSH (β = -0.045) and TPOAb(β = -0.080), and smoking duration was associated with the decreased TSH level (β = -0.030).
Conclusions
Our findings suggest that cigarette smoking is related to a significant decline in the concentrations of TSH, TPOAb and TgAb. In addition, daily smoking number and long-term smoking decrease serum TSH and TPOAb levels. Cigarette smoking plays a significant role in the development of thyroid dysfunction.
Keywords:
Thyroid-stimulating hormone – Smoking habits – Cross-sectional studies – Smoking related disorders – Seaweed – Thyroid – Iodine
Introduction
Thyroid dysfunction has a significant impact upon the general population[1, 2]. In China, although the prevalence of goiter, Graves’ disease, clinical and subclinical hyperthyroidism have decreased in recent years, the prevalence of subclinical hypothyroidism and thyroid nodules have strikingly increased[3]. It is thought that advanced pharmaceutical engineering and food processing may interfere with medicine and iodine intake, and such interventions may affect or improve euthyroidism. Thyroid dysfunction has been recognized as a global public health problem, which affects 10% of the general population and increases the risk of cardiovascular morbidity and mortality[4]. Given the current trajectory, thyroid disease will become a concerned public health issue and require practical interventions.
Cigarette smoking is the leading cause of avoidable premature mortality, and the number of cigarette smokers exceeds 300 million in China[5, 6]. The prevalence of cigarette smoking in population with the age of ≥ 18 years old has been reported as 62.4% in men and 3.4% in women[7]. Smoking is a risk factor for several diseases, such as cancer, chronic obstructive pulmonary disease, stroke, aneurysm and aortic aneurysms and peripheral vascular disease[8]. Additionally, smoking is regard as an independent risk factor for cardiovascular disease[9]. Studies have reported that smoking is a risk factor for the development of thyroid diseases. For example, several studies have confirmed that in developed countries, smoking can increase thyroid size and nontoxic goiter[10–12]. Cigarette smoking increases the risk and severity of Graves’ disease, Graves’ ophtalmopathy and thyroid multinodularity[12–14].
Thyroid stimulating hormone (TSH), thyroid peroxidase antibody (TPOAb) and thyroglobulin antibody (TgAb) are the most conventional indicators of thyroid dysfunction, including hypothyroidism, hyperthyroidism and autoimmune thyroid diseases. Early diagnosis of thyroid diseases has been clearly shown to improve the prognosis of these diseases, according to the third round of the National Health and Nutrition Examination Survey (NHANES III) in United States, which advise to use the three indexes of TSH, TPOAb and TgAb for consideration of thyroid health[15]. Chemical components of tobacco including nicotine, thiocyanate and benzpyrene have been associated with the inhibition of thyroid hormone synthesis and the promotion of goiter, which can directly or indirectly lead to abnormal thyroid hormone production[16, 17].
Cigarette smoking has multiple, minor effects on thyroid function[18]. The effect of cigarette smoking on thyroid function is associated with age, smoking history, number of cigarettes per day, physical health, environment and iodine status (iodine deficiency or residing in an iodine more than adequate region), and other factors[17, 19, 20]. However, the effect of cigarette on thyroid function is controversial. Some studies have shown that smokers had a marked reduction in thyroid hormone levels compared with non-smokers, while other reports provide inconsistent results[16, 21]. Several population-based studies have reported lower levels of serum TSH in smokers than in non-smokers[22–26], while TSH levels were found to be unaltered in other studies[27–29]. The significance to elucidate the effect of smoking on thyroid function is far-reaching, however, up to date the association between smoking and levels of TSH, TPOAb, and TgAb is far from being clear. Therefore, we conducted this cross-sectional survey across ten cities in China to explore the relationship between cigarette smoking and the concentrations of TSH, TPOAb and TgAb, which may be helpful to further investigation of the impact of smoking on thyroid function.
Materials and methods
Ethical statement
This study was approved by the ethics committee of the First Affiliated Hospital of China Medical University (No. 34–2008). Written informed consent was obtained from each participant in accordance with the ethical standards of the responsible committee on human research.
Study population
The survey was conducted in China and ten cities were chosen according to their historical median urine iodine concentration in school-age children that was representative of iodine-adequate and iodine more than adequate status. They are located in densely populated areas of China, which include Shenyang, Beijing, Jinan, Xi’an, Chengdu, Nanjing, Shanghai, Wuhan, Guiyang and Guangzhou. According to environmental information, six cities (Shenyang, Beijing, Jinan, Shanghai, Chengdu and Guangzhou) were classified as iodine-adequate areas and four cities (Xi’an, Nanjing, Wuhan and Guiyang) were classified as iodine more than adequate areas[3]. The cross-sectional study used multi-stage stratified and cluster sampling methods. The random selection procedure has previously been described[3]. We randomly selected regions from each city, and randomly selected communities from the selected regions. People who met the study requirements were then selected for the survey. Finally, one or two communities include 1500 individuals that were randomly selected in each city, and 15,008 participants agreed and completed the study (S1 Fig). The target population covered participants aged ≥20 of the Han ethnic group and other ethnic minorities, including Hui, Manchu, Korean, Mongol, Miao and Zhuang ethnic groups.
Study design
This study was a cross-sectional epidemiological survey that included face-to-face interviews and thyroid examinations. Data were collected based on a self-designed structured questionnaire. The questionnaire covered five areas gathered from participant interviews: (1) demographic characteristics such as gender, age, ethnic group, education, occupation, etc.; (2) consumption of iodine status: type of salt used, consumption of kelp and porphyra, and the personal or family history of thyroid diseases (including time of diagnosis and therapy undertaken); (3) smoking status including smoking status, smoking cessation status, tobacco type, years of smoking, age when they began smoking, number of cigarettes per day and passive smoking; (4) physical examination, which considered blood pressure levels, body mass index (BMI) and waistline; and (5) laboratory measurements.
In this study we measured serum TSH, TPOAb and TgAb. Samples of blood were obtained from each subject after an overnight fast. All samples were stored at -20°C and transferred within 1 month of collection to the laboratory in the project center for centralized measurements. TSH, TPOAb and TgAb levels were tested using electrochemiluminescence immunoassays on a Cobas 601 analyzer (Roche Diagnostic, Switzerland). Normal reference ranges were 0.27–4.2 mIU/L for TSH, 0–34 IU/ml for TPOAb and 0–115 IU/ml for TgAb[3]. In those with abnormal serum TSH, free thyroxin (FT4) and free triiodothyronine (FT3) levels was measured. However, the latter was excluded in this study, because FT4 and FT3 had too many missing values and beyond the aim of the study. The functional sensitivity of serum TSH was 0.002 mIU/L. The intra-assay coefficients of variation (CV) of serum TSH, TPOAb and TgAb were 1.1–6.3% and the inter-assay CV values were 1.9–9.5%[3]. And we defined positive antithyroid antibodies as TPOAb >34 IU/ml or TgAb >115 IU/ml[30].
Implementation
This cross-sectional study lasted over 17 months, from March 2009 to August 2010 across ten cities of China. Investigators and physicians were recruited in each survey region before the implementation of this study. To ensure objectivity and authenticity, all participating investigators and physicians performing physical examinations received strict and standardized professional training before the implementation of the project. A total of 71 physicians and surveyors participated in the on-site survey. All survey subjects were selected strictly according to the random sampling method. During the survey, a supervisor in each region oversaw the surveyors and verified their work; and 10% of the questionnaires completed each day were randomly inspected for completeness, accuracy and standardization. After the whole investigation was completed, the questionnaires were entered twice into computers by two different inputters blinded to the study goals. Based on the questionnaire, the participants in this study were divided into never smoker, former smoker, occasional smoker, and regular smoker groups. People who had never smoked were defined as never smokers. People who smoked previously but had quit currently were defined as former smokers. Current smokers who smoked less than 1 cigarette per day were occasional smokers, and those who smoked more than 1 cigarette per day were regular smokers.
Statistical analysis
A descriptive analysis was performed to describe demographic characteristics of study participants. Categorical variables were reported as numbers and percentages. Quantitative data that were normally distributed were expressed as means and standard deviations while non-normally distributed data were expressed as medians and quartiles (P25~P75). Cigarette smoking status was described as ratio, and the concentrations of TSH, TPOAb and TgAb were presented as medians and quartiles (P25~P75). Differences of demographic characteristics among smoke status groups were evaluated using ANOVA and chi-squared (χ2) test. A Mann-Whitney test or a Kruskal-Wallis test was used to compare the differences of TSH, TPOAb and TgAb between groups. Since TSH, TPOAb and TgAb as dependent variables had no normal distribution, we applied Ln TSH, Ln TPOAb and Ln TgAb for multivariable analysis. Multivariable linear regression analyses were used to evaluate the associations of cigarette smoking with Ln TSH, Ln TPOAb and Ln TgAb. For all outcomes, significant variables (p<0.05) in univariate analyses were entered into the multivariate models and retained in the final models if p< 0.05. All statistical analyses were performed using SPSS 17.0 (SPSS Inc., Chicago, IL, USA).
Results
The demographic characteristics of participants
The study included 13,512 subjects with complete data enrolled at this epidemiological survey (i.e. effective response rate of 90.0%). Of the 13,512 subjects surveyed, 7,761 (57.4%) participants were from iodine-adequate areas and 5,751 (42.6%) lived in iodine more than adequate areas. Among them, 115 were defined as former smokers (61 males, 54 females), 396 were occasional smokers (276 males, 120 females), 3,127 were regular smokers (2,938 males, 189 females), and 9,874 were never smokers (2,454 males, 7,420 females).
The characteristics of the entire sample among smokers and non-smokers are described and compared in Table 1. The mean age (± standard deviation; SD) was 45.61 (±14.92) for the entire population. There were significant differences between these four groups for age (p<0.001), gender (p<0.001), frequency of postmenopausal women (p = 0.005), frequency of abnormal childbearing (p<0.001), BMI (p<0.001), waistline (p<0.001), hypertension (p<0.001) and family history of thyroid diseases (p<0.001). However, no significant difference was found among different smoking status groups for Han ethnicity (p = 0.618). Other demographic characteristics of study participants are displayed in S1 Table.
Smoking and iodine uptake situation
The percentage of people with current smoking was 26.1%, the percentage of people who occasionally smoked was 2.9%, and the percentage of people who regularly smoked was 23.1%. Among male participants, the percentage of regular smoking was as high as 51.3% (S2 Fig). The percentage of subjects who were exposed to second-hand smoke was 30.7%. Among those who smoked, their mean age of onset smoking was 22.6±7.0 years, the smoke duration was 20.5±12.5 years (S3 Fig).
As shown in S2 Table, 98.4% of participants had iodized salt intake, there were 1779 (13.2%) subjects without kelp and porphyra consumption at ordinary times, and only 3.1% had iodine drugs use. Of the three common indexes of iodine uptake, significant differences were found between smoking status groups for iodized salt (p = 0.019), kelp and porphyra consumption (p = 0.001) and iodine drugs use (p = 0.003). The results suggested that smokers had more iodine uptake than non-smokers.
The association between cigarette smoking and TSH, TPOAb, TgAb
Table 2 displays a summary of the concentrations of TSH, TPOAb and TgAb among those with different smoking behaviors. Kruskal-Wallis tests were used to compare the difference, and significant differences were found among different smoking status groups for TSH (p<0.001), TPOAb (p = 0.017) and TgAb (p<0.001). However, no significant differences were found between dry tobacco and cigarette groups for TSH (p = 0.679), TPOAb (p = 0.220) and TgAb (p<0.728).
Among smokers, TSH and TPOAb were significantly affected by smoking duration and daily smoking amount. The levels of TSH and TPOAb showed declining trend with the increase of smoking years and the daily smoking amount, while no effect of smoking duration and daily smoking amount on TgAb was found. The levels of TSH and TgAb in passive smokers were significantly higher than that in non-passive smokers. However, no significant differences were found between passive smokers and non-passive smokers for TPOAb. TSH, TPOAb and TgAb levels among different smoking status groups between iodine-adequate area and iodine more than adequate area are presented in Fig 1. Kruskal-Wallis tests showed that the levels of TSH, TPOAb and TgAb were significantly different among different smoking status groups (p<0.05). In addition, the proportion of TPOAb positivity and TgAb positivity among different smoking status groups is shown in Table 3. The proportion of TPOAb and TgAb was decreased for smokers than never smokers.
Box plot of TSH (A), TPOAb (B) and TgAb (C) levels among different smoking status groups between iodine-adequate area and iodine more than adequate area. The data were expressed as minimum, P25, median, P75, maximum.
Multivariate analysis
Since TSH, TPOAb and TgAb as dependent variables had not normal distribution by normality tests, we applied Ln TSH, Ln TPOAb and Ln TgAb for multiple linear regression. Multivariate analysis of demographic characteristics, iodine uptake situation, cigarette smoking, family history of thyroid diseases and physical examination as independent factors associated with Ln TSH (Table 4). Regression analysis suggested that regular smoking, smoking duration and daily smoking amount were related to a decline in the concentration of Ln TSH after adjusting for other variables (β = -0.178, -0.030 and -0.048, respectively). Of these factors, regular smoking was strongly associated with Ln TSH (standardized β = -0.086) and monthly income was the least influential factor on Ln TSH (standardized β = -0.032).
Parameter estimates and test results of the multifactorial linear regression model for TPOAb are presented in Table 5. Multivariable analysis showed that former smoking (β = -0.370), occasional smoking(β = -0.263), regular smoking (β = -0.287) and daily smoking amount (β = -0.080) were significantly associated with a decline Ln TPOAb after adjusting for other factors. According to the standardized regression coefficients of each variable, regular smoking and gender exhibited the higher values (Standardized β = -0.108 and 0.105), which indicated that regular smoking and gender were the important factors that affected the concentration of TPOAb.
Table 6 shows the result of multivariate analysis of factors related to Ln TgAb. Former smoking (β = -0.268), occasional smoking(β = -0.316), regular smoking (β = -0.453) and passive smoking (β = 0.063) were significantly associated with a decline in Ln TgAb even after adjustment with other factors, and regular smoking was the strongest influence factor to affect the concentration of TgAb (Standardized β = -0.149).
Discussion
This cross-sectional study is the largest scale survey to date on the correlation of cigarette smoking with thyroid function in China. In this study we have found that cigarette smoking is associated with lower serum TSH, TPOAb and TgAb values, which may lead to lower risk of hypothyroidism and possibly lower frequency of thyroid autoimmune diseases such as Hashimoto's thyroiditis. This finding has important significance since early detection and intervention is necessary in high-risk populations that are known to smoke.
This study has identified that smoking is associated with a decreased serum concentration of TSH after adjusting for gender, age, iodine-intake status, family history of thyroid diseases and other variables. Slightly reduced serum TSH concentrations in smokers have been found in many previous and a few recent studies[14, 17, 20, 22–26, 31–34]. However, the influence of smoking on TSH is controversial. Some studies have reported no association between serum TSH levels and smoking[16, 27–29]. The study also shows that the TSH level decreases with the increase of the number of smokers per day and the years of smoking. In addition, although passive smoking was not included in the multivariate model, univariate analysis revealed that TSH levels in passive smokers were significantly higher than those in non-passive smokers. Some epidemiological studies have reported lesser TSH levels not in all passive smokers compared with non-smokers[35–37]. The mechanism of passive smoking on TSH remains unclear. The reason for a lower serum TSH level among smokers cannot be identified from our study. One possible mechanism is that cyanide is transformed into thiocyanate in the body during cigarette smoking, and thiocyanate can concomitantly lead to reduced iodine adsorption and increased iodide efflux, which further enhances the promoting effect of sympathetic stimulation or increases autoimmune thyroid function, which consequently regulates and increases the synthesis of thyroid hormones[33, 38]. Thyroid hormones reduce the level of TSH through thyroxin feedback inhibition, thus maintaining normal metabolic and organ functions in the smoking population.
TPOAb and TgAb are indicators of autoimmune thyroid disease. However, the association between TPOAb/TgAb and cigarette smoking is controversial. One study from Korea found that smoking status is not associated with the presence of TPOAb, and smoking has a direct effect on thyroid function which is not mediated by autoimmune processes[39]. As reported in the third NHANES, the impact of smoking on TPOAb is related to urinary iodine and racial-ethnic differences. The protective effect of smoking on TPOAb prevalence is only observed in subjects with normal urinary iodine but not in subjects with less or great levels, and the protective effect was only significant in the non-Hispanic white cohort but not in non-Hispanic black, Mexican-American, or other cohorts[34]. One study from China revealed that long-term smoking could increase the prevalence of thyroid autoantibodies in a population with mildly deficient iodine intake[40]. But there are extensive studies showing decreases in risk of positive TPOAb and TgAb associated with smoking[20, 41–44]. In NHANES, fewer smokers had TPOAb and/ or TgAb compared with non-smokers[34]. The percentage of nonsmokers with positive TPOAb and TgAb was significantly higher than that of smokers, i.e. smoking was negatively associated with the presence of thyroid antibodies (TPOAb/TgAb)[45]. Another study reported that TPOAb were significantly lower among smokers but no association between smoking and the other antibodies was observed[46]. Our study has identified that smoking appears to influence not only the lower serum concentration of TSH level but also the concentration of TPOA and TgAb, which suggests that smokers may be less likely to have positive TPOAb/ TgAb than never smokers. In addition, the dose of smoking was associated with a decreased level of TPOAb, but not with TgAb in our multivariate models. This study also revealed that TgAb levels in passive smokers were significantly higher than those in non-passive smokers. The lower level of autoantibody in smokers may be restricted to Hashimoto's thyroiditis[47]. While smoking is a risk factor for Graves' disease[48]. Reduced risk of TPOAb/ TgAb positivity in smokers may be due to smoke effects on cell mediated immunity[49, 50]. Smoking can inhibit natural killer cell activity, increase CD3+ and CD4+ T cell numbers, and reduce CD8+ T cell numbers[50]. CD8+ T-cells participate in autoimmune processes and recognize TPO- and TG-antigens, while natural killer cell and CD4+ T-cells are also involved in the development of thyroid dysfunction[51, 52]. Other studies have noted that the reason for reducing risk of TPOAb/ TgAb positivity in smokers is the interference of smoke in iodide transport and organification, decreased TSH secretion or smoke effects on decreased hormonal and inhibition of prostaglandin synthesis[53, 54]. The protective effect of smoking on TPOAb and TgAb is observed in our study. However, since this study is a cross-sectional study, the causality between smoking and TPOAb/ TgAb cannot be confirmed. Prospective studies are needed in the further.
The limitations of our study are as follows: FT3 and FT4 are two important direct indicators of thyroid function. However, FT3 and FT3 levels were only measured if TSH was outside the reference range. Therefore, we did not evaluate the relationship between smoking and both FT3 and FT4 in our study. The accuracy of using a questionnaire to define smoking status groups was less than NHANESIII[34], which examined serum cotinine levels. Lastly, this cross-sectional study does not permit to assess changes of serum TSH, TPOAb and TgAb over time in the study participants.
In summary, cigarette smoking is related to a significant decline in the concentrations of TSH, TPOAb and TgAb after adjusting for other variable, especially in regular smokers. In addition, the number of cigarettes smoked per day and long-term smoking could decrease serum TSH and TPOAb levels. This finding suggests that smoking has a crucial environmental effect and may play a significant role in the development of thyroid dysfunction.
Supporting information
S1 Table [docx]
Other demographic characteristics of study participants.
S2 Table [docx]
Iodine uptake situation of study participants in each group.
S1 Fig [tif]
Selection procedures of this cross-sectional epidemiological survey data.
S2 Fig [tif]
The percentage of different smoking status in ten-city residents in China.
S3 Fig [tif]
The age of onset smoking and smoke duration of the smokers.
Zdroje
1. Nie X, Chen Y, Chen Y, Chen C, Han B, Li Q, et al. Lead and cadmium exposure, higher thyroid antibodies and thyroid dysfunction in Chinese women. Environmental pollution (Barking, Essex: 1987). 2017;230:320–8. Epub 2017/07/02. doi: 10.1016/j.envpol.2017.06.052 28667913.
2. Gopinath B, Liew G, Kifley A, Mitchell P. Thyroid Dysfunction and Ten-Year Incidence of Age-Related Macular Degeneration. Investigative ophthalmology & visual science. 2016;57(13):5273–7. Epub 2016/10/08. doi: 10.1167/iovs.16-19735 27716857.
3. Shan Z, Chen L, Lian X, Liu C, Shi B, Shi L, et al. Iodine Status and Prevalence of Thyroid Disorders After Introduction of Mandatory Universal Salt Iodization for 16 Years in China: A Cross-Sectional Study in 10 Cities. Thyroid: official journal of the American Thyroid Association. 2016;26(8):1125–30. Epub 2016/07/03. doi: 10.1089/thy.2015.0613 27370068.
4. Teumer A, Chaker L, Groeneweg S, Li Y, Di Munno C, Barbieri C, et al. Genome-wide analyses identify a role for SLC17A4 and AADAT in thyroid hormone regulation. Nature communications. 2018;9(1):4455. Epub 2018/10/28. doi: 10.1038/s41467-018-06356-1 30367059; PubMed Central PMCID: PMC6203810.
5. Samet JM. Tobacco smoking: the leading cause of preventable disease worldwide. Thoracic surgery clinics. 2013;23(2):103–12. Epub 2013/04/10. doi: 10.1016/j.thorsurg.2013.01.009 23566962.
6. Li W, Kung K, Li Z, Hui C, Holroyd E, Wong WCW. Quitting Smoking in Mainland China: A New Role for Hospital-Based Nurses. Holistic nursing practice. 2019;33(1):45–51. Epub 2018/11/14. doi: 10.1097/HNP.0000000000000303 30422924.
7. Liu S, Zhang M, Yang L, Li Y, Wang L, Huang Z, et al. Prevalence and patterns of tobacco smoking among Chinese adult men and women: findings of the 2010 national smoking survey. Journal of epidemiology and community health. 2017;71(2):154–61. Epub 2016/09/24. doi: 10.1136/jech-2016-207805 27660401; PubMed Central PMCID: PMC5284482.
8. Luijckx E, Lohse T, Faeh D, Rohrmann S. Joints effects of BMI and smoking on mortality of all-causes, CVD, and cancer. Cancer causes & control: CCC. 2019. doi: 10.1007/s10552-019-01160-8 30911976
9. Min JY, Cho SG, Jeon YS, Kong E, Min KB, Park SG, et al. Cigarette smoking and vascular conditions in elderly males: evidence from a community-based study. International journal of cardiology. 2011;146(2):251–2. Epub 2010/11/26. doi: 10.1016/j.ijcard.2010.10.063 21095022.
10. Ittermann T, Schmidt CO, Kramer A, Below H, John U, Thamm M, et al. Smoking as a risk factor for thyroid volume progression and incident goiter in a region with improved iodine supply. European journal of endocrinology. 2008;159(6):761–6. Epub 2008/09/04. doi: 10.1530/EJE-08-0386 18765562.
11. Kapoor D, Jones TH. Smoking and hormones in health and endocrine disorders. European journal of endocrinology. 2005;152(4):491–9. Epub 2005/04/09. doi: 10.1530/eje.1.01867 15817903.
12. Prummel MF, Wiersinga WM. Smoking and risk of Graves' disease. Jama. 1993;269(4):479–82. Epub 1993/01/27. 8419666.
13. Vestergaard P, Rejnmark L, Weeke J, Hoeck HC, Nielsen HK, Rungby J, et al. Smoking as a risk factor for Graves' disease, toxic nodular goiter, and autoimmune hypothyroidism. Thyroid: official journal of the American Thyroid Association. 2002;12(1):69–75. Epub 2002/02/13. doi: 10.1089/105072502753451995 11838733.
14. Knudsen N, Bulow I, Laurberg P, Perrild H, Ovesen L, Jorgensen T. High occurrence of thyroid multinodularity and low occurrence of subclinical hypothyroidism among tobacco smokers in a large population study. The Journal of endocrinology. 2002;175(3):571–6. Epub 2002/12/12. doi: 10.1677/joe.0.1750571 12475368.
15. Hollowell JG, Staehling NW, Flanders WD, Hannon WH, Gunter EW, Spencer CA, et al. Serum TSH, T(4), and thyroid antibodies in the United States population (1988 to 1994): National Health and Nutrition Examination Survey (NHANES III). The Journal of clinical endocrinology and metabolism. 2002;87(2):489–99. Epub 2002/02/12. doi: 10.1210/jcem.87.2.8182 11836274.
16. Meral I, Arslan A, Him A, Arslan H. Smoking-related Alterations in Serum Levels of Thyroid Hormones and Insulin in Female and Male Students. Alternative therapies in health and medicine. 2015;21(5):24–9. Epub 2015/09/24. 26393988.
17. Brown SJ, Bremner AP, Hadlow NC, Feddema P, Leedman PJ, O'Leary PC, et al. The log TSH-free T4 relationship in a community-based cohort is nonlinear and is influenced by age, smoking and thyroid peroxidase antibody status. Clinical endocrinology. 2016;85(5):789–96. Epub 2016/05/21. doi: 10.1111/cen.13107 27197788.
18. Pontikides N, Krassas GE. Influence of cigarette smoking on thyroid function, goiter formation and autoimmune thyroid disorders. Hormones (Athens, Greece). 2002;1(2):91–8. Epub 2006/11/18. doi: 10.14310/horm.2002.1156 17110360.
19. Sawicka-Gutaj N, Gutaj P, Sowinski J, Wender-Ozegowska E, Czarnywojtek A, Brazert J, et al. Influence of cigarette smoking on thyroid gland—an update. Endokrynologia Polska. 2014;65(1):54–62. Epub 2014/02/20. doi: 10.5603/EP.2014.0008 24549603
20. Mehran L, Amouzgar A, Delshad H, Azizi F. The association of cigarette smoking with serum TSH concentration and thyroperoxidase antibody. Experimental and clinical endocrinology & diabetes: official journal, German Society of Endocrinology [and] German Diabetes Association. 2012;120(2):80–3. Epub 2011/09/15. doi: 10.1055/s-0031-1285910 21915816.
21. Mannisto T, Hartikainen AL, Vaarasmaki M, Bloigu A, Surcel HM, Pouta A, et al. Smoking and early pregnancy thyroid hormone and anti-thyroid antibody levels in euthyroid mothers of the Northern Finland Birth Cohort 1986. Thyroid: official journal of the American Thyroid Association. 2012;22(9):944–50. Epub 2012/08/10. doi: 10.1089/thy.2011.0377 22873201; PubMed Central PMCID: PMC3429279.
22. Hegedus L, Karstrup S, Veiergang D, Jacobsen B, Skovsted L, Feldt-Rasmussen U. High frequency of goitre in cigarette smokers. Clinical endocrinology. 1985;22(3):287–92. Epub 1985/03/01. doi: 10.1111/j.1365-2265.1985.tb03242.x 3978834.
23. Petersen K, Lindstedt G, Lundberg PA, Bengtsson C, Lapidus L, Nystrom E. Thyroid disease in middle-aged and elderly Swedish women: thyroid-related hormones, thyroid dysfunction and goitre in relation to age and smoking. Journal of internal medicine. 1991;229(5):407–13. Epub 1991/05/01. doi: 10.1111/j.1365-2796.1991.tb00367.x 2040866.
24. Eden S, Jagenburg R, Lindstedt G, Lundberg PA, Mellstrom D. Thyroregulatory changes associated with smoking in 70-year-old men. Clinical endocrinology. 1984;21(6):605–10. Epub 1984/12/01. doi: 10.1111/j.1365-2265.1984.tb01402.x 6439438.
25. Jorde R, Sundsfjord J. Serum TSH levels in smokers and non-smokers. The 5th Tromso study. Experimental and clinical endocrinology & diabetes: official journal, German Society of Endocrinology [and] German Diabetes Association. 2006;114(7):343–7. Epub 2006/08/18. doi: 10.1055/s-2006-924264 16915535.
26. Asvold BO, Bjoro T, Nilsen TI, Vatten LJ. Tobacco smoking and thyroid function: a population-based study. Archives of internal medicine. 2007;167(13):1428–32. Epub 2007/07/11. doi: 10.1001/archinte.167.13.1428 17620538.
27. Christensen SB, Ericsson UB, Janzon L, Tibblin S, Melander A. Influence of cigarette smoking on goiter formation, thyroglobulin, and thyroid hormone levels in women. The Journal of clinical endocrinology and metabolism. 1984;58(4):615–8. Epub 1984/04/01. doi: 10.1210/jcem-58-4-615 6699129.
28. Karakaya A, Tuncel N, Alptuna G, Kocer Z, Erbay G. Influence of cigarette smoking on thyroid hormone levels. Human toxicology. 1987;6(6):507–9. Epub 1987/11/01. doi: 10.1177/096032718700600610 3692496.
29. Lio S, Napolitano G, Marinuzzi G, Monaco F. Role of smoking in goiter morphology and thyrotropin response to TRH in untreated goitrous women. Journal of endocrinological investigation. 1989;12(2):93–7. Epub 1989/02/01. doi: 10.1007/BF03349928 2502572.
30. Song B, Zuo Z, Tan J, Guo J, Teng W, Lu Y, et al. Association of thyroid nodules with adiposity: a community-based cross-sectional study in China. BMC endocrine disorders. 2018;18(1):3. Epub 2018/01/29. doi: 10.1186/s12902-018-0232-8 29374470; PubMed Central PMCID: PMC5787304.
31. Nystrom E, Bengtsson C, Lapidus L, Petersen K, Lindstedt G. Smoking—a risk factor for hypothyroidism. Journal of endocrinological investigation. 1993;16(2):129–31. Epub 1993/02/01. doi: 10.1007/BF03347665 8463548.
32. Mehran L, Amouzegar A, Bakhtiyari M, Mansournia MA, Rahimabad PK, Tohidi M, et al. Variations in Serum Free Thyroxine Concentration Within the Reference Range Predicts the Incidence of Metabolic Syndrome in Non-Obese Adults: A Cohort Study. Thyroid: official journal of the American Thyroid Association. 2017;27(7):886–93. Epub 2017/05/10. doi: 10.1089/thy.2016.0557 28486021.
33. Andersen SL, Olsen J, Wu CS, Laurberg P. Smoking reduces the risk of hypothyroidism and increases the risk of hyperthyroidism: evidence from 450,842 mothers giving birth in Denmark. Clinical endocrinology. 2014;80(2):307–14. Epub 2013/07/03. doi: 10.1111/cen.12279 23808881.
34. Belin RM, Astor BC, Powe NR, Ladenson PW. Smoke exposure is associated with a lower prevalence of serum thyroid autoantibodies and thyrotropin concentration elevation and a higher prevalence of mild thyrotropin concentration suppression in the third National Health and Nutrition Examination Survey (NHANES III). The Journal of clinical endocrinology and metabolism. 2004;89(12):6077–86. Epub 2004/12/08. doi: 10.1210/jc.2004-0431 15579761.
35. Soldin OP, Goughenour BE, Gilbert SZ, Landy HJ, Soldin SJ. Thyroid hormone levels associated with active and passive cigarette smoking. Thyroid: official journal of the American Thyroid Association. 2009;19(8):817–23. Epub 2009/06/10. doi: 10.1089/thy.2009.0023 19505184; PubMed Central PMCID: PMC3643222.
36. Ittermann T, Thamm M, Schipf S, John U, Rettig R, Volzke H. Relationship of smoking and/or passive exposure to tobacco smoke on the association between serum thyrotropin and body mass index in large groups of adolescents and children. Thyroid: official journal of the American Thyroid Association. 2013;23(3):262–8. Epub 2012/10/11. doi: 10.1089/thy.2012.0110 23046200.
37. Benedict MD, Missmer SA, Ferguson KK, Vitonis AF, Cramer DW, Meeker JD. Secondhand tobacco smoke exposure is associated with prolactin but not thyroid stimulating hormone among nonsmoking women seeking in vitro fertilization. Environmental toxicology and pharmacology. 2012;34(3):761–7. Epub 2012/10/11. doi: 10.1016/j.etap.2012.09.010 23046534; PubMed Central PMCID: PMC3514562.
38. Cho NH, Choi HS, Kim KW, Kim HL, Lee SY, Choi SH, et al. Interaction between cigarette smoking and iodine intake and their impact on thyroid function. Clinical endocrinology. 2010;73(2):264–70. Epub 2010/01/29. doi: 10.1111/j.1365-2265.2010.03790.x 20105185.
39. Park S, Kim WG, Jeon MJ, Kim M, Oh HS, Han M, et al. Serum thyroid-stimulating hormone levels and smoking status: Data from the Korean National Health and Nutrition Examination Survey VI. Clinical endocrinology. 2018;88(6):969–76. Epub 2018/04/01. doi: 10.1111/cen.13606 29604104.
40. Jia M, Shi X, Gu X, Guan H, Teng X, Teng D, et al. Smoking Is Positively Associated with Antithyroperoxidase Antibodies and Antithyroglobulin Antibodies in Populations with Mildly Deficient Iodine Intake. Biological trace element research. 2019;187(2):383–91. Epub 2018/06/26. doi: 10.1007/s12011-018-1410-2 29938384.
41. Strieder TG, Prummel MF, Tijssen JG, Endert E, Wiersinga WM. Risk factors for and prevalence of thyroid disorders in a cross-sectional study among healthy female relatives of patients with autoimmune thyroid disease. Clinical endocrinology. 2003;59(3):396–401. Epub 2003/08/16. doi: 10.1046/j.1365-2265.2003.01862.x 12919165.
42. Pedersen IB, Laurberg P, Knudsen N, Jorgensen T, Perrild H, Ovesen L, et al. Smoking is negatively associated with the presence of thyroglobulin autoantibody and to a lesser degree with thyroid peroxidase autoantibody in serum: a population study. European journal of endocrinology. 2008;158(3):367–73. Epub 2008/02/27. doi: 10.1530/EJE-07-0595 18299471.
43. Carle A, Bulow Pedersen I, Knudsen N, Perrild H, Ovesen L, Banke Rasmussen L, et al. Smoking cessation is followed by a sharp but transient rise in the incidence of overt autoimmune hypothyroidism—a population-based, case-control study. Clinical endocrinology. 2012;77(5):764–72. Epub 2012/06/02. doi: 10.1111/j.1365-2265.2012.04455.x 22651374.
44. Effraimidis G, Tijssen JG, Wiersinga WM. Discontinuation of smoking increases the risk for developing thyroid peroxidase antibodies and/or thyroglobulin antibodies: a prospective study. The Journal of clinical endocrinology and metabolism. 2009;94(4):1324–8. Epub 2009/01/15. doi: 10.1210/jc.2008-1548 19141579.
45. Hou X, Li Y, Li J, Wang W, Fan C, Wang H, et al. Development of thyroid dysfunction and autoantibodies in Graves' multiplex families: an eight-year follow-up study in Chinese Han pedigrees. Thyroid: official journal of the American Thyroid Association. 2011;21(12):1353–8. Epub 2011/10/28. doi: 10.1089/thy.2011.0035 22029718.
46. Goh SY, Ho SC, Seah LL, Fong KS, Khoo DH. Thyroid autoantibody profiles in ophthalmic dominant and thyroid dominant Graves' disease differ and suggest ophthalmopathy is a multiantigenic disease. Clinical endocrinology. 2004;60(5):600–7. Epub 2004/04/24. doi: 10.1111/j.1365-2265.2004.02033.x 15104563.
47. Wiersinga WM. Smoking and thyroid. Clinical endocrinology. 2013;79(2):145–51. Epub 2013/04/16. doi: 10.1111/cen.12222 23581474.
48. Bartalena L, Piantanida E. Cigarette smoking: number one enemy for Graves ophthalmopathy. Polskie Archiwum Medycyny Wewnetrznej. 2016;126(10):725–6. Epub 2016/11/23. doi: 10.20452/pamw.3592 27872448.
49. Hersey P, Prendergast D, Edwards A. Effects of cigarette smoking on the immune system. Follow-up studies in normal subjects after cessation of smoking. The Medical journal of Australia. 1983;2(9):425–9. Epub 1983/10/29. 6633406.
50. Qiu F, Liang CL, Liu H, Zeng YQ, Hou S, Huang S, et al. Impacts of cigarette smoking on immune responsiveness: Up and down or upside down? Oncotarget. 2017;8(1):268–84. Epub 2016/12/03. doi: 10.18632/oncotarget.13613 27902485; PubMed Central PMCID: PMC5352117.
51. Bernecker C, Halim F, Lenz L, Haase M, Nguyen T, Ehlers M, et al. microRNA expressions in CD4+ and CD8+ T-cell subsets in autoimmune thyroid diseases. Experimental and clinical endocrinology & diabetes: official journal, German Society of Endocrinology [and] German Diabetes Association. 2014;122(2):107–12. Epub 2014/02/21. doi: 10.1055/s-0033-1361088 24554510.
52. Ehlers M, Thiel A, Bernecker C, Porwol D, Papewalis C, Willenberg HS, et al. Evidence of a combined cytotoxic thyroglobulin and thyroperoxidase epitope-specific cellular immunity in Hashimoto's thyroiditis. The Journal of clinical endocrinology and metabolism. 2012;97(4):1347–54. Epub 2012/01/20. doi: 10.1210/jc.2011-2178 22259066.
53. Jeremy JY, Mikhailidis DP. Vascular and platelet eicosanoids, smoking and atherosclerosis. Advances in experimental medicine and biology. 1990;273:135–46. Epub 1990/01/01. doi: 10.1007/978-1-4684-5829-9_14 2288270.
54. Harrison BJ. Influence of cigarette smoking on disease outcome in rheumatoid arthritis. Current opinion in rheumatology. 2002;14(2):93–7. Epub 2002/02/15. doi: 10.1097/00002281-200203000-00003 11845011.
Článek vyšel v časopise
PLOS One
2019 Číslo 11
- Proč se v Česku šíří několik „vymýcených“ infekcí najednou? Ptáme se odborníků
- ADHD jako evoluční výhoda? Výzkum se zaměřil na lovce a sběrače
- Není migréna jako migréna: Co pociťují ženy a co muži?
- Metamizol jako analgetikum první volby: kdy, pro koho, jak a proč?
- Není statin jako statin aneb praktický přehled rozdílů jednotlivých molekul
Nejčtenější v tomto čísle
- A daily diary study on maladaptive daydreaming, mind wandering, and sleep disturbances: Examining within-person and between-persons relations
- Molecular validation of clinical Pantoea isolates identified by MALDI-TOF
- Pathways to conspiracy: The social and linguistic precursors of involvement in Reddit’s conspiracy theory forum
- Urticating setae of tarantulas (Araneae: Theraphosidae): Morphology, revision of typology and terminology and implications for taxonomy