1.Urine Cotinine and Environmental Tobacco Exposure in Korean Adolescents.
Korean Journal of Family Medicine 2009;30(3):222-222
No abstract available.
Adolescent
;
Cotinine
;
Humans
;
Tobacco
2.Relation between Cotinine in the Urine and Indices Based on Self-Declared Smoking Habits
Akiko TSUTSUMI ; Jun KAGAWA ; Yuko YAMANO ; Toshio NAKADATE ; Satoru SHIMIZU
Environmental Health and Preventive Medicine 2001;6(4):240-247
Objectives: The reliability of surveys on smoking habits based on questionnaires was investigated, using the urinary cotinine content as an objective index. Methods: The subjects tested were 2,849 office workers of middle age, who responded to questions concerning their smoking status, and also their urinary cotinine was measured by the HPLC method. Results: The boundary value between smokers and non-smokers, determined by the histogram independent of the questionnaire, was 63.1 and 79.4 ng/mg of creatinine for males and females, respectively. The rate of misclassification of the non-smokers and former smokers as smokers was 1.3% for males and 1.8% for females, whereas that of current smokers as non-smokers was 6.3% and 2.1%. We also assessed the effect of smoke inhalation on the urinary cotinine value, and found a significant difference for males in the cotinine value by the presence of inhalation and also its depth. Conclusions: The rate of misclassification in this study was considered to be comparatively low. Several studies have also assessed the reliability of the questionnaire on smoking habits, and found different misclassification rates, indicating the dependence on the race and number of subjects tested. To our knowledge, there were only a few surveys on smoking among large groups, particularly in Japan, such as this one, therefore the results obtained in this study are meaningful.
Smoking
;
Cotinine
;
Indexes
;
seconds
;
Urine
3.Estimation of Secondhand Smoke Exposure in Clubs Based on Urinary Cotinine Levels.
Yu Jin LEE ; Young Ji LEE ; Man Joong JEON ; Joon SAKONG
Yeungnam University Journal of Medicine 2011;28(1):45-53
BACKGROUND: Increasing numbers of young people go to clubs. In Korea, however, no studies have been conducted regarding the exposure of club patrons to secondhand smoke. The present study was conducted to evaluate the degree of club customers' exposure to secondhand smoke. METHODS: The study subjects included 10 male and 12 female non-smokers. The investigational site was a club located in Daegu. Urine samples were collected before exposure to secondhand smoke in the club and 6 hours after a 3-hour exposure. The urine cotinine levels were measured via the LC-MS/MS method. A survey was conducted to collect data regarding the subjects' smoking experiences and the degree of exposure to secondhand smoke in their daily lives. RESULTS: The average urine cotinine level increased from 1.09 microg/L to 5.55 microg/L (p<0.05). No significant difference existed in the change in urine cotinine level between the male and female subjects. In addition, there was no significant difference in the change in urine cotinine level by the degree of exposure to secondhand smoke in daily life. CONCLUSIONS: The average urine cotinine level in all the subjects significantly increased after exposure to secondhand smoke. This is the first study on exposure to secondhand smoke in clubs; these results can be used to craft measures that reduce exposure to secondhand smoke in public places, such as clubs.
Cotinine
;
Female
;
Humans
;
Korea
;
Male
;
Smoke
;
Smoking
;
Tobacco Smoke Pollution
4.Urine Cotinine and Environmental Tobacco Exposure in Korean Adolescents.
Hae Reung LEE ; Hyeon Keun KIM ; Jang Suk YOO ; Kyu Nam KIM ; Seon Yeong LEE ; Sun Mi YOO ; Hyo Bin KIM ; Bong Seong KIM ; Soo Jong HONG ; Ja Hyeung KIM ; So Yeon LEE ; Moon Woo SEONG ; Do Hoon LEE
Korean Journal of Family Medicine 2009;30(1):31-38
BACKGROUND: The aim of this study was to elucidate the relationship of environmental tobacco smoke (ETS) exposure and the urine cotinine concentrations in Korean adolescents. METHODS: The study population was 1st grade high school adolescents (n = 1467, girls 22.2%) recruited from four high schools, two from Seoul, one from Kangleung and one from Woolsan. We obtained information on active smoking and ETS exposure through self-reported questionnaire and urine cotinine concentrations. RESULTS: The prevalence of active smoking was 6.9% in boys and 0.9% in girls. Median urine cotinine concentrations were 19.5 microgram/L (range, 0-2341 microgram/L) among smokers, and 0 microgram/L (range, 0-1359 microgram/L) among nonsmokers. The positive rate of urine cotinine among nonsmokers exposed to ETS was 2.9%. Boys were exposed to ETS in the order of frequency in PC room (79.6%), home (39.4%), school (11.5%), and public places (5.9%); girls were exposed in the order of frequency in home (40.9%), PC room (33.2%), public places (28.0%), and school (15.2%). The frequency and duration of ETS exposure were significantly larger and longer in boys than in girls. Boys contacted friends who smoked more than girls did (32.6% vs. 17.1%). Parents; smoking status was similar both in boys and girls. Any information on ETS exposure did not differ according to the detectable urine cotinine among nonsmoking adolescents. CONCLUSION: Low positive rate of urine cotinine and no association of urine cotinine with various ETS exposure history reflect that urine cotinine may not be a good marker for ETS exposure in Korean adolescents.
Adolescent
;
Cotinine
;
Friends
;
Humans
;
Prevalence
;
Smoke
;
Smoking
;
Tobacco
;
Surveys and Questionnaires
5.Relationship between Passive Smoke and Urinary Cotinine Level.
Min Jeoung KIM ; Cheol Hwan KIM ; Yang Hyeon KIM ; Joo Ho KANG
Journal of the Korean Academy of Family Medicine 2007;28(5):379-382
BACKGROUND: Cotinine, a nicotine metabolite detected in urine, has been recommended as the best quantitative marker of smoking and environmental tobacco smoke (ETS) exposure. The aim of this study was to analyze the relationship between indoor ETS and urinary cotinine level of the passive smokers. METHODS: We selected 42 nonsmokers who lived in Seoul and were not exposed to passive smoking at least 5 days before test. Urinary cotinine levels were measured by Smokescreen Colorimeter (Surescreen Diagnostics LTD, U.K.). We measured urinary cotinine levels twice (before and after smoking exposure). RESULTS: The mean urinary cotinine level was 0.33microgram/mL before smoking exposure, and 0.46microgram/mL after smoking exposure. There was statistically significant difference (P-value=0.003). There was no significant difference between exposure time and increase of urinary cotinine level(P=0.138, r=-0.233). There was also no significant difference between measuring time taking after exposure and increase of urinary cotinine level (P=0.671, r=0.067). CONCLUSION: One experience of indoor exposure to ETS caused significant elevation of urinary cotinine level.
Cotinine*
;
Nicotine
;
Seoul
;
Smoke*
;
Smoking
;
Tobacco
;
Tobacco Smoke Pollution
6.Relationship between Passive Smoke and Urinary Cotinine Level.
Min Jeoung KIM ; Cheol Hwan KIM ; Yang Hyeon KIM ; Joo Ho KANG
Journal of the Korean Academy of Family Medicine 2007;28(5):379-382
BACKGROUND: Cotinine, a nicotine metabolite detected in urine, has been recommended as the best quantitative marker of smoking and environmental tobacco smoke (ETS) exposure. The aim of this study was to analyze the relationship between indoor ETS and urinary cotinine level of the passive smokers. METHODS: We selected 42 nonsmokers who lived in Seoul and were not exposed to passive smoking at least 5 days before test. Urinary cotinine levels were measured by Smokescreen Colorimeter (Surescreen Diagnostics LTD, U.K.). We measured urinary cotinine levels twice (before and after smoking exposure). RESULTS: The mean urinary cotinine level was 0.33microgram/mL before smoking exposure, and 0.46microgram/mL after smoking exposure. There was statistically significant difference (P-value=0.003). There was no significant difference between exposure time and increase of urinary cotinine level(P=0.138, r=-0.233). There was also no significant difference between measuring time taking after exposure and increase of urinary cotinine level (P=0.671, r=0.067). CONCLUSION: One experience of indoor exposure to ETS caused significant elevation of urinary cotinine level.
Cotinine*
;
Nicotine
;
Seoul
;
Smoke*
;
Smoking
;
Tobacco
;
Tobacco Smoke Pollution
7.Determination of cotinine, phenylglyoxylic acid and mandelic acid in human urine by GC/MS.
Yuan-Yang WU ; Wei-Xing SHI ; Shu-Qing CHEN
Journal of Zhejiang University. Medical sciences 2009;38(3):229-234
OBJECTIVETo establish a GC/MS method for analysis of cotinine (COT), phenylglyoxylic acid (PA) and mandelic acid (MA) in human urine.
METHODSHuman urine samples were extracted by CCl(3) and derivatized with MSTFA after dried completely. The contents of COT, PA and MA were measured by GC/MS method with DB-5MS capillary column and EI ion-source.
RESULTThe calibration curves for COT in urine samples were linear over the concentration ranges of 0.0002 approximately 3.5 microg ml(-1), while PA and MA were both of 1.25 approximately 160 microg ml(-1). The limits of quantification were 0.0002 microg ml(-1), 1.25 microg ml(-1) and 1.25 microg ml(-1) for COT, PA and MA, respectively. The assay recoveries for COT, PA and MA ranged from 89.53% approximately 102.4%, 84.88% approximately 91.46% and 83.46% approximately 13.6%, respectively.
CONCLUSIONThe established method can detect cotinine, phenylglyoxylic acid and mandelic acid simultaneously, which would be used in routine assessment and monitoring of the internal exposure to nicotine and styrene in human body.
Cotinine ; urine ; Environmental Pollutants ; urine ; Gas Chromatography-Mass Spectrometry ; Glyoxylates ; urine ; Humans ; Mandelic Acids ; urine
8.Validity of Self-reported Smoking Using Urinary Cotinine among Vocational High School Students.
Journal of Preventive Medicine and Public Health 2009;42(4):223-230
OBJECTIVES: This study was conducted to validate self-reported smoking among high school students using urinary cotinine. METHODS: A self report of smoking behavior was collected together with urine sample for cotinine analysis from 130 male and female students in two vocational high school students in November, 2007. Validity and agreement between self-reported smoking and urinary cotinine was analyzed with STATA 9.0 for different definitions of current smokers, and frequent and daily smokers. Urinary cotinine concentration was measured by the DRI Cotinine Assay for urine (Microgenics Corp., Fremont, CA) on Toshiba 200FR. The cut-off point of urinary cotinine was 50 ng/dl. RESULTS: The concentrations of urinary cotinine were significantly different according to the frequency and amount of smoking. Sensitivity and specificity was 90.9% and 91.8% respectively, and the Cohen's kappa value was 0.787 among the current smokers who smoked at least one day during one month preceding the survey. The comparable high sensitivity, specificity, and kappa value were shown also among the other definitions of current smokers, that is, subjective smokers, and weekly smokers. CONCLUSIONS: The results showed the high validity of self-reported smoking among high school students. However, due to the small sample size and limitation of the participants, it is cautious to generalize the results to overall high school students.
Adolescent
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*Adolescent Behavior
;
Cotinine/*urine
;
Female
;
Humans
;
Korea/epidemiology
;
Male
;
Self Disclosure
;
Smoking/epidemiology/*urine
;
Students
9.The Effect of Life Smoking Cessation Program- multidisciplinary approach.
Sung Rae SHIN ; Dong Sup LEE ; Jung Hwan PARK
Journal of Korean Academy of Nursing 2000;30(1):110-121
This study was designed to develop the life moking cessation program with multidisciplinary approach using the Bandura's theory of self-efficacy and confirm the effect of it on the self-efficacy and smoking amount in college students. For this purpose non-equivalent control group, pretest-posttest design was used. The participating subjects in this study were 46 male college freshmen, 23 in experimental and 23 in control group. The experimental group received the 8 sessions of lecture and small group discussions for 4 weeks and a telephone coaching program for a period of 8 weeks. The control group received 5 sessions of lecture without further treatments. The data was collected from March 15 to June 11, 1999, and analysed by SAS/PC program with X2 test, simple t, paired t test. The results were as follows. 1. The score of self-efficacy was significantly increased over time in the experimental group than those of the control group. 2. The amount of urine cotinine was decreased over time in the experimental group, number of cigarettes smoked a day were significantly decreased, and they were significantly less than those of the control group. In conclusion it was found that the Life Smoking Cessation Program with Multidisciplinary Approach was an effective nursing intervention for increasing self efficacy and reducing the amount of smoking in male college students. Therefore, future smoking cessation programs should always consider the concept of self-efficacy and ways to positively reinforce it.
Cotinine
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Humans
;
Male
;
Nursing
;
Self Efficacy
;
Smoke*
;
Smoking Cessation*
;
Smoking*
;
Telephone
;
Tobacco Products
10.Urine Cotinine for Assessing Tobacco Smoke Exposure in Korean: Analysis of the Korea National Health and Nutrition Examination Survey (KNHANES).
Sungmo JUNG ; In Seon LEE ; Sae Byol KIM ; Chan Soo MOON ; Ji Ye JUNG ; Young Ae KANG ; Moo Suk PARK ; Young Sam KIM ; Se Kyu KIM ; Joon CHANG ; Eun Young KIM
Tuberculosis and Respiratory Diseases 2012;73(4):210-218
BACKGROUND: The level of urine cotinine is an indicator of tobacco smoke exposure. The purpose of this study is to investigate urine cotinine for the purpose of assessing the smoking status of Korean smokers and non-smokers exposed to tobacco smoke. METHODS: The subjects were identified from the 2007-2009 and the 2010 data sets of the Korea National Health and Nutrition Examination Survey (KNHANES). They were assigned as non-smokers, current smokers and ex-smokers. Non-smokers were also divided into three subset groups according to the duration of smoke exposure. Each group was stratified by gender prior to analysis. RESULTS: The median value of urine cotinine in the male current smokers was 1,221.93 ng/mL which was the highest among all groups. The difference between levels of urine cotinine for male and the female groups was statistically significant (p<0.01). In the female group, passive smoke exposure groups reported higher urine cotinine levels than non-exposure groups (p=0.01). The cutoff point for the discrimination of current smokers from non-smokers was 95.6 ng/mL in males and 96.8 ng/mL in females. The sensitivity and specificity were 95.2% and 97.1%, respectively, in males, 96.1% and 96.5% in females. However, the determination of urine cotinine level was not useful in distinguishing between passive smoke exposure groups and non-exposure groups. CONCLUSION: Urine cotinine concentration is a useful biomarker for discriminating non-smokers from current smokers. However, careful interpretation is necessary for assessing passive smoke exposure by urine cotinine concentration.
Cotinine
;
Discrimination (Psychology)
;
Female
;
Humans
;
Korea
;
Male
;
Nutrition Surveys
;
Smoke
;
Smoking
;
Tobacco