Assessment of the exposure of children to environmental tobacco smoke (ETS) by different methods.

1. In order to elucidate the role of exposure to environmental tobacco smoke (ETS) in various acute and chronic illnesses in children, it is important to assess the degree of exposure by suitable methods. For this purpose, we determined the exposure to ETS in 39 children (4-15 years) and 43 adults (16+ years) by questionnaires, personal diffusion samplers for nicotine, and cotinine measurements in saliva and urine. In addition, the influence of the smoking status and the location of the home (urban or suburban) on the benzene exposure of the children was investigated. 2. On average, the 24 children living in homes with at least one smoker were exposed to ETS for 3.1 h/d. This is significantly longer (P<0.001) than the daily exposure time of the 15 children from nonsmoking homes (0.3 h/d). The nicotine concentrations on the personal samplers worn over 7 days were 0.615 and 0.046 microg/m3 for children from smoking and nonsmoking homes, respectively (P<0.001). Average salivary cotinine levels were 1.95 ng/ml in children from smoking homes and 0.11 ng/ml in children from nonsmoking homes (P< 0.01). The corresponding urinary cotinine levels were 29.4 and 4.5 ng/mg creatinine (P< 0.001). There was no difference in the extent of ETS exposure between children and adults from smoking households. Adults from nonsmoking homes tended to have higher ETS exposure than children from nonsmoking homes. 3. Exposure to benzene, which was determined by means of personal samplers, measurements of benzene in exhaled air and of the urinary benzene metabolite trans, trans-muconic acid, was not significantly related to the smoking status of the home but primarily dependent on the location of the home.     

Low level saliva cotinine determination and its application as a biomarker for environmental tobacco smoke exposure.

1. The determination of personal exposures to environmental tobacco smoke (ETS) and respirable suspended particles (RSP) for housewives, and fixed site monitoring of their homes, have been undertaken by these authors throughout Europe, South East Asia and Australia. Median 24 h time weighted average (TWA) concentrations for ETS particles and nicotine were found to be significantly higher for housewives living in smoking households compared with those living in nonsmoking households. For Europe, median TWA concentrations of 4.1 and <0.26 microg/ml for ETS particles and 0.63 and < 0.08 microg/m3 for nicotine were found for housewives living in smoking and nonsmoking households respectively. 2. In addition to the measurement of RSP, ETS particles and nicotine, saliva cotinine concentrations were determined using a radioimmunoassay method with a limit of quantitation of 1 ng/ml. Median saliva cotinine concentrations of 1.4 and <1 ng/ml were determined for European housewives living in smoking and nonsmoking households respectively, which reflected the poor limit of quantitation of this methodology. A chromatographic method utilising tandem mass-spectrometric detection was developed and validated for the determination of both cotinine and 3-hydroxycotinine, two of the main metabolites of nicotine, with lower limits of quantitation of 0.05 and 0.10 ng/ml respectively. This method was applied to samples collected from subjects with a known ETS exposure history and median cotinine concentrations of <0.05 ng/ml for self-reported unexposed nonsmokers, 0.65 ng/ml for nonsmokers reporting some ETS exposure and 1.28 ng/ml for nonsmokers living with smokers were found. 3. In conclusion, the measurement of RSP and ETS concentrations derived from personal or fixed site monitors for housewives may provide some indication of potential exposures to dependent children. The recent development and application of a highly sensitive assay for the determination of cotinine in saliva has provided evidence to suggest that concentrations determined at sub-nanogram levels may be used as a biomarker for ETS exposure. This improved methodology, coupled with non-invasive sampling for saliva, may be of significance when considering the application of cotinine as a biomarker for ETS exposure in children.     

Quantitation of cotinine in nonsmoker saliva using chip-based nanoelectrospray tandem mass spectrometry

A new analytical procedure was developed for the quantitation of nonsmoker salivary cotinine. Small volumes of saliva were diluted with water, fortified with cotinine-d3 (internal standard), then passed through small extraction columns. The analyte and internal standard were eluted with 0.1% (v/v) acetic acid/acetonitrile. Aliquots of each extract were analyzed directly, without chromatographic separation, using chip-based (NanoMate) nanospray tandem mass spectrometry. The calculated detection limit was 0.49 ng cotinine/mL saliva. This method was used to quantify salivary cotinine collected from nonsmoking human subjects living in one of three environmental tobacco smoke (ETS) exposure categories or "cells": 1. smoking home/smoking workplace; 2. smoking home/nonsmoking workplace; and 3. nonsmoking home/smoking workplace. Samples were collected during five sequential days, including Saturday, as part of a larger study to evaluate potential variability in exposure to ETS. Salivary cotinine measurements were made for the purpose of excluding misclassified smokers and for comparison with known levels of exposure to airborne nicotine in each exposure category. The concentrations observed were consistent with those reported from other large studies reported elsewhere. A non-parametric statistical test was applied to the data within each cell. No statistically significant differences were found between the mean cotinine concentrations collected on a weekday as compared to those collected on a weekend day. When the non-parametric test was applied to the three cells, a statistically significant difference was observed between cell 1 compared to cells 2 and 3. The salivary cotinine concentrations were thus statistically invariant over a five-day exposure period, and they were greatest under the conditions of smoking home and smoking workplace.     

Environmental tobacco smoke at home and in public places prior to smoking ban enforcement: Assessment by hair analysis in a population of young adult students

Despite inititatives to reduce tobacco consumption, smoking remains a primary cause of death for both smokers and nonsmokers exposed to environmental tobacco smoke (ETS). The characteristics of some specific groups can make them more exposed to ETS or limit the benefit of prevention measures. This study investigated determinants of ETS in a population of young adult students, considered at higher risk of exposure due to their specific lifestyle. This cross-sectional study involved 90 students aged 20 ± 1.7 years, from the University of Luxembourg, prior to the smoking ban enforcement in public places in the country. Participants reported their tobacco consumption and exposure to ETS at home and/or in public places, and provided a hair sample analyzed for nicotine and cotinine. Nicotine and cotinine were significantly higher in smokers than in nonsmokers' hair in general (median: 2.6 vs. 0.9 ng/mg and 87.1 vs. 22.5 pg/mg respectively). However, nonsmokers exposed to ETS at home and in public places had comparable concentrations to smokers (nic = 2.2 ng/mg; cot = 56.2 pg/mg), whereas unexposed nonsmokers presented significantly lower values (nic = 0.4 ng/mg, cot = 8.5 pg/mg). Nonsmokers exposed to ETS only at home presented higher values than nonsmokers only exposed in public places (nic: 1.3 vs. 0.8 ng/mg, cot: 70.4 vs. 15.0 pg/mg). The study shows the widespread exposure to ETS in this population, the importance of exposure assessment, and the relevance of hair analysis for this purpose. Results suggest that ETS can lead to equivalent exposure to active smoking and that exposure at home can highly contribute to ETS, which is not solved by smoking ban in public places.     

Correlation between urinary nicotine, cotinine and self-reported smoking status among educated young adults

The objective of this study was to correlate, differentiate and validate the self-reported smoking status of educated young adults with urinary biomarkers (i.e. nicotine and cotinine). Freshmen students were recruited on voluntary basis. They filled-up self-administered questionnaire and their urine samples were collected for analysis. The urinary nicotine (UN) and cotinine (UC) were measured by gas chromatograph-mass spectrometry. Smokers, non-smokers and ex-smokers were found to be both significantly correlated and different in their UN and UC levels. UC level of 25ng/ml was the optimal cut-off to differentiate smokers from non-smokers. Using this cut-off value, the prevalence of smoking among the students was found to be higher (15.4%) than the self-reported data (14.3%). UC is useful in validating individual recent smoking history and the cut-off could serve as a marker for assessing the clinical impact of smoking and environmental tobacco smoke (ETS) exposure on human health.     

Nicotine in hair of bar and restaurant workers

AIM: To measure the relation between workplace smoking policies and exposures to Environmental Tobacco Smoke (ETS) of workers in bars and restaurants. METHODS: 114 workers in Wellington and Auckland were questioned about sources of exposure to ETS and smoking habits, and details of the smoke-free policy in their work place were recorded. A hair sample was collected from each participant and tested for nicotine. RESULTS: Among non-smoking workers, hair nicotine levels varied strongly according to the smoke free policy at their place of work (Kruskall-Wallis, chi2 = 26.38, p < 0.0001). Those working in 100% smoke free restaurants had much lower levels than staff working in bars with no restrictions on smoking, and levels were intermediate for staff working in places with a partial smoking ban. These findings were not changed when adjustments were made for other sources of ETS exposure. Hair nicotine levels among nonsmokers working in places with no restriction on smoking were similar to hair nicotine levels of active smokers. CONCLUSION: The present New Zealand Smoke Free Environment Act does not protect workers in the hospitality industry from exposure to ETS. The findings from this study highlight the substantial levels of exposure of bar and restaurant staff from patrons' smoking.     

Maternal exposure to environmental tobacco smoke, GSTM1/T1 polymorphisms and oxidative stress

Environmental tobacco smoking (ETS) is known to be associated with adverse pregnancy outcomes. The purpose of this study was to investigate the relationship between maternal exposure to ETS and oxidative stress for neonates, as well as the effect of maternal genetic polymorphisms, glutathione-S-transferase M1 (GSTM1) and GSTT1, on this relationship. We used the radioimmunoassay to measure the urinary concentration of cotinine in 266 pregnant women who denied smoking cigarettes during pregnancy and in their singleton babies. In addition, the urinary concentration of malondialdehyde (MDA) and 8-hydroxy-2-deoxyguanosine (8-OH-dG) were assessed using high-performance liquid chromatography and enzyme-linked immunosorbent assay, respectively. We also extracted DNA from whole blood obtained from the mothers and then conducted polymerase chain reaction on the samples to determine the GSTM1 and GSTT1 genotypes. The maternal cotinine concentration was found to be significantly associated with the fetal cotinine concentration, particularly for mothers whose urine cotinine concentrations were above 120 microg/gcr (p<0.01). The fetal urine cotinine concentration was also found to be significantly associated with the fetal urine MDA concentration (p<0.01). When the null type maternal GSTM1 or the wild type GSTT1 was present, the maternal oxidative stress level increased significantly as the maternal continine concentration increased (MDA: p<0.01; 8-OH-dG: p<0.01). No significant relationships were found between maternal cotinine and fetal oxidative stress markers, however, the fetal MDA levels increased significantly as fetal cotinine levels increased. These results suggest that the maternal exposure to ETS affects the fetal urine cotinine concentration and induces production of maternal oxidative stress. In addition, maternal genetic polymorphisms of GSTM1 and GSTT1 may modify the oxidative stress by maternal exposure to ETS.     

Occupational exposure to environmental tobacco smoke: a study in Lisbon restaurants

Environmental tobacco smoke (ETS), also referred to as secondhand smoke (SHS), is a major threat to public health and is increasingly recognized as an occupational hazard to workers in the hospitality industry. Therefore, several countries have implemented smoke-free regulations at hospitality industry sites. In Portugal, since 2008, legislation partially banned smoking in restaurants and bars but until now no data have been made available on levels of indoor ETS pollution/exposure at these locations. The aim of this study was to examine the occupational exposure to ETS/SHS in several restaurants in Lisbon, measured by indoor fine particles (PM(2.5)) and urinary cotinine concentration in workers, after the partial smoking ban in Portugal. Results showed that the PM(2.5) median level in smoking designated areas was 253 μg/m3, eightfold higher than levels recorded in canteens or outdoor. The nonsmoking rooms of mixed restaurants exhibited PM(2.5) median level of 88 μg/m3, which is higher than all smoke-free locations studied, approximately threefold greater than those found in canteens. Importantly, urinary cotinine concentrations were significantly higher in nonsmoker employees working in those smoking designated areas, confirming exposure to ETS. The proportion of smokers in those rooms was found to be significantly positively correlated with nonsmoker urinary cotinine and indoor PM(2.5) levels, establishing that both markers were occupational-ETS derived. The use of reinforced ventilation systems seemed not to be sufficient to decrease the observed ETS pollution/exposure in those smoking locations. Taken together, these findings demonstrate that the partial restrictions on smoking in Portuguese venues failed to provide adequate protection to their employees, irrespective of protective measures used. Therefore, a smoke-free legislation protecting individuals from exposure to ETS/SHS in all public places and workplaces is urgently needed in Portugal.     

Environmental tobacco smoke exposure and respiratory morbidity in children

Environmental tobacco smoke (ETS) contains carcinogenic and toxic agents. Smoking might have a more serious effect on children than adults. We aimed to examine the effects of passive smoking on pulmonary function and respiratory health in children and to assess the concordance between parental self-reported smoking habits and urinary cotinine levels in their children. This cross-sectional study was conducted in the winter with the participation of 131 children (9-12 yr old). The procedure for each subject consisted of administration of a questionnaire to the parents, and collection of a urine sample and measurement of lung function in each child. Cotinine level excreted into urine was analyzed with respect to parental self-reported smoking behavior. Working mothers and mothers with higher level of education tended to smoke more at home (p values, respectively, .002 and .005). There was a statistical difference between the urinary cotinine levels of children when divided into two groups according to their fathers' smoking behavior at home (p = .0001). No statistically significant difference was determined in the mean episodes of respiratory infections treated during the last 12 mo among the groups formed according to daily number of cigarettes smoked by the parents at home (1: not exposed; 2: < 5 cigarettes; 3: 5-10 cigarettes; 4: > 10 cigarettes), or among the groups formed according to urinary cotinine levels (1: < 10 ng/ml; 2: > or =10 ng/ml). No significant difference was demonstrated in any of the respiratory function parameters investigated between the groups considered. The reliability of the declarations of the parents in the estimation of ETS exposure of children was low. Children are unable to remove themselves from ETS exposure. It is better to reduce the percentage of parents who smoke rather than to isolate smokers or increase ventilation.     

Environmental Tobacco Smoke Exposure and Respiratory Morbidity in Children

Environmental tobacco smoke (ETS) contains carcinogenic and toxic agents. Smoking might have a more serious effect on children than adults. We aimed to examine the effects of passive smoking on pulmonary function and respiratory health in children and to assess the concordance between parental self-reported smoking habits and urinary cotinine levels in their children. This cross-sectional study was conducted in the winter with the participation of 131 children (9–12 yr old). The procedure for each subject consisted of administration of a questionnaire to the parents, and collection of a urine sample and measurement of lung function in each child. Cotinine level excreted into urine was analyzed with respect to parental self-reported smoking behavior. Working mothers and mothers with higher level of education tended to smoke more at home (p values, respectively, .002 and.005). There was a statistical difference between the urinary cotinine levels of children when divided into two groups according to their fathers' smoking behavior at home (p = .0001). No statistically significant difference was determined in the mean episodes of respiratory infections treated during the last 12 mo among the groups formed according to daily number of cigarettes smoked by the parents at home (1: not exposed; 2: < 5 cigarettes; 3: 5–10 cigarettes; 4: > 10 cigarettes), or among the groups formed according to urinary cotinine levels (1: < 10 ng/ml; 2: ≥10 ng/ml). No significant difference was demonstrated in any of the respiratory function parameters investigated between the groups considered. The reliability of the declarations of the parents in the estimation of ETS exposure of children was low. Children are unable to remove themselves from ETS exposure. It is better to reduce the percentage of parents who smoke rather than to isolate smokers or increase ventilation.     

Assessment of prenatal tobacco smoke exposure by determining nicotine and its metabolites in meconium

Meconium samples collected from 115 neonates were analysed for nicotine, cotinine and trans -3-hydroxycotinine (OH-cotinine) by means of high-performance liquid chromatography (HPLC) to identify prenatal smoke exposure. The self-reported maternal smoking status during pregnancy was determined by means of a questionnaire and verified by measurements in urine prior to childbirth. The total sum of nicotine and its metabolites (Sum(tot)) of the first passed meconium samples was 1560 +/- 1024 pmol/g in newborns of smoking mothers. Smoking of less than five cigarettes was clearly detected. Sum(tot) remained constant in all meconium samples passed by a neonate in succession. However, the proportion of nicotine decreased with the time of passage after birth and the OH-cotinine proportion increased, whereas cotinine hardly changed. Nicotine or its metabolites were not detectable in meconium (detection limit < 20 pmol/g), when the mothers were only exposed to environmental tobacco smoke (ETS) using the HPLC method. The hypothesis that the content of nicotine metabolites in meconium reflects long-term smoke exposure could not be confirmed in newborns whose mothers had quit smoking during the latter half of pregnancy. Determining Sum(tot) enables the intensity of continuous smoking during pregnancy to be estimated in all meconium samples passed by a newborn.     

Time course of nicotine and cotinine incorporation into samples of nonsmokers' beard hair following a single dose of nicotine polacrilex

Hair nicotine and cotinine have been proposed as longer-term markers of exposure to secondhand smoke. In this study, we evaluated the rate and extent of nicotine and cotinine deposition into beard hair among six male nonsmokers following a single exposure to 4 mg of nicotine in Nicorette(?) (nicotine polacrilex) gum. We collected beard hair samples daily for 12 days following exposure and urine samples for 6 days after exposure. Using liquid chromatographic-tandem mass spectrometric analysis, we found that both nicotine and cotinine could be detected in beard samples within 24 h of the exposure and reached a maximum of about 71 pg nicotine and 47 pg cotinine/mg hair, respectively, within 1-2 days, followed by a gradual decline. Compared to beard hair concentrations, nicotine, cotinine, and hydroxycotinine were excreted in urine at much higher levels and also peaked on the day after exposure (mean ± SD urine cotinine = 300 ± 183 ng/mL). Our results confirmed that both nicotine and cotinine can be measured in beard hair samples following a single dose of nicotine. However, both the time-course and extent of deposition of these analytes in beard hair in this study differed from the results reported previously from a similar evaluation.     

Hubble-bubble (water pipe) smoking: levels of nicotine and cotinine in plasma,saliva and urine

OBJECTIVES: The purpose of the present study was to assess the levels of nicotine and cotinine in biological fluids (plasma, saliva, and urine) following hubble-bubble (HB) smoking. METHODS: Fourteen healthy male volunteers, aged 28 +/- 8 years, body weight of 82.7 +/- 13.53 kg, participated in the study. All volunteers were habitual HB smokers for 3.29 +/- 1.90 years who smoked at least 3 runs per week with an average of 20 g Mua'sel per run. Volunteers were requested to avoid smoking, at least 84 hours prior to the time of the study. After baseline samples were taken, volunteers started smoking 20 g of Mua'sel for a period of 45 minutes. Heparinized blood samples (5 or 10 ml each) were drawn for nicotine and cotinine analysis before, during and after the smoking period. Saliva samples were collected just before smoking (time 0) and at the end of smoking (45 min). Urine also was collected at time 0 and 24-hour urine collection was also taken to measure nicotine and cotinine excretion. Nicotine and cotinine were extracted from samples and assayed by gas chromatography. All data are presented as mean +/- SEM throughout the text, Tables and Figures unless indicated otherwise. RESULTS: Plasma nicotine levels rose from 1.11 +/- 0.62 ng/ml at baseline to a maximum of 60.31 +/- 7.58 ng/ml (p < 0.001) at the end of smoking (45 min). Plasma cotinine levels increased from 0.79 +/- 0.79 ng/ml at baseline to its highest concentration of 51.95 +/- 13.58 ng/ml (p < 0.001) 3 hours following the end of smoking. Saliva nicotine levels significantly rose from 1.05 +/- 0.72 to 624.74 +/- 149.3 ng/ml and also saliva cotinine levels significantly increased from 0.79 +/- 0.79 ng/ml to 283.49 +/- 75.04 ng/ml. Mean amounts of nicotine and cotinine excreted in urine during the 24-hour urine collection following smoking were equal to 73.59 +/- 18.28 and 249 +/- 54.78 microg, respectively. CONCLUSION: Following a single run of HB smoking, plasma, saliva and urinary nicotine and cotinine concentration increased to high values. This observation suggests that HB may not be an innocent habit, as people believe.     

Relationship between the level and time of exposure to tobacco smoke and urine nicotine and cotinine concentration

The study attempts to evaluate whether it is possible to determine time and level of exposure of rats to tobacco smoke based on nicotine and cotinine content in urine. The animals were exposed to tobacco smoke by inhalation in a specially designed experimental chambers. The exposure to three different tobacco smoke levels (500, 1000 and 1500 mg CO/m3 of air) lasted 6 h per day, for one, three and five days. Nicotine and cotinine concentrations were measured in daily urine using high performance liquid chromatography procedure developed by the authors. It has been shown that cotinine but not nicotine can be used as a biomarker of time and extent of exposure to tobacco smoke.     

HPTLC screening assay for urinary cotinine as biomarker of environmental tobacco smoke exposure among male adolescents

For selective screening determination of urinary cotinine, i.e. (S)-1-methyl-5-(3-pyridyl)-2-pyrrolidinone, the major metabolite of nicotine, the high-performance thin-layer chromatographic (HPTLC) method have been proposed. Prior the final HPTLC analysis the procedure required a solid-phase extraction (SPE) of cotinine from collected urine samples with 1-methyl-2-pyrrolidinone as an internal standard. Densitometrical quantitation of cotinine on the chromatograms have been performed with a 16-grayscale scanner using the specialized software implemented on a desktop microcomputer. The lower detection limit of cotinine was 6 microg/l allowing the method to be applied for the measurement a concentration of this compound in urine samples collected from 35 elementary schoolboys exposed on both moderate and/or significant ETS. The mean recovery of cotinine from urine samples was 93%. The mean intra-day accuracy for the analysis of cotinine in range 6-750 microg/l. including four paralell measurements, was 2.9 %. The results of cotinine measurements by proposed SPE-HPTLC procedure were used in the pilot studies for assessment of hazard from home ETS on the health status of elementary schoolboys, especially an increased risk for infectious respiratory track diseases.     

Implications of nicotine detected in autopsy cases of newborn babies and infants from the perspective of social medicine

Smoking by pregnant and parturient women is generally suspected to increase nicotine levels in fetal and infant blood. Supportive data of nicotine levels in infants is, however, inadequate. We investigated blood and muscle nicotine and cotinine levels in 14 autopsy cases of newborn babies and infants using gas chromatography. Among the 14 cases investigated, nicotine or cotinine was detected in six cases (42.9%). In each of these six cases, the mother was a smoker. Route of exposure to nicotine originating from smoking was transplacental in three cases, via breast milk in one case and secondhand smoke in two cases. Nicotine and cotinine levels in blood from the two cases with placental exposure were 10.6-84.4 ng/ml and 20.3-183 ng/ml, and levels in muscle from one case were 43.9 ng/g and 308 ng/g, respectively. Nicotine and cotinine levels in blood from exposure via breast milk were 19.1 ng/ml and 87.1 ng/ml, and from secondhand smoke were 0 ng/ml and 14.6-20.1 ng/ml. Mean concentrations of blood nicotine and cotinine in 68 autopsy cases of adult habitual smokers were 30.0 ng/ml and 247 ng/ml. Our data for nicotine and cotinine levels in infant blood seem to indicate that some infants who are born and develop under exposure to smoking by family members, particularly the mother, may show high nicotine levels in blood and experience possible health risks.     

Maternal exposure to environmental tobacco smoke,GSTM1/T1 polymorphisms and oxidative stress

Environmental tobacco smoking (ETS) is known to be associated with adverse pregnancy outcomes. The purpose of this study was to investigate the relationship between maternal exposure to ETS and oxidative stress for neonates, as well as the effect of maternal genetic polymorphisms, glutathione-S-transferase M1 (GSTM1) and GSTT1, on this relationship.We used the radioimmunoassay to measure the urinary concentration of cotinine in 266 pregnant women who denied smoking cigarettes during pregnancy and in their singleton babies. In addition, the urinary concentration of malondialdehyde (MDA) and 8-hydroxy-2-deoxyguanosine (8-OH-dG) were assessed using high-performance liquid chromatography and enzyme-linked immunosorbent assay, respectively. We also extracted DNA from whole blood obtained from the mothers and then conducted polymerase chain reaction on the samples to determine the GSTM1 and GSTT1 genotypes.The maternal cotinine concentration was found to be significantly associated with the fetal cotinine concentration, particularly for mothers whose urine cotinine concentrations were above 120 μg/g cr (p < 0.01). The fetal urine cotinine concentration was also found to be significantly associated with the fetal urine MDA concentration (p < 0.01). When the null type maternal GSTM1 or the wild type GSTT1 was present, the maternal oxidative stress level increased significantly as the maternal continine concentration increased (MDA: p < 0.01; 8-OH-dG: p < 0.01). No significant relationships were found between maternal cotinine and fetal oxidative stress markers, however, the fetal MDA levels increased significantly as fetal cotinine levels increased.These results suggest that the maternal exposure to ETS affects the fetal urine cotinine concentration and induces production of maternal oxidative stress. In addition, maternal genetic polymorphisms of GSTM1 and GSTT1 may modify the oxidative stress by maternal exposure to ETS.     

Measuring problems in estimating the exposure to passive smoking using the excretion of cotinine

Quality control studies on cotinine measurements following low level environmental tobacco smoke (ETS) exposure are rare. The exposure to ETS was controlled and systematically changed in a series of experiments in a climatic chamber. Healthy nonsmoking volunteers were exposed to ETS simultaneously. The duration and level of exposure varied using high (8, 17 and 25 ppm CO), and low (2 and 5 ppm CO) exposure levels. The variation between radioimmunoassay (RIA) and gas chromatography (GC) was high as was the variation between the results of RIA laboratories. There was also a high within-laboratory-variation. A 1:10 dilution seems to be preferable over a 1:3 dilution. Freezing the urine samples immediately after collection led to the detection of higher cotinine values than freezing the samples 24 h after collection. Highly reliable data for cotinine were obtained when the urine samples were kept frozen immediately after collection and fractionated sampling over 48-72 h was used. Our data show that estimating low-level ETS exposure by measuring urinary cotinine is highly susceptible to uncontrolled variation and errors. Sufficiently reliable estimates of low-level ETS exposure can be made only when fractionated sampling over 48-72 h is used and when the urine samples are kept frozen just after collection.     

Development and Characterization of an Elisa for Cotinine in Biological Fluids

Abstract

Cotinine is a major metabolite of nicotine and serves as an important biomarker of tobacco smoke exposure. To monitor exposure to tobacco smoke or nicotine, a sensitive enzyme-linked immunosorbent assay (ELISA) for cotinine was developed. The test had an 1–50 of between 0.5 and 1.0 ng/ml for cotinine and about 500-fold less affinity for nicotine. Few matrix effects were not detectable in human saliva, although relatively small matrix effects (1–50 for cotinine, 2.8 ng/ml) were observed in human serum and urine. The test accurately measured the levels of cotinine in NI5T standards in freeze-dried human urine derivative material (r = .9999) indicating its reliability for measurement of cotinine. The test readily detected low levels (5–500 nglml) of cotinine in human saliva and serum samples. Also, the levels of cotinine in plasma and urine samples from smoke-exposed mice and rats could be rapidly analyzed for cotinine. This ELISA is therefore a sensitive and accurate test for the determination of cotinine in plasma, serum, saliva, and urine samples from humans and animals, and can be successfully used for monitoring and quantifying exposure to tobacco smoke or nicotine.     

Biochemical markers of cardiovascular damage from tobacco smoke

There is growing evidence that several biochemical constituents of cigarette smoking play a significant role in the development and progression of heart and blood vessel damage, especially atherosclerotic lesions. Some biochemical markers of tobacco smoke may be determined in blood and urine samples. They are also the main responsible factors of cardiovascular harm. Nicotine and its major metabolite, cotinine, carbon monoxide, and thiocyanate seem to be specific markers. Ischaemic heart disease, cardiac arrhythmias, and endothelial dysfunction are the most common evidence of both active and passive smoking exposure. Dosage of cotinine in urine is of easier determination than that of other metabolites in assessing exposure to smoking, although carboxyhaemoglobin levels seem to be a qualitative, but not quantitative factor to estimate either the degree of cardiovascular damage or the level of exposure. Cigarette smoking is addictive because of nicotine, and it is nicotine withdrawal that causes many side effects of quitting smoking as well as the nicotine itself may exacerbate cardiac lesions. Also haematologic changes are a consequence of cigarette smoking exposure. Increased white blood cells, platelet aggregation and adhesiveness, fibrinogen level, and changes in serum lipids characterise the response to smoking. Anatomical and ultrastructural alterations of the heart and blood vessels are also described as a consequence of negative effects of biochemical markers of cigarette smoking. These alterations are known as "Smoke cardiomyopathy" in experimental pathology.