ASSOCIATION BETWEEN EXPOSURE TO ENVIRONMENTAL TOBACCO SMOKE AND BIOMARKERS OF CARDIOVASCULAR DISEASE IN NHANES 1999-2006 Public
Aboye, Dereje Mekonnen (2013)
Abstract
Background: Exposure to environmental tobacco smoke (ETS) is among the leading causes of preventable poor health and premature death in the developed world. Current knowledge pertaining to the association between ETS exposure and early biomarkers of cardiovascular disease is limited.
Objective: This study's purpose was to
investigate the association between ETS exposure
and the target biomarker concentration.
Methods: Using data from 1996-2006 U.S. National
Health and Nutrition Examination Survey (NHANES), adult (≥20
years) non-smokers were selected for analysis (N=4,986). We used
weighted multiple linear regression to investigate the association
between the target biomarker concentration and ETS exposure,
controlling for other predictors of cardiovascular disease risk
(diabetes, hypertension, high cholesterol, obesity, and physical
activity status). We defined ETS exposure as either self-reported
ETS exposure at home or serum cotinine tertile and tested these in
separate models.
Results: In the homocysteine models, the
regression coefficient of the ETS exposure at home variable was
statistically significant and the β
coefficient (95% confidence interval) of the ETS term was
0.48 (5.12, 6.57), p-value <0.01. In the
cotinine model, the β for the
cotinine categories were -0.02 (-0.29, 0.25),
p-value=0.88 for the moderate category and 0.34(0.06,
0.63), p =0.02 for the high category. The ETS
variable coefficients were not statistically significant in the
c-reactive protein models.
Conclusions: We found significant
associations between ETS exposure and serum homocysteine, an early
biomarker of cardiovascular risk, in a large, representative sample
of U.S. adult non-smokers. These findings build on previous studies
reporting significant associations and illustrate the need for
continued public health strategies to control ETS
exposure.
Table of Contents
Contents
Introduction
.........................................................................................................................
1
Methods..............................................................................................................................
6
Results
................................................................................................................................
8
Discussion
.........................................................................................................................
10
Conclusions
.......................................................................................................................
12
References
.........................................................................................................................
13
Tables
Table 1. Unweighted frequencies (weighted %) of missing and
non-missing observations, Adult (age ≥20) non-smokers,
NHANES 1999-2006
(N=4,986)........................................17
Table 2. Weighted frequencies of selected categorical
variables, adult (age ≥20) non-smokers, NHANES 1999-2006
(N=4,986)........................................................................18
Table 3. Weighted descriptive statistics of selected
continuous variables, adult (age ≥20) non-smokers, NHANES
1999-2006
(N=4,986)................................................................20
Table 4. Characteristics of adult (age ≥20) non-smokers
(weighted % unless noted) by home ETS exposure status, NHANES
1999-2006
(N=4,986)...........................................21
Table 5. Weighted frequencies (%) by cotinine tertile and
weighted geometric mean (geometric standard deviation)
concentrations of serum cotinine, homocysteine, c-reactive protein,
and total cholesterol among adult (≥20) non-smokers, by ETS
exposure status at home, NHANES
1999-2006................................................................................22
Table 6. Results of multivariable linear regression of serum
homocysteine and ETS exposure at home, adult (≥20)
non-smokers, NHANES 1999-2006 (Adjusted R2= 0.28)
23
Table 7. Multivariable linear regression analysis of serum
homocysteine by serum cotinine level, among adult (≥20)
non-smokers, NHANES 1999-2006 (Adjusted R2=
0.28)................................................................................................................24
Table 8. Multivariable linear regression analysis of serum
homocysteine by ETS exposure status at home and workplace, among
adult (≥20) non-smokers, NHANES 1999-2006 (Adjusted
R2=0.20)..........................................................................................25
Table 9. Multivariable analysis of serum c-reactive protein
level among nonsmoker adults (≥ 20 years) by ETS exposure at
home, NHANES 1999-2006 (Adjusted
R2=0.10).........26
Table 10. Linear regression analysis of c-reactive protein
among adult (≥20) non-smokers by ETS exposure status at home
and work, NHANES 1999-2006 (Adjusted R2=0.13)...27
Table 11. Linear regression analysis of c-reactive protein
among adult (≥20) non-smokers by serum cotinine level, NHANES
1999-2006 (Adjusted R2=0.10)...................28
Figures
Figure 1. Histogram of residuals from multiple linear
regression model of homoysteine and ETS exposure at
home................................................................................................29
Figure 2. Linear regression model for log Homoysteine, by ETS
exposure status at
home...................................................................................................................................30
Figure 3. Scatter plot of predicted versus observed values
from multiple linear regression of log homoysteine and ETS exposure
at
home................................................................31
Figure 4 & 5. Linear regression model for homocysteine, by
serum cotinine category....32
Figure 6. Linear regression model for log homocysteine,
by serum cotinine category.....34
Figure 7. Linear regression model for homocysteine, by
ETS exposure status at home and
workplace...........................................................................................................................35
Figure 8 & 9. Linear regression model for log
homocysteine, by ETS exposure status at home and
workplace..........................................................................................................36
Figure 10. Linear regression model for c-reactive
protein by ETS exposure status at
home...................................................................................................................................38
Figure 11 & 12. Linear regression model for
c-reactive protein by ETS exposure status at home and
workplace..........................................................................................................39
Figure 13. Scatter plot: log homocysteine by log
cotinine................................................41
Figure 14. Scatter plot c-reactive protein by log
continine...............................................42
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