Factors influencing bone lead concentration in a suburban community assessed by noninvasive K x-ray fluorescence
M. J. Kosnett, C. E. Becker, J. D. Osterloh, T. J. Kelly and D. J. Pasta
Center for Occupational and Environmental Health, University of California, San Francisco 94143-0843.
OBJECTIVE--To determine the influence of demographic, exposure and medical
factors on the bone lead concentration of subjects with background
(nonindustrial) environmental lead exposure. DESIGN--Survey.
SETTING--Suburban residential community. PARTICIPANTS--A total of 101
subjects (49 males, 52 females; aged 11 to 78 years) were recruited from 49
of 123 households geographically located in a suburban residential
neighborhood unexposed to any major source of industrial lead emissions.
MAIN OUTCOME MEASUREMENTS--Cortical bone lead concentrations in the
midshaft of the tibia were noninvasively measured by in vivo K x-ray
fluorescence. Blood lead concentrations were measured by anodic stripping
voltammetry. An administered questionnaire assessed potential sources of
lead exposure and medical conditions affecting bone metabolism.
RESULTS--After the exclusion of one outlier, log-transformed bone lead
concentration was highly correlated with age (r = .71; P < or = .0001).
Bone lead concentration showed no significant change up to age 20 years,
increased with the same slope in men and women between ages 20 and 55
years, and then increased at a faster rate in men older than 55 years. In
addition to the variables age and sex, the best fitting multiple regression
model for bone lead concentration (R2 = .66; P < or = .0001) revealed a
positive correlation with total pack-years of cigarette smoking and a
negative correlation with a history of having nursed an infant for longer
than 2 weeks. Blood lead concentrations of the subjects were low (geometric
mean, 0.24 mumol/L [4.9 micrograms/dL]) and after log transformation were
weakly correlated with log-transformed bone lead concentration (r = .23; P
= .02). CONCLUSIONS--The age- and sex-related increases in bone lead
concentration found by K x-ray fluorescence concur with published
postmortem studies of bone lead concentration and are consistent with the
kinetics of bone turnover and secular trends in lead exposure. These data
help to establish a reference range for assessing the lead burden of other
populations with environmental or occupational lead exposure.
Gender and Race/Ethnicity Differences in Lead Dose Biomarkers
Theppeang et al.
Am. J. Public Health 2008;98:1248-1255.
ABSTRACT
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Gracia and Snodgrass
Am J Health Syst Pharm 2007;64:45-53.
ABSTRACT
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Influence of Maternal Bone Lead Burden and Calcium Intake on Levels of Lead in Breast Milk over the Course of Lactation
Ettinger et al.
Am J Epidemiol 2006;163:48-56.
ABSTRACT
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Nash et al.
Am J Epidemiol 2004;160:901-911.
ABSTRACT
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Mycyk and Leikin
The Annals of Pharmacotherapy 2004;38:821-824.
ABSTRACT
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Korrick et al.
Am J Epidemiol 2002;156:335-343.
ABSTRACT
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Predictors of DMSA chelatable lead, tibial lead, and blood lead in 802 Korean lead workers
Todd et al.
Occup. Environ. Med. 2001;58:73-80.
ABSTRACT
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Brown et al.
Occup. Environ. Med. 2000;57:535-541.
ABSTRACT
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Hoppin et al.
Pediatrics 1997;100:365-370.
ABSTRACT
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Occupational Illness
Newman
NEJM 1995;333:1128-1134.
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