TY - JOUR
T1 - Strategies for evaluating the environment-public health interaction of long-term latency disease
T2 - The quandary of the inconclusive case-control study
AU - Pleil, Joachim D.
AU - Sobus, Jon R.
AU - Sheppard, Paul R.
AU - Ridenour, Gary
AU - Witten, Mark L.
N1 - Funding Information:
The authors are indebted to a number of experts in the various technical fields (biostatistics, epidemiology, risk assessment, and exposure assessment) for their excellent advice, arguments, and discussions; they are Stephen Rappaport (now at University of California in Berkeley), Douglas Crawford-Brown, and Gail Tudor from the School of Public Health, University of North Carolina at Chapel Hill, David Ashley and Ben Blount from Centers of Disease Control and Prevention, Atlanta, GA, and Andrew Lindstrom from the U.S. Environmental Protection Agency, Research Triangle Park, NC. Coauthors on original publications of the University of Arizona research on Fallon are acknowledged. Original ecologic research by the University of Arizona was funded in part by the Cancer Research and Prevention Foundation and the Gerber Foundation, neither of which is otherwise responsible for any content of this paper. This summary was funded in part by the US Environmental Protection Agency ( AM-96963201 , Fallon Leukemia Studies). This research has been subjected to (EPA) Agency review and approved for publication. Mention of trade names or commercial products does not constitute endorsement or recommendation for use.
PY - 2012/4/5
Y1 - 2012/4/5
N2 - Environmental links to disease are difficult to uncover because environmental exposures are variable in time and space, contaminants occur in complex mixtures, and many diseases have a long time delay between exposure and onset. Furthermore, individuals in a population have different activity patterns (e.g., hobbies, jobs, and interests), and different genetic susceptibilities to disease. As such, there are many potential confounding factors to obscure the reasons that one individual gets sick and another remains healthy. An important method for deducing environmental associations with disease outbreak is the retrospective case-control study wherein the affected and control subject cohorts are studied to see what is different about their previous exposure history. Despite success with infectious diseases (e.g., food poisoning, and flu), case-control studies of cancer clusters rarely have an unambiguous outcome. This is attributed to the complexity of disease progression and the long-term latency between exposure and disease onset. In this article, we consider strategies for investigating cancer clusters and make some observations for improving statistical power through broader non-parametric approaches wherein sub-populations (i.e., whole towns), rather than individuals, are treated as the cases and controls, and the associated cancer rates are treated as the dependent variable. We subsequently present some ecological data for tungsten and cobalt from studies by University of Arizona researchers who document elevated levels of tungsten and cobalt in Fallon, NV. These results serve as candidates for future hybrid ecologic case-control investigations of childhood leukemia clusters.
AB - Environmental links to disease are difficult to uncover because environmental exposures are variable in time and space, contaminants occur in complex mixtures, and many diseases have a long time delay between exposure and onset. Furthermore, individuals in a population have different activity patterns (e.g., hobbies, jobs, and interests), and different genetic susceptibilities to disease. As such, there are many potential confounding factors to obscure the reasons that one individual gets sick and another remains healthy. An important method for deducing environmental associations with disease outbreak is the retrospective case-control study wherein the affected and control subject cohorts are studied to see what is different about their previous exposure history. Despite success with infectious diseases (e.g., food poisoning, and flu), case-control studies of cancer clusters rarely have an unambiguous outcome. This is attributed to the complexity of disease progression and the long-term latency between exposure and disease onset. In this article, we consider strategies for investigating cancer clusters and make some observations for improving statistical power through broader non-parametric approaches wherein sub-populations (i.e., whole towns), rather than individuals, are treated as the cases and controls, and the associated cancer rates are treated as the dependent variable. We subsequently present some ecological data for tungsten and cobalt from studies by University of Arizona researchers who document elevated levels of tungsten and cobalt in Fallon, NV. These results serve as candidates for future hybrid ecologic case-control investigations of childhood leukemia clusters.
KW - Cancer cluster
KW - Case-control
KW - Childhood leukemia
KW - Ecologic study
KW - Environmental exposure
KW - Epidemiology
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U2 - 10.1016/j.cbi.2011.02.020
DO - 10.1016/j.cbi.2011.02.020
M3 - Article
C2 - 21382361
AN - SCOPUS:84859739568
SN - 0009-2797
VL - 196
SP - 68
EP - 78
JO - Chemico-Biological Interactions
JF - Chemico-Biological Interactions
IS - 3
ER -