8,395 research outputs found
Common genetic effects on risk-taking preferences and choices
Although prior research has shown that risk-taking preferences and choices are correlated across many domains, there is a dearth of research investigating whether these correlations are primarily the result of genetic or environmental factors. We examine the extent to which common genetic factors account for the association between general risk-taking preferences and domain specific risk-taking preferences, and between general risk-taking preferences and risk taking choices in financial investments, stock market participation and business formation. Using data from 1898 monozygotic (MZ) and 1344 same-sex dizygotic (DZ) twins, we find that general risk-taking shares a common genetic component with domain-specific risk-taking preferences and risk-taking choices
Agricultural Trade Liberalization: Implications for Productive Factors in the U.S.
This report presents preliminary results of impacts on factors of production in the United States, following reductions in assistance to agriculture. Analysis was conducted by modifying the production structure of the U.S. country model in SWOPSIM to explicitly include inputs employed by agriculture. The results indicate that it is important to adequately model the production technology and include inputs, otherwise simulation results may not capture the impact of liberalization on input use and may not adequately represent changes in producer income.International Relations/Trade,
Bayesian testing of many hypotheses many genes: A study of sleep apnea
Substantial statistical research has recently been devoted to the analysis of
large-scale microarray experiments which provide a measure of the simultaneous
expression of thousands of genes in a particular condition. A typical goal is
the comparison of gene expression between two conditions (e.g., diseased vs.
nondiseased) to detect genes which show differential expression. Classical
hypothesis testing procedures have been applied to this problem and more recent
work has employed sophisticated models that allow for the sharing of
information across genes. However, many recent gene expression studies have an
experimental design with several conditions that requires an even more involved
hypothesis testing approach. In this paper, we use a hierarchical Bayesian
model to address the situation where there are many hypotheses that must be
simultaneously tested for each gene. In addition to having many hypotheses
within each gene, our analysis also addresses the more typical multiple
comparison issue of testing many genes simultaneously. We illustrate our
approach with an application to a study of genes involved in obstructive sleep
apnea in humans.Comment: Published in at http://dx.doi.org/10.1214/09-AOAS241 the Annals of
Applied Statistics (http://www.imstat.org/aoas/) by the Institute of
Mathematical Statistics (http://www.imstat.org
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