Biomedical Engineering Reference
In-Depth Information
57. Culverhouse, R., Klein, T. and Shannon, W. (2004) Detecting epistatic interactions contributing
to quantitative traits.
Genetic Epidemiology
,
27
, 141 -152.
58. Cheverud, J.M. (2001) A simple correction for multiple comparisons in interval mapping genome
scans.
Heredity
,
87
, 52 - 58.
59. Li, J. and Ji, L. (2005) Adjusting multiple testing in multilocus analyses using the eigenvalues of
a correlation matrix.
Heredity
,
95
, 221 - 227.
60. Storey, J.D. and Tibshirani, R. (2003) Statistical significance for genomewide studies.
Proceedings
of the National Academy of Sciences of the United States of America
,
100
, 9440 -9445.
61. Purcell, S., Cherny, S.S. and Sham, P.C. (2003) Genetic Power Calculator: design of linkage
and association genetic mapping studies of complex traits.
Bioinformatics (Oxford, England)
,
19
,
149 - 150.
62. Menashe, I., Rosenberg, P.S. and Chen, B.E. (2008) PGA: power calculator for case-control
genetic association analyses.
BMC Genetics
,
9
, 36.
63. Gordon, D., Haynes, C., Blumenfeld, J. and Finch, S.J. (2005) PAWE-3D: visualizing power for
association with error in case-control genetic studies of complex traits.
Bioinformatics (Oxford,
England)
,
21
, 3935 -3937.
64. Zondervan, K.T. and Cardon, L.R. (2007) Designing candidate gene and genome-wide case-control
association studies.
Nature Protocols
,
2
, 2492 -2501.
65. Balding, D.J. (2006) A tutorial on statistical methods for population association studies.
Nature
Reviews Genetics
,
7
, 781 - 791. A helpful overview of methods and issues for case - control asso-
ciation studies.
66. Spielman, R.S., McGinnis, R.E. and Ewens, W.J. (1993) Transmission test for linkage disequilib-
rium: the insulin gene region and insulin-dependent diabetes mellitus (IDDM).
American Journal
of Human Genetics
,
52
, 506 - 516.
67. Martin, E.R., Monks, S.A., Warren, L.L. and Kaplan, N.L. (2000) A test for linkage and association
in general pedigrees: the pedigree disequilibrium test.
American Journal of Human Genetics
,
67
,
146 - 154.
68. Rabinowitz, D. and Laird, N. (2000) A unified approach to adjusting association tests for popula-
tion admixture with arbitrary pedigree structure and arbitrary missing marker information.
Human
Heredity
,
50
, 211 - 223.
69. Laird, N.M., Horvath, S. and Xu, X. (2000) Implementing a unified approach to family-based
tests of association.
Genetic Epidemiology
,
19
(Suppl 1), S36 - S42.
70. Lewinger, J.P. and Bull, S.B. (2006) Validity, efficiency, and robustness of a family-based test of
association.
Genetic Epidemiology
,
30
, 62 - 76.
71. Horvath, S., Xu, X, Lake, S.L.
et al
. (2004) Family-based tests for associating haplotypes with
general phenotype data: application to asthma genetics.
Genetic Epidemiology
,
26
, 61 - 69.
72. Xu, X., Rakovski, C. and Laird, N. (2006) An efficient family-based association test using multiple
markers.
Genetic Epidemiology
,
30
, 620 - 626.
73. Rakovski, C.S., Weiss, S.T., Laird, N.M. and Lange, C. (2008) FBAT-SNP-PC: an approach for
multiple markers and single trait in family-based association tests.
Human Heredity
,
66
, 122 - 126.
74. McPeek, M.S. and Sun, L. (2000) Statistical tests for detection of misspecified relationships by
use of genome-screen data.
American Journal of Human Genetics
,
66
, 1076 -1094.