×
Sibley, Alexander B.; Li, Zhiguo; Jiang, Yu; Li, Yi-Ju; Chan, Cliburn; Allen, Andrew; Owzar, Kouros

Facilitating the calculation of the efficient score using symbolic computing. (English) Zbl 07663940

Am. Stat. 72, No. 2, 199-205 (2018).

MSC:

62-XX Statistics

Keywords:

computer algebra; genome-wide association study; mathematical statistics; nuisance parameters; trio data

Software:

SymPy; SageMath; MACSYMA; Maxima; Mathematica; Maple; NCAlgebra; PythonTeX
Cite Review PDF
Full Text: DOI Link

References:

[1] Abecasis, G. R.; Cardon, L. R.; Cookson, W. O., A General Test of Association for Quantitative Traits in Nuclear Families, The American Journal of Human Genetics, 66, 279-292 (2000)
[2] Andrews, D. F.; Stafford, J. E., Symbolic Computation for Statistical Inference (2000), New York: Oxford University Press, New York · Zbl 0995.62002
[3] Caviness, B., Computer Algebra: Past and Future, Journal of Symbolic Computation, 2, 217-236 (1986) · Zbl 0636.68033
[4] Conneely, K. N.; Boehnke, M., So Many Correlated Tests, So Little Time! Rapid Adjustment of P Values for Multiple Correlated Tests, The American Journal of Human Genetics, 81, 1158-1168 (2007)
[5] Continuum Analytics, Anaconda Software Distribution, v2-2.4.0, (2016)
[6] Ekström Smedby, K.; Lindgren, C. M.; Hjalgrim, H.; Humphreys, K.; Schöllkopf, C.; Chang, E. T.; Roos, G.; Ryder, L. P.; Falk, K. I.; Palmgren, J.; Kere, J.; Melbye, M.; Glimelius, B.; Adami, H.-O., Variation in DNA Repair Genes ERCC2, XRCC1, and XRCC3 and Risk of Follicular Lymphoma, Cancer Epidemiology and Prevention Biomarkers, 15, 258-265 (2006)
[7] Freedman, D. A., How can the Score Test be Inconsistent?, The American Statistician, 61, 291-295 (2007)
[8] Freedman, N. D.; Ahn, J.; Hou, L.; Lissowska, J.; Zatonski, W.; Yeager, M.; Chanock, S. J.; Chow, W. H.; Abnet, C. C., Polymorphisms in Estrogen- and Androgen-metabolizing Genes and the Risk of Gastric Cancer, Carcinogenesis, 30, 71-77 (2009)
[9] Fulker, D.; Cherny, S.; Sham, P.; Hewitt, J., Combined Linkage and Association Sib-pair Analysis for Quantitative Traits, The American Journal of Human Genetics, 64, 259-267 (1999)
[10] Gaudet, M. M.; Kirchhoff, T.; Green, T.; Vijai, J.; Korn, J. M.; Guiducci, C.; Segr, A. V.; Mcgee, K.; Mcguffog, L.; Kartsonaki, C.; Morrison, J.; Healey, S.; Sinilnikova, O. M.; Stoppa-Lyonnet, D.; Mazoyer, S.; Gauthier-Villars, M.; Sobol, H.; Longy, M.; Frenay, M.; Collaborators, G. S.; Hogervorst, F. B. L.; Rookus, M. A.; Colle, J. M.; Hoogerbrugge, N.; Van Roozendaal, K. E. P.; Collaborators, H. S.; Piedmonte, M.; Rubinstein, W.; Nerenstone, S.; Van Le, L.; Blank, S. V.; Calds, T.; De La Hoya, M.; Nevanlinna, H.; Aittomki, K.; Lazaro, C.; Blanco, I.; Arason, A.; Johannsson, O. T.; Barkardottir, R. B.; Devilee, P.; Olopade, O. I.; Neuhausen, S. L.; Wang, X.; Fredericksen, Z. S.; Peterlongo, P.; Manoukian, S.; Barile, M.; Viel, A.; Radice, P.; Phelan, C. M.; Narod, S.; Rennert, G.; Lejbkowicz, F.; Flugelman, A.; Andrulis, I. L.; Glendon, G.; Ozcelik, H.; OCGN; Toland, A. E.; Montagna, M.; D’Andrea, E.; Friedman, E.; Laitman, Y.; Borg, A.; Beattie, M.; Ramus, S. J.; Domchek, S. M.; Nathanson, K. L.; Rebbeck, T.; Spurdle, A. B.; Chen, X.; Holland, H.; kConFab; John, E. M.; Hopper, J. L.; Buys, S. S.; Daly, M. B.; Southey, M. C.; Terry, M. B.; Tung, N.; Overeem Hansen, T. V.; Nielsen, F. C.; Greene, M. I.; Mai, P. L.; Osorio, A.; Durn, M.; Andres, R.; Bentez, J.; Weitzel, J. N.; Garber, J.; Hamann, U.; Peock, S.; Cook, M.; Oliver, C.; Frost, D.; Platte, R.; Evans, D. G.; Lalloo, F.; Eeles, R.; Izatt, L.; Walker, L.; Eason, J.; Barwell, J.; Godwin, A. K.; Schmutzler, R. K.; Wappenschmidt, B.; Engert, S.; Arnold, N.; Gadzicki, D.; Dean, M.; Gold, B.; Klein, R. J.; Couch, F. J.; Chenevix-Trench, G.; Easton, D. F.; Daly, M. J.; Antoniou, A. C.; Altshuler, D. M.; Offit, K., Common Genetic Variants and Modification of Penetrance of BRCA2-Associated Breast Cancer, PLOS Genetics, 6, 1-12 (2010)
[11] Hall, W. J.; Mathiason, D. J., On Large-Sample Estimation and Testing in Parametric Models, International Statistical Review/Revue Internationale de Statistique, 58, 77-97 (1990) · Zbl 0715.62058
[12] Helton, J. W.; Miller, R. L.; Stankus, M., NCAlgebra: A Mathematica Package for doing Noncommuting Algebra, (1996)
[13] Horton, N. J.; Hardin, J. S., Teaching the Next Generation of Statistics Students to Think with Data: Special Issue on Statistics and the Undergraduate Curriculum, The American Statistician, 69, 259-265 (2015) · Zbl 07671743
[14] Jiang, Y.; Ji, Y.; Sibley, A. B.; Li, Y.-J.; Allen, A. S., Leveraging Population Information in Family-Based Rare Variant Association Analyses of Quantitative Traits, Genetic Epidemiology, 41, 98-107 (2017)
[15] Lin, D. Y., An Efficient Monte Carlo Approach to Assessing Statistical Significance in Genomic Studies, Bioinformatics, 21, 781 (2005)
[16] Magnus, J. R.; Neudecker, H., Matrix Differential Calculus with Applications in Statistics and Econometrics (2007), Chichester, UK: Wiley, Chichester, UK
[17] Maplesoft, A. Division Of Waterloo Maple Inc., Maple v18.0 (2014), Waterloo, Ontario: Springer Science+Business Media, LLC, Waterloo, Ontario
[18] Maxima, Maxima, a Computer Algebra System, v5.39.0, (2016)
[19] Moses, J., Macsyma: A Personal History, Journal of Symbolic Computation, 47, 78-84 (2012) · Zbl 1231.68291
[20] Pang, H.; Kim, I.; Zhao, H., Random Effects Model for Multiple Pathway Analysis with Applications to Type II Diabetes Microarray Data, Statistics in Biosciences, 7, 167-186 (2015)
[21] Poore, G. M., Reproducible Documents with PythonTeX,, Proceedings of the 12th Python in Science Conference, 123-130 (2013)
[22] Rao, C. R., Tests of Significance in Multivariate Analysis, Biometrika, 35, 58-79 (1948) · Zbl 0031.06202
[23] Schaffner, S.; Foo, C.; Gabriel, S.; Reich, D.; Daly, M.; Altshuler, D., Calibrating a Coalescent Simulation of Human Genome Sequence Variation, Genome Research, 15, 1576-1583 (2005)
[24] Seaman, S.; Müller-Myhsok, B., Rapid Simulation of p Values for Product Methods and Multiple-Testing Adjustment in Association Studies, The American Journal of Human Genetics, 76, 399-408 (2005)
[25] Siamakpour-Reihani, S.; Owzar, K.; Jiang, C.; Scarbrough, P. M.; Craciunescu, O. I.; Horton, J. K.; Dressman, H. K.; Blackwell, K. L.; Dewhirst, M. W., Genomic Profiling in Locally Advanced and Inflammatory Breast Cancer and its Link to DCE-MRI and Overall Survival, International Journal of Hyperthermia, 31, 386-395 (2015)
[26] Sibley, A. B.; Li, Z.; Jiang, Y.; Chan, C.; Allen, A.; Owzar, K., JSM Proceedings, Section on Statistical Education, Facilitating the Calculation of the Efficient Score Using Symbolic Computing,, 3136-3143 (2014), Alexandria, VA: American Statistical Association, Alexandria, VA
[27] Sorensen, D.; Gianola, D., Likelihood, Bayesian, and MCMC Methods in Quantitative Genetics (2013), New York: Springer-Verlag New York Inc, New York
[28] SymPy Development Team, Sympy: Python Library for Symbolic Mathematics, (2014)
[29] The Sage Developers, SageMath, the Sage Mathematics Software System, v7.6, (2017)
[30] Tsiatis, A. A., Semiparametric Theory and Missing Data (2006), New York: Springer Science+Business Media, LLC, New York · Zbl 1105.62002
[31] Wolfram Research, Inc., Mathematica v9.0 (2012), Champaign, IL: Wolfram Research, Inc, Champaign, IL
[32] Zhang, X.; Johnson, A. D.; Hendricks, A. E.; Hwang, S.-J.; Tanriverdi, K.; Ganesh, S. K.; Smith, N. L.; Peyser, P. A.; Freedman, J. E.; O’Donnell, C. J., Genetic Associations with Expression for Genes Implicated in GWAS Studies for Atherosclerotic Cardiovascular Disease and Blood Phenotypes, Human Molecular Genetics, 23, 782 (2014)
This reference list is based on information provided by the publisher or from digital mathematics libraries. Its items are heuristically matched to zbMATH identifiers and may contain data conversion errors. In some cases that data have been complemented/enhanced by data from zbMATH Open. This attempts to reflect the references listed in the original paper as accurately as possible without claiming completeness or a perfect matching.