Tilting the Lasso by Knowledge-Based Post-Processing

K Tharmaratnam; M Sperrin; T Jaki; S Reppe; A. Frigessi

doi:10.1186/s12859-016-1210-7

Tilting the Lasso by Knowledge-Based Post-Processing

K Tharmaratnam, M Sperrin, T Jaki, S Reppe, A. Frigessi

Research output: Contribution to journal › Article › peer-review

Abstract

It is useful to incorporate biological knowledge on the role of genetic determinants in predicting an outcome. It is, however, not always feasible to fully elicit this information when the number of determinants is large. We present an approach to overcome this difficulty. First, using half of the available data, a shortlist of potentially interesting determinants are generated. Second, binary indications of biological importance are elicited for this much smaller number of determinants. Third, an analysis is carried out on this shortlist using the second half of the data.

Results
We show through simulations that, compared with adaptive lasso, this approach leads to models containing more biologically relevant variables, while the prediction mean squared error (PMSE) is comparable or even reduced. We also apply our approach to bone mineral density data, and again final models contain more biologically relevant variables and have reduced PMSEs.

Conclusion
Our method leads to comparable or improved predictive performance, and models with greater face validity and interpretability with feasible incorporation of biological knowledge into predictive models.

Original language	English
Journal	B M C Bioinformatics
DOIs	https://doi.org/10.1186/s12859-016-1210-7
Publication status	Published - 2 Sept 2016

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10.1186/s12859-016-1210-7Licence: CC BY

Tilting the lasso by knowledge-based post-processing
Tharmaratnam, K. (Contributor), Sperrin, M. (Contributor), Jaki, T. (Contributor), Reppe, S. (Contributor) & Frigessi, A. (Contributor), figshare , 2 Sept 2016
DOI: 10.6084/m9.figshare.c.3626198.v1, https://figshare.com/collections/Tilting_the_lasso_by_knowledge-based_post-processing/3626198/1
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title = "Tilting the Lasso by Knowledge-Based Post-Processing",

abstract = "It is useful to incorporate biological knowledge on the role of genetic determinants in predicting an outcome. It is, however, not always feasible to fully elicit this information when the number of determinants is large. We present an approach to overcome this difficulty. First, using half of the available data, a shortlist of potentially interesting determinants are generated. Second, binary indications of biological importance are elicited for this much smaller number of determinants. Third, an analysis is carried out on this shortlist using the second half of the data.ResultsWe show through simulations that, compared with adaptive lasso, this approach leads to models containing more biologically relevant variables, while the prediction mean squared error (PMSE) is comparable or even reduced. We also apply our approach to bone mineral density data, and again final models contain more biologically relevant variables and have reduced PMSEs.ConclusionOur method leads to comparable or improved predictive performance, and models with greater face validity and interpretability with feasible incorporation of biological knowledge into predictive models.",

author = "K Tharmaratnam and M Sperrin and T Jaki and S Reppe and A. Frigessi",

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AU - Tharmaratnam, K

AU - Sperrin, M

AU - Jaki, T

AU - Reppe, S

AU - Frigessi, A.

PY - 2016/9/2

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N2 - It is useful to incorporate biological knowledge on the role of genetic determinants in predicting an outcome. It is, however, not always feasible to fully elicit this information when the number of determinants is large. We present an approach to overcome this difficulty. First, using half of the available data, a shortlist of potentially interesting determinants are generated. Second, binary indications of biological importance are elicited for this much smaller number of determinants. Third, an analysis is carried out on this shortlist using the second half of the data.ResultsWe show through simulations that, compared with adaptive lasso, this approach leads to models containing more biologically relevant variables, while the prediction mean squared error (PMSE) is comparable or even reduced. We also apply our approach to bone mineral density data, and again final models contain more biologically relevant variables and have reduced PMSEs.ConclusionOur method leads to comparable or improved predictive performance, and models with greater face validity and interpretability with feasible incorporation of biological knowledge into predictive models.

AB - It is useful to incorporate biological knowledge on the role of genetic determinants in predicting an outcome. It is, however, not always feasible to fully elicit this information when the number of determinants is large. We present an approach to overcome this difficulty. First, using half of the available data, a shortlist of potentially interesting determinants are generated. Second, binary indications of biological importance are elicited for this much smaller number of determinants. Third, an analysis is carried out on this shortlist using the second half of the data.ResultsWe show through simulations that, compared with adaptive lasso, this approach leads to models containing more biologically relevant variables, while the prediction mean squared error (PMSE) is comparable or even reduced. We also apply our approach to bone mineral density data, and again final models contain more biologically relevant variables and have reduced PMSEs.ConclusionOur method leads to comparable or improved predictive performance, and models with greater face validity and interpretability with feasible incorporation of biological knowledge into predictive models.

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Tilting the Lasso by Knowledge-Based Post-Processing

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Tilting the lasso by knowledge-based post-processing

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