Human-Computer Interaction in a Computational Evolution System for the Genetic Analysis of Cancer
Created by W.Langdon from
gp-bibliography.bib Revision:1.8120
- @InCollection{Moore:2011:GPTP,
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author = "Jason H. Moore and Douglas P. Hill and
Jonathan M. Fisher and Nicole Lavender and La Creis Kidd",
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title = "Human-Computer Interaction in a Computational
Evolution System for the Genetic Analysis of Cancer",
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booktitle = "Genetic Programming Theory and Practice IX",
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year = "2011",
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editor = "Rick Riolo and Ekaterina Vladislavleva and
Jason H. Moore",
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series = "Genetic and Evolutionary Computation",
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address = "Ann Arbor, USA",
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month = "12-14 " # may,
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publisher = "Springer",
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chapter = "9",
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pages = "153--171",
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keywords = "genetic algorithms, genetic programming, Computational
Evolution, Genetic Epidemiology, epistasis, Prostate
Cancer, Visualisation",
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isbn13 = "978-1-4614-1769-9",
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DOI = "doi:10.1007/978-1-4614-1770-5_9",
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abstract = "The paradigm of identifying genetic risk factors for
common human diseases by analysing one DNA sequence
variation at a time is quickly being replaced by
research strategies that embrace the multivariate
complexity of the genotype to phenotype mapping
relationship that is likely due, in part, to nonlinear
interactions among many genetic and environmental
factors. Embracing the complexity of common diseases
such as cancer requires powerful computational methods
that are able to model nonlinear interactions in
high-dimensional genetic data. Previously, we have
addressed this challenge with the development of a
computational evolution system (CES) that incorporates
greater biological realism than traditional artificial
evolution methods, such as genetic programming. Our
results have demonstrated that CES is capable of
efficiently navigating these large and rugged fitness
landscapes toward the discovery of biologically
meaningful genetic models of disease predisposition.
Further, we have shown that the efficacy of CES is
improved dramatically when the system is provided with
statistical expert knowledge, derived from a family of
machine learning techniques known as Relief, or
biological expert knowledge, derived from sources such
as protein-protein interaction databases. The goal of
the present study was to apply CES to the genetic
analysis of prostate cancer aggressiveness in a large
sample of European Americans. We introduce here the use
of 3D visualization methods to identify interesting
patterns in CES results. Information extracted from the
visualization through human-computer interaction are
then provide as expert knowledge to new CES runs in a
cascading framework. We present a CES-derived
multivariate classifier and provide a statistical and
biological interpretation in the context of prostate
cancer prediction. The incorporation of human-computer
interaction into CES provides a first step towards an
interactive discovery system where the experts can be
embedded in the computational discovery process. Our
working hypothesis is that this type of human-computer
interaction will provide more useful results for
complex problem solving than the traditional black box
machine learning approach.",
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notes = "part of \cite{Riolo:2011:GPTP}",
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affiliation = "Dartmouth Medical School, One Medical Center Drive,
HB7937, Lebanon, NH 03756, USA",
- }
Genetic Programming entries for
Jason H Moore
Douglas P Hill
Jonathan M Fisher
Nicole A Lavender
La Creis Renee Kidd
Citations