Abstract
BackgroundComputational genomics of Alzheimer disease (AD), the most common form of senile dementia, is a nascent field in AD research. The field includes AD gene clustering by computing gene order which generates higher quality gene clustering patterns than most other clustering methods. However, there are few available gene order computing methods such as Genetic Algorithm (GA) and Ant Colony Optimization (ACO). Further, their performance in gene order computation using AD microarray data is not known. We thus set forth to evaluate the performances of current gene order computing methods with different distance formulas, and to identify additional features associated with gene order computation.MethodsUsing different distance formulas- Pearson distance and Euclidean distance, the squared Euclidean distance, and other conditions, gene orders were calculated by ACO and GA (including standard GA and improved GA) methods, respectively. The qualities of the gene orders were compared, and new features from the calculated gene orders were identified.ResultsCompared to the GA methods tested in this study, ACO fits the AD microarray data the best when calculating gene order. In addition, the following features were revealed: different distance formulas generated a different quality of gene order, and the commonly used Pearson distance was not the best distance formula when used with both GA and ACO methods for AD microarray data.ConclusionCompared with Pearson distance and Euclidean distance, the squared Euclidean distance generated the best quality gene order computed by GA and ACO methods.
Highlights
Introduction of genetic algorithmGenetic algorithm (GA) can be understood as an intelligent probabilistic search algorithm that works on Darwin’s principle of natural selection and that can be applied to a variety of combinatorial optimization problems [41]
We reported that Ant Colony Optimization (ACO) fits the Alzheimer disease (AD) microarray data the best when calculating gene order in comparison to the Genetic Algorithm (GA) methods tested in this study
From these figures and tables, we discovered that: (1) ACO was better suited than GA to calculate the gene order of the AD genes tested in this paper
Summary
Introduction of genetic algorithmGenetic algorithm (GA) can be understood as an intelligent probabilistic search algorithm that works on Darwin’s principle of natural selection and that can be applied to a variety of combinatorial optimization problems [41]. Each individual in the population is encoded into a string or chromosome that represents a possible solution to a given problem. Fit individuals or solutions have opportunities to reproduce by exchanging pieces of their genetic information, in a crossover procedure, with other highly fit individuals. This produces new “offspring” solutions (i.e., children), who share some characteristics taken from both parents [43]. There are few available gene order computing methods such as Genetic Algorithm (GA) and Ant Colony Optimization (ACO). Their performance in gene order computation using AD microarray data is not known. This study has laid the foundation for AD’s “amyloid hypothesis” which claims that the accumulation of Ab, as determined by its generation versus clearance in the brain, is the primary driver of AD-related pathogenesis, including neuronal cell death
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