Abstract
Analyses of multifactorial experimental designs are used as an explorative technique describing hypothesized multifactorial effects based on their variation. The procedure of analyzing multifactorial designs is well established for univariate data, and it is known as analysis of variance (ANOVA) tests, whereas only a few methods have been developed for multivariate data. In this work, we present the weighted-effect ASCA, named WE-ASCA, as an enhanced version of ANOVA-simultaneous component analysis (ASCA) to deal with multivariate data in unbalanced multifactorial designs. The core of our work is to use general linear models (GLMs) in decomposing the response matrix into a design matrix and a parameter matrix, while the main improvement in WE-ASCA is to implement the weighted-effect (WE) coding in the design matrix. This WE-coding introduces a unique solution to solve GLMs and satisfies a constrain in which the sum of all level effects of a categorical variable equal to zero. To assess the WE-ASCA performance, two applications were demonstrated using a biomedical Raman spectral data set consisting of mice colorectal tissue. The results revealed that WE-ASCA is ideally suitable for analyzing unbalanced designs. Furthermore, if WE-ASCA is applied as a preprocessing tool, the classification performance and its reproducibility can significantly improve.
Highlights
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.license.An essential part of statistical analysis is the extraction of informative features that describe a specific phenomenon based on a limited number of samples
Two applications of WE-ANOVA simultaneous component analysis (ASCA) are demonstrated based on an unbalanced multifactorial design of a Raman spectral data set comprising 387 colorectal tissue scans that were collected from 47 mice
The number of spectra within the levels of each factor is different; the introduced Weighted-effect ASCA (WE-ASCA) is ideal for analyzing this unbalanced design
Summary
An essential part of statistical analysis is the extraction of informative features that describe a specific phenomenon based on a limited number of samples. These samples are mostly collected by conducting either experiments or surveys [1,2]. The other type of sampling is to conduct an experiment that tests the effect of one, or more than one, treatment on selected individuals. This experimental approach is widely applied in the fields of the physical and life sciences
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