Abstract

IntroductionMetabolomics data is commonly modelled multivariately using partial least squares discriminant analysis (PLS-DA). Its success is primarily due to ease of interpretation, through projection to latent structures, and transparent assessment of feature importance using regression coefficients and Variable Importance in Projection scores. In recent years several non-linear machine learning (ML) methods have grown in popularity but with limited uptake essentially due to convoluted optimisation and interpretation. Artificial neural networks (ANNs) are a non-linear projection-based ML method that share a structural equivalence with PLS, and as such should be amenable to equivalent optimisation and interpretation methods.ObjectivesWe hypothesise that standardised optimisation, visualisation, evaluation and statistical inference techniques commonly used by metabolomics researchers for PLS-DA can be migrated to a non-linear, single hidden layer, ANN.MethodsWe compared a standardised optimisation, visualisation, evaluation and statistical inference techniques workflow for PLS with the proposed ANN workflow. Both workflows were implemented in the Python programming language. All code and results have been made publicly available as Jupyter notebooks on GitHub.ResultsThe migration of the PLS workflow to a non-linear, single hidden layer, ANN was successful. There was a similarity in significant metabolites determined using PLS model coefficients and ANN Connection Weight Approach.ConclusionWe have shown that it is possible to migrate the standardised PLS-DA workflow to simple non-linear ANNs. This result opens the door for more widespread use and to the investigation of transparent interpretation of more complex ANN architectures.

Highlights

  • Metabolomics data is commonly modelled multivariately using partial least squares discriminant analysis (PLSDA)

  • We recently showed that Artificial neural networks (ANNs) have similar predictive ability to PLS across multiple diverse metabolomics data sets (Mendez et al 2019c)

  • We include the application of the identical workflows and visualisation techniques to a second previously published dataset (Ganna et al 2016) as a supplementary document

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Summary

Introduction

Metabolomics data is commonly modelled multivariately using partial least squares discriminant analysis (PLSDA). Objectives We hypothesise that standardised optimisation, visualisation, evaluation and statistical inference techniques commonly used by metabolomics researchers for PLS-DA can be migrated to a non-linear, single hidden layer, ANN. Methods We compared a standardised optimisation, visualisation, evaluation and statistical inference techniques workflow for PLS with the proposed ANN workflow. Both workflows were implemented in the Python programming language. Partial least squares (PLS), a.k.a. projection to latent structures (Wold 1975; Wold et al 1993), has been the standard multivariate machine learning (ML) method used to construct predictive models to classify metabolite profiles. The ability for PLS to visualise and infer statistical confidence intervals upon the latent relationships within and between sample classes, together with the fact that a PLS model can be reduced to a simple linear regression (and exposed to multiple well established post-hoc statistical tests), means that it sits alone as an effective hybrid prediction-inference algorithm for high dimensional data (Eriksson et al 2013; Wold 1975; Wold et al 1993)

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