Identification of disease-distinct complex biomarker patterns by means of unsupervised machine-learning using an interactive R toolbox (Umatrix)

Lötsch, Jörn; Lerch, F. Javier; Djaldetti, Ruth; Tegder, Irmgard; Ultsch, Alfred

doi:10.1186/s41044-018-0032-1

Cited by 26 publications

(46 citation statements)

References 58 publications

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“…Valleys indicate clusters of functionally similar genes based on the significant GO term annotations. The figure was created using the R software package (version 3.3.2 for Linux; http://CRAN.R-project.org/; R Development Core Team, ) using our R library ‘Umatrix’ ( https://cran.r-project.org/package=Umatrix; Lötsch et al., ).…”

Section: Resultsmentioning

confidence: 99%

“…The ‘map’ was further enhanced by calculating a so‐called P‐matrix (Ultsch, ), which displays the probability of a data point as

p false(x false) = ∣ {data points x_{i} ∣ d false(x_{i}, x false) < = r} ∣

estimated as the number of data points in a sphere with radius r around x at each grid point on the ESOM's output grid. The calculations were performed using our R library ‘Umatrix’ (https://cran.r-project.org/package=Umatrix; Lötsch et al., ).…”

Section: Methodsmentioning

confidence: 99%

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A machine‐learned analysis of human gene polymorphisms modulating persisting pain points to major roles of neuroimmune processes

Kringel

Lippmann

Parnham

et al. 2018

European Journal of Pain

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BackgroundHuman genetic research has implicated functional variants of more than one hundred genes in the modulation of persisting pain. Artificial intelligence and machine‐learning techniques may combine this knowledge with results of genetic research gathered in any context, which permits the identification of the key biological processes involved in chronic sensitization to pain.MethodsBased on published evidence, a set of 110 genes carrying variants reported to be associated with modulation of the clinical phenotype of persisting pain in eight different clinical settings was submitted to unsupervised machine‐learning aimed at functional clustering. Subsequently, a mathematically supported subset of genes, comprising those most consistently involved in persisting pain, was analysed by means of computational functional genomics in the Gene Ontology knowledgebase.ResultsClustering of genes with evidence for a modulation of persisting pain elucidated a functionally heterogeneous set. The situation cleared when the focus was narrowed to a genetic modulation consistently observed throughout several clinical settings. On this basis, two groups of biological processes, the immune system and nitric oxide signalling, emerged as major players in sensitization to persisting pain, which is biologically highly plausible and in agreement with other lines of pain research.ConclusionsThe present computational functional genomics‐based approach provided a computational systems‐biology perspective on chronic sensitization to pain. Human genetic control of persisting pain points to the immune system as a source of potential future targets for drugs directed against persisting pain. Contemporary machine‐learned methods provide innovative approaches to knowledge discovery from previous evidence.SignificanceWe show that knowledge discovery in genetic databases and contemporary machine‐learned techniques can identify relevant biological processes involved in Persitent pain.

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Section: Resultsmentioning

confidence: 99%

“…The ‘map’ was further enhanced by calculating a so‐called P‐matrix (Ultsch, ), which displays the probability of a data point as

p false(x false) = ∣ {data points x_{i} ∣ d false(x_{i}, x false) < = r} ∣

Section: Methodsmentioning

confidence: 99%

A machine‐learned analysis of human gene polymorphisms modulating persisting pain points to major roles of neuroimmune processes

Kringel

Lippmann

Parnham

et al. 2018

European Journal of Pain

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“…When analyzing the same data using emergent self-organizing feature maps (ESOM), projecting the data on a grid of thousands of artificial neurons [7] and combining it with U-matrix methods [4,5], it was correctly concluded that there is no group structure in these data. As shown in the lower-left panel of Figure 1, the U-matrix consists of a random structure without subgroups.…”

Section: Results Of T-sne Analysis In Artificial Data Setsmentioning

confidence: 99%

“…Results of an alternative projection and subgroup detection technique, implemented as ESOM/U-matrix, which clearly indicate the absence of any systematic data structures, are shown at lower-left panel. The figure has been created based on the t-SNE analysis implemented in the R library "tsne" [3] and the U-matrix was obtained using the R library "Umatrix" [4].…”

Section: Introductionmentioning

confidence: 99%

“…With an emphasis on t-SNE as a data projection technique that appears to be becoming a standard in flow cytometry, this paper, therefore, aims to evaluate the results of this technique when applied on several different artificial or biomedical data sets. To demonstrate that data analysis is not limited to a single method that is occasionally delivered with the laboratory device, an alternative approach has been used in parallel to t-SNE, consisting of emergent self-organizing feature maps (ESOM) that have been shown to reliably detect structures in artificial and biomedical data sets [4,5]. The following report will identify potential pitfalls in the use of t-SNE for the analysis of data in molecular research and provide some technical background to these shortcomings; however, it cannot substitute the fundamentals of data science and tuning of analytical methods, which requires further reading presented in a broader context such as [6].…”

Section: Introductionmentioning

confidence: 99%

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Current Projection Methods-Induced Biases at Subgroup Detection for Machine-Learning Based Data-Analysis of Biomedical Data

Lötsch

Ultsch

2019

IJMS

Self Cite

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Advances in flow cytometry enable the acquisition of large and high-dimensional data sets per patient. Novel computational techniques allow the visualization of structures in these data and, finally, the identification of relevant subgroups. Correct data visualizations and projections from the high-dimensional space to the visualization plane require the correct representation of the structures in the data. This work shows that frequently used techniques are unreliable in this respect. One of the most important methods for data projection in this area is the t-distributed stochastic neighbor embedding (t-SNE). We analyzed its performance on artificial and real biomedical data sets. t-SNE introduced a cluster structure for homogeneously distributed data that did not contain any subgroup structure. In other data sets, t-SNE occasionally suggested the wrong number of subgroups or projected data points belonging to different subgroups, as if belonging to the same subgroup. As an alternative approach, emergent self-organizing maps (ESOM) were used in combination with U-matrix methods. This approach allowed the correct identification of homogeneous data while in sets containing distance or density-based subgroups structures; the number of subgroups and data point assignments were correctly displayed. The results highlight possible pitfalls in the use of a currently widely applied algorithmic technique for the detection of subgroups in high dimensional cytometric data and suggest a robust alternative.

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Unsupervised Learning in Accordance With New Aspects of Artificial Intelligence

Sharma

Saxena

Rana

2021

Machine Learning Approach for Cloud Data Analytics in IoT

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Identification of disease-distinct complex biomarker patterns by means of unsupervised machine-learning using an interactive R toolbox (Umatrix)

Cited by 26 publications

References 58 publications

A machine‐learned analysis of human gene polymorphisms modulating persisting pain points to major roles of neuroimmune processes

A machine‐learned analysis of human gene polymorphisms modulating persisting pain points to major roles of neuroimmune processes

Current Projection Methods-Induced Biases at Subgroup Detection for Machine-Learning Based Data-Analysis of Biomedical Data

Unsupervised Learning in Accordance With New Aspects of Artificial Intelligence

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