Computational prediction of inter-species relationships through omics data analysis and machine learning

Leite, Diogo Manuel Carvalho; Brochet, Xavier; Resch, Grégory; Que, Yok-Ai; Neves, Aitana; Peña-Reyes, Carlos Andrés

doi:10.1186/s12859-018-2388-7

Cited by 51 publications

(50 citation statements)

References 39 publications

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“…It was seen previously that SVM sometimes fails when it is intended for distinguishing fine biomedical properties such as disease progression prognosis or assessment of clinical efficiency of drugs for an individual patient, using high throughput molecular data, e.g., complete DNA mutation or gene expression profiles (Ray and Zhang, 2009; Babaoglu et al, 2010). Particularly, for many biologically relevant applications, SVM occurred either fully incapable to predict drug sensitivity (Turki and Wei, 2016), or demonstrated poorer performance than competing method for machine learning (Davoudi et al, 2017; Cho et al, 2018; Jeong et al, 2018; Leite et al, 2018; Sauer et al, 2018; Yosipof et al, 2018). Thus, the tool for improvement of SVM performance is certainly needed.…”

Section: Discussionmentioning

confidence: 99%

FLOating-Window Projective Separator (FloWPS): A Data Trimming Tool for Support Vector Machines (SVM) to Improve Robustness of the Classifier

Tkachev¹,

Sorokin²,

Mescheryakov

et al. 2019

Front. Genet.

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Here, we propose a heuristic technique of data trimming for SVM termed FLOating Window Projective Separator (FloWPS), tailored for personalized predictions based on molecular data. This procedure can operate with high throughput genetic datasets like gene expression or mutation profiles. Its application prevents SVM from extrapolation by excluding non-informative features. FloWPS requires training on the data for the individuals with known clinical outcomes to create a clinically relevant classifier. The genetic profiles linked with the outcomes are broken as usual into the training and validation datasets. The unique property of FloWPS is that irrelevant features in validation dataset that don’t have significant number of neighboring hits in the training dataset are removed from further analyses. Next, similarly to the k nearest neighbors (kNN) method, for each point of a validation dataset, FloWPS takes into account only the proximal points of the training dataset. Thus, for every point of a validation dataset, the training dataset is adjusted to form a floating window. FloWPS performance was tested on ten gene expression datasets for 992 cancer patients either responding or not on the different types of chemotherapy. We experimentally confirmed by leave-one-out cross-validation that FloWPS enables to significantly increase quality of a classifier built based on the classical SVM in most of the applications, particularly for polynomial kernels.

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Section: Discussionmentioning

confidence: 99%

FLOating-Window Projective Separator (FloWPS): A Data Trimming Tool for Support Vector Machines (SVM) to Improve Robustness of the Classifier

Tkachev¹,

Sorokin²,

Mescheryakov

et al. 2019

Front. Genet.

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“…For example, it is used for the prediction of various chemical and biological properties from chemical structures (e.g. [5][6][7]). Classical multivariate statistics and machine learning approaches include logistic regression, support vector machines, decision trees and Bayesian networks.…”

Section: Introductionmentioning

confidence: 99%

Learning Chemistry: Exploring the Suitability of Machine Learning for the Task of Structure-based Chemical Ontology Classification

Hastings

Glauer

Memariani

et al. 2020

Preprint

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Chemical data is increasingly openly available in databases such as PubChem, which contains more than 110 million compound entries as of October 2020. With the availability of data at such scale, the burden has shifted to organisation, analysis and interpretation. Chemical ontologies provide structured classifications of chemical entities that can be used for navigation and filtering of the large chemical space. ChEBI is a prominent example of a chemical ontology, widely used in life science contexts. However, ChEBI is manually maintained and as such cannot easily scale to the full scope of public chemical data. There is a need for tools that are able to automatically classify chemical data into chemical ontologies, which can be framed as a hierarchical multi-class classification problem. In this paper we evaluate machine learning approaches for this task, comparing different learning frameworks including logistic regression, decision trees and long short-term memory articial neural networks, and different encoding approaches for the chemical structures, including cheminformatics fingerprints and character-based encoding from chemical line notation representations. We nd that classical learning approaches such as logistic regression perform well with sets of relatively specific, disjoint chemical classes, while the neural network is able to handle larger sets of overlapping classes but needs more examples per class to learn from, and is not able to make a class prediction for every molecule. Future work will explore hybrid and ensemble approaches, as well as alternative network architectures including neuro-symbolic approaches.

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“…The use of phages could also enable to combat current unculturable bacteria, on the condition that they can easily be identified through genomic approach. It has been suggested that machine learning approaches can be utilized to either identify, or generate through synthetic genomics, based on the genomic information provided on the bacterial target ( Leite et al, 2018 ; Martorell-Marugán et al, 2019 ; Baláž et al, 2020 ; Pirnay, 2020 ).…”

Section: Discussionmentioning

confidence: 99%

The Rationale for Using Bacteriophage to Treat and Prevent Periprosthetic Joint Infections

et al. 2020

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Prosthetic joint infection (PJI) is a devastating complication after a joint replacement. PJI and its treatment have a high monetary cost, morbidity, and mortality. The lack of success treating PJI with conventional antibiotics alone is related to the presence of bacterial biofilm on medical implants. Consequently, surgical removal of the implant and prolonged intravenous antibiotics to eradicate the infection are necessary prior to re-implanting a new prosthetic joint. Growing clinical data shows that bacterial predators, called bacteriophages (phages), could be an alternative treatment strategy or prophylactic approach for PJI. Phages could further be exploited to degrade biofilms, making bacteria more susceptible to antibiotics and enabling potential combinatorial therapies. Emerging research suggests that phages may also directly interact with the innate immune response. Phage therapy may play an important, and currently understudied, role in the clearance of PJI, and has the potential to treat thousands of patients who would either have to undergo revision surgery to attempt to clear an infections, take antibiotics for a prolonged period to try and suppress the re-emerging infection, or potentially risk losing a limb.

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Computational prediction of inter-species relationships through omics data analysis and machine learning

Cited by 51 publications

References 39 publications

FLOating-Window Projective Separator (FloWPS): A Data Trimming Tool for Support Vector Machines (SVM) to Improve Robustness of the Classifier

FLOating-Window Projective Separator (FloWPS): A Data Trimming Tool for Support Vector Machines (SVM) to Improve Robustness of the Classifier

Learning Chemistry: Exploring the Suitability of Machine Learning for the Task of Structure-based Chemical Ontology Classification

The Rationale for Using Bacteriophage to Treat and Prevent Periprosthetic Joint Infections

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