Net-Net AutoML Selection of Artificial Neural Network Topology for Brain Connectome Prediction

Brain Connectome Networks (BCNs) are defined by brain cortex regions (nodes) interacting with others by electrophysiological co-activation (edges). The experimental prediction of new interactions in BCNs represents a difficult task due to the large number of edges and the complex connectivity patter...

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Bibliographic Details
Published in:Applied sciences 2020-02, Vol.10 (4), p.1308
Main Authors: Barreiro, Enrique, Munteanu, Cristian R., Gestal, Marcos, Rabuñal, Juan Ramón, Pazos, Alejandro, González-Díaz, Humberto, Dorado, Julián
Format: Article
Language:English
Subjects:
Algorithms
artificial neural networks
Brain
brain connectome networks
Complex systems
Datasets
Entropy
Experiments
Expert systems
Learning algorithms
Learning theory
Machine learning
net-net automl
Network topologies
Neural networks
Nodes
Predictions
Proteins
Topology
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Summary:Brain Connectome Networks (BCNs) are defined by brain cortex regions (nodes) interacting with others by electrophysiological co-activation (edges). The experimental prediction of new interactions in BCNs represents a difficult task due to the large number of edges and the complex connectivity patterns. Fortunately, we can use another special type of networks to achieve this goal—Artificial Neural Networks (ANNs). Thus, ANNs could use node descriptors such as Shannon Entropies (Sh) to predict node connectivity for large datasets including complex systems such as BCN. However, the training of a high number of ANNs for BCNs is a time-consuming task. In this work, we propose the use of a method to automatically determine which ANN topology is more efficient for the BCN prediction. Since a network (ANN) is used to predict the connectivity in another network (BCN), this method was entitled Net-Net AutoML. The algorithm uses Sh descriptors for pairs of nodes in BCNs and for ANN predictors of BCNs. Therefore, it is able to predict the efficiency of new ANN topologies to predict BCNs. The current study used a set of 500,470 examples from 10 different ANNs to predict node connectivity in BCNs and 20 features. After testing five Machine Learning classifiers, the best classification model to predict the ability of an ANN to evaluate node interactions in BCNs was provided by Random Forest (mean test AUROC of 0.9991 ± 0.0001, 10-fold cross-validation). Net-Net AutoML algorithms based on entropy descriptors may become a useful tool in the design of automatic expert systems to select ANN topologies for complex biological systems. The scripts and dataset for this project are available in an open GitHub repository.
ISSN:2076-3417
2076-3417
DOI:10.3390/app10041308