Jiaojiao Guan scite author profile

Identifying genes associated with Parkinson's disease plays an extremely important role in the diagnosis and treatment of Parkinson's disease. In recent years, based on the guilt-by-association hypothesis, many methods have been proposed to predict disease-related genes, but few of these methods are designed or used for Parkinson's disease gene prediction. In this paper, we propose a novel prediction method for Parkinson's disease gene prediction, named N2A-SVM. N2A-SVM includes three parts: extracting features of genes based on network, reducing the dimension using deep neural network, and predicting Parkinson's disease genes using a machine learning method. The evaluation test shows that N2A-SVM performs better than existing methods. Furthermore, we evaluate the significance of each step in the N2A-SVM algorithm and the influence of the hyper-parameters on the result. In addition, we train N2A-SVM on the recent dataset and used it to predict Parkinson's disease genes. The predicted top-rank genes can be verified based on literature study.

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An end-to-end heterogeneous graph representation learning-based framework for drug–target interaction prediction

Peng

Wang

Guan

et al. 2021

124

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Accurately identifying potential drug–target interactions (DTIs) is a key step in drug discovery. Although many related experimental studies have been carried out for identifying DTIs in the past few decades, the biological experiment-based DTI identification is still timeconsuming and expensive. Therefore, it is of great significance to develop effective computational methods for identifying DTIs. In this paper, we develop a novel ‘end-to-end’ learning-based framework based on heterogeneous ‘graph’ convolutional networks for ‘DTI’ prediction called end-to-end graph (EEG)-DTI. Given a heterogeneous network containing multiple types of biological entities (i.e. drug, protein, disease, side-effect), EEG-DTI learns the low-dimensional feature representation of drugs and targets using a graph convolutional networks-based model and predicts DTIs based on the learned features. During the training process, EEG-DTI learns the feature representation of nodes in an end-to-end mode. The evaluation test shows that EEG-DTI performs better than existing state-of-art methods. The data and source code are available at: https://github.com/MedicineBiology-AI/EEG-DTI.

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Semisupervised Classification of PolSAR Image Incorporating Labels’ Semantic Priors

Hou

Guan

et al. 2020

IEEE Geosci. Remote Sensing Lett.

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A novel subnetwork representation learning method for uncovering disease-disease relationships

Peng

Guan

Hui

et al. 2021

Methods

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Jiaojiao Guan

Predicting Parkinson's Disease Genes Based on Node2vec and Autoencoder

An end-to-end heterogeneous graph representation learning-based framework for drug–target interaction prediction

Semisupervised Classification of PolSAR Image Incorporating Labels’ Semantic Priors

A novel subnetwork representation learning method for uncovering disease-disease relationships

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