Multi-omics integration method based on attention deep learning network for biomedical data classification

•Proposed a novel end-to-end Multi-omics attention deep learning network (MOADLN) for biomedical data classification.•MOADLN jointly explores the correlation between patients in intra-omics and the correlation of cross-omics in the label space.•Construct the patient correlation via self-attention in...

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Published in:Computer methods and programs in biomedicine Vol. 231; p. 107377
Main Authors: Gong, Ping, Cheng, Lei, Zhang, Zhiyuan, Meng, Ao, Li, Enshuo, Chen, Jie, Zhang, Longzhen
Format: Journal Article
Language:English
Published: Ireland Elsevier B.V 01.04.2023
Subjects:
Algorithms
Attention mechanism
Biomedical data classification
Computational Biology - methods
Deep Learning
Humans
MicroRNAs
Multi-omics integration
Multiomics
Biomedical data classification
Deep learning
Attention mechanism
Multi-omics integration
ISSN:0169-2607, 1872-7565, 1872-7565
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Abstract •Proposed a novel end-to-end Multi-omics attention deep learning network (MOADLN) for biomedical data classification.•MOADLN jointly explores the correlation between patients in intra-omics and the correlation of cross-omics in the label space.•Construct the patient correlation via self-attention in the latent feature space for omics-specific feature learning. Integrating multi-omics data for the comprehensive analysis of the biological processes in human diseases has become one of the most challenging tasks of bioinformatics. Deep learning (DL) algorithms have recently become one of the most promising multi-omics data integration analysis methods. However, existing DL-based studies almost integrate the multi-omics data by concatenation in the input data space or the learned feature space, ignoring the correlations between patients and omics. We propose a novel multi-omics integration method, called Multi-omics Attention Deep Learning Network (MOADLN), which is used for biomedical data classification. Firstly, for each type of omics data, we use three fully-connected layers and the self-attention mechanism to reduce dimensionality, and construct the correlations between patients, respectively. Then, we apply the feature vector learned from self-attention to generate the initial category labels. Secondly, for the initial label predicted of each omics data, we use an effective Multi-Omics Correlation Discovery Network (MOCDN) to learn the cross-omic correlations in the label space. Finally, we use the softmax classifier for label prediction. We demonstrate that our method outperforms several state-of-the-art methods on two datasets with mRNA expression data, DNA methylation data, and miRNA expression data. In addition, we identified essential biomarkers of relevant diseases by MOADLN, and the generality of MOADLN is also demonstrated in the KIRP and KIRC datasets. MOADLN jointly explores correlations between patients in intra-omics and correlations of cross-omics in label space, which is an effective DL-based classification of biomedical data.
AbstractList •Proposed a novel end-to-end Multi-omics attention deep learning network (MOADLN) for biomedical data classification.•MOADLN jointly explores the correlation between patients in intra-omics and the correlation of cross-omics in the label space.•Construct the patient correlation via self-attention in the latent feature space for omics-specific feature learning. Integrating multi-omics data for the comprehensive analysis of the biological processes in human diseases has become one of the most challenging tasks of bioinformatics. Deep learning (DL) algorithms have recently become one of the most promising multi-omics data integration analysis methods. However, existing DL-based studies almost integrate the multi-omics data by concatenation in the input data space or the learned feature space, ignoring the correlations between patients and omics. We propose a novel multi-omics integration method, called Multi-omics Attention Deep Learning Network (MOADLN), which is used for biomedical data classification. Firstly, for each type of omics data, we use three fully-connected layers and the self-attention mechanism to reduce dimensionality, and construct the correlations between patients, respectively. Then, we apply the feature vector learned from self-attention to generate the initial category labels. Secondly, for the initial label predicted of each omics data, we use an effective Multi-Omics Correlation Discovery Network (MOCDN) to learn the cross-omic correlations in the label space. Finally, we use the softmax classifier for label prediction. We demonstrate that our method outperforms several state-of-the-art methods on two datasets with mRNA expression data, DNA methylation data, and miRNA expression data. In addition, we identified essential biomarkers of relevant diseases by MOADLN, and the generality of MOADLN is also demonstrated in the KIRP and KIRC datasets. MOADLN jointly explores correlations between patients in intra-omics and correlations of cross-omics in label space, which is an effective DL-based classification of biomedical data.
Integrating multi-omics data for the comprehensive analysis of the biological processes in human diseases has become one of the most challenging tasks of bioinformatics. Deep learning (DL) algorithms have recently become one of the most promising multi-omics data integration analysis methods. However, existing DL-based studies almost integrate the multi-omics data by concatenation in the input data space or the learned feature space, ignoring the correlations between patients and omics.BACKGROUND AND OBJECTIVEIntegrating multi-omics data for the comprehensive analysis of the biological processes in human diseases has become one of the most challenging tasks of bioinformatics. Deep learning (DL) algorithms have recently become one of the most promising multi-omics data integration analysis methods. However, existing DL-based studies almost integrate the multi-omics data by concatenation in the input data space or the learned feature space, ignoring the correlations between patients and omics.We propose a novel multi-omics integration method, called Multi-omics Attention Deep Learning Network (MOADLN), which is used for biomedical data classification. Firstly, for each type of omics data, we use three fully-connected layers and the self-attention mechanism to reduce dimensionality, and construct the correlations between patients, respectively. Then, we apply the feature vector learned from self-attention to generate the initial category labels. Secondly, for the initial label predicted of each omics data, we use an effective Multi-Omics Correlation Discovery Network (MOCDN) to learn the cross-omic correlations in the label space. Finally, we use the softmax classifier for label prediction.METHODSWe propose a novel multi-omics integration method, called Multi-omics Attention Deep Learning Network (MOADLN), which is used for biomedical data classification. Firstly, for each type of omics data, we use three fully-connected layers and the self-attention mechanism to reduce dimensionality, and construct the correlations between patients, respectively. Then, we apply the feature vector learned from self-attention to generate the initial category labels. Secondly, for the initial label predicted of each omics data, we use an effective Multi-Omics Correlation Discovery Network (MOCDN) to learn the cross-omic correlations in the label space. Finally, we use the softmax classifier for label prediction.We demonstrate that our method outperforms several state-of-the-art methods on two datasets with mRNA expression data, DNA methylation data, and miRNA expression data. In addition, we identified essential biomarkers of relevant diseases by MOADLN, and the generality of MOADLN is also demonstrated in the KIRP and KIRC datasets.RESULTSWe demonstrate that our method outperforms several state-of-the-art methods on two datasets with mRNA expression data, DNA methylation data, and miRNA expression data. In addition, we identified essential biomarkers of relevant diseases by MOADLN, and the generality of MOADLN is also demonstrated in the KIRP and KIRC datasets.MOADLN jointly explores correlations between patients in intra-omics and correlations of cross-omics in label space, which is an effective DL-based classification of biomedical data.CONCLUSIONSMOADLN jointly explores correlations between patients in intra-omics and correlations of cross-omics in label space, which is an effective DL-based classification of biomedical data.
Integrating multi-omics data for the comprehensive analysis of the biological processes in human diseases has become one of the most challenging tasks of bioinformatics. Deep learning (DL) algorithms have recently become one of the most promising multi-omics data integration analysis methods. However, existing DL-based studies almost integrate the multi-omics data by concatenation in the input data space or the learned feature space, ignoring the correlations between patients and omics. We propose a novel multi-omics integration method, called Multi-omics Attention Deep Learning Network (MOADLN), which is used for biomedical data classification. Firstly, for each type of omics data, we use three fully-connected layers and the self-attention mechanism to reduce dimensionality, and construct the correlations between patients, respectively. Then, we apply the feature vector learned from self-attention to generate the initial category labels. Secondly, for the initial label predicted of each omics data, we use an effective Multi-Omics Correlation Discovery Network (MOCDN) to learn the cross-omic correlations in the label space. Finally, we use the softmax classifier for label prediction. We demonstrate that our method outperforms several state-of-the-art methods on two datasets with mRNA expression data, DNA methylation data, and miRNA expression data. In addition, we identified essential biomarkers of relevant diseases by MOADLN, and the generality of MOADLN is also demonstrated in the KIRP and KIRC datasets. MOADLN jointly explores correlations between patients in intra-omics and correlations of cross-omics in label space, which is an effective DL-based classification of biomedical data.
ArticleNumber 107377
Author Zhang, Zhiyuan
Li, Enshuo
Meng, Ao
Cheng, Lei
Gong, Ping
Zhang, Longzhen
Chen, Jie
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  surname: Zhang
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  organization: Department of Radiation Oncology, Affiliated Hospital of Xuzhou Medical University, Xuzhou, CN, China
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Keywords Biomedical data classification
Deep learning
Attention mechanism
Multi-omics integration
Language English
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Snippet •Proposed a novel end-to-end Multi-omics attention deep learning network (MOADLN) for biomedical data classification.•MOADLN jointly explores the correlation...
Integrating multi-omics data for the comprehensive analysis of the biological processes in human diseases has become one of the most challenging tasks of...
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StartPage 107377
SubjectTerms Algorithms
Attention mechanism
Biomedical data classification
Computational Biology - methods
Deep Learning
Humans
MicroRNAs
Multi-omics integration
Multiomics
Title Multi-omics integration method based on attention deep learning network for biomedical data classification
URI https://www.clinicalkey.com/#!/content/1-s2.0-S0169260723000445
https://dx.doi.org/10.1016/j.cmpb.2023.107377
https://www.ncbi.nlm.nih.gov/pubmed/36739624
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