Sparse deep neural network for encoding and decoding the structural connectome
Brain state classification by applying deep learning techniques on neuroimaging data has become a recent topic of research. However, unlike domains where the data is low dimensional or there are large number of available training samples, neuroimaging data is high dimensional and has few training sa...
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sg-ntu-dr.10356-1757592024-05-10T15:38:31Z Sparse deep neural network for encoding and decoding the structural connectome Singh, Satya P. Gupta, Sukrit Rajapakse, Jagath Chandana School of Computer Science and Engineering Computer and Information Science Alzheimer's disease Brain decoding Brain state classification by applying deep learning techniques on neuroimaging data has become a recent topic of research. However, unlike domains where the data is low dimensional or there are large number of available training samples, neuroimaging data is high dimensional and has few training samples. To tackle these issues, we present a sparse feedforward deep neural architecture for encoding and decoding the structural connectome of the human brain. We use a sparsely connected element-wise multiplication as the first hidden layer and a fixed transform layer as the output layer. The number of trainable parameters and the training time is significantly reduced compared to feedforward networks. We demonstrate superior performance of this architecture in encoding the structural connectome implicated in Alzheimer's disease (AD) and Parkinson's disease (PD) from DTI brain scans. For decoding, we propose recursive feature elimination (RFE) algorithm based on DeepLIFT, layer-wise relevance propagation (LRP), and Integrated Gradients (IG) algorithms to remove irrelevant features and thereby identify key biomarkers associated with AD and PD. We show that the proposed architecture reduces 45.1% and 47.1% of the trainable parameters compared to a feedforward DNN with an increase in accuracy by 2.6 % and 3.1% for cognitively normal (CN) vs AD and CN vs PD classification, respectively. We also show that the proposed RFE method leads to a further increase in accuracy by 2.1% and 4% for CN vs AD and CN vs PD classification, while removing approximately 90% to 95% irrelevant features. Furthermore, we argue that the biomarkers (i.e., key brain regions and connections) identified are consistent with previous literature. We show that relevancy score-based methods can yield high discriminative power and are suitable for brain decoding. We also show that the proposed approach led to a reduction in the number of trainable network parameters, an increase in classification accuracy, and a detection of brain connections and regions that were consistent with earlier studies. Ministry of Education (MOE) Published version This work was supported by AcRF Tier-2 of Ministry of Education, Singapore, under Grant MOE T2EP20121-0003. The data collection and sharing for this project was funded by the Alzheimer’s Disease Neuroimaging Initiative (ADNI) (a detailed acknowledgment is found in the Supplementary Material). 2024-05-06T05:24:14Z 2024-05-06T05:24:14Z 2024 Journal Article Singh, S. P., Gupta, S. & Rajapakse, J. C. (2024). Sparse deep neural network for encoding and decoding the structural connectome. IEEE Journal of Translational Engineering in Health and Medicine, 12, 371-381. https://dx.doi.org/10.1109/JTEHM.2024.3366504 2168-2372 https://hdl.handle.net/10356/175759 10.1109/JTEHM.2024.3366504 38633564 2-s2.0-85186106033 12 371 381 en MOE T2EP20121-0003 IEEE Journal of Translational Engineering in Health and Medicine © 2024 The Authors. This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License. For more information, see https://creativecommons.org/licenses/by-nc-nd/4.0/. application/pdf |
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Computer and Information Science Alzheimer's disease Brain decoding Singh, Satya P. Gupta, Sukrit Rajapakse, Jagath Chandana Sparse deep neural network for encoding and decoding the structural connectome |
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Brain state classification by applying deep learning techniques on neuroimaging data has become a recent topic of research. However, unlike domains where the data is low dimensional or there are large number of available training samples, neuroimaging data is high dimensional and has few training samples. To tackle these issues, we present a sparse feedforward deep neural architecture for encoding and decoding the structural connectome of the human brain. We use a sparsely connected element-wise multiplication as the first hidden layer and a fixed transform layer as the output layer. The number of trainable parameters and the training time is significantly reduced compared to feedforward networks. We demonstrate superior performance of this architecture in encoding the structural connectome implicated in Alzheimer's disease (AD) and Parkinson's disease (PD) from DTI brain scans. For decoding, we propose recursive feature elimination (RFE) algorithm based on DeepLIFT, layer-wise relevance propagation (LRP), and Integrated Gradients (IG) algorithms to remove irrelevant features and thereby identify key biomarkers associated with AD and PD. We show that the proposed architecture reduces 45.1% and 47.1% of the trainable parameters compared to a feedforward DNN with an increase in accuracy by 2.6 % and 3.1% for cognitively normal (CN) vs AD and CN vs PD classification, respectively. We also show that the proposed RFE method leads to a further increase in accuracy by 2.1% and 4% for CN vs AD and CN vs PD classification, while removing approximately 90% to 95% irrelevant features. Furthermore, we argue that the biomarkers (i.e., key brain regions and connections) identified are consistent with previous literature. We show that relevancy score-based methods can yield high discriminative power and are suitable for brain decoding. We also show that the proposed approach led to a reduction in the number of trainable network parameters, an increase in classification accuracy, and a detection of brain connections and regions that were consistent with earlier studies. |
| author2 |
School of Computer Science and Engineering |
| author_facet |
School of Computer Science and Engineering Singh, Satya P. Gupta, Sukrit Rajapakse, Jagath Chandana |
| format |
Article |
| author |
Singh, Satya P. Gupta, Sukrit Rajapakse, Jagath Chandana |
| author_sort |
Singh, Satya P. |
| title |
Sparse deep neural network for encoding and decoding the structural connectome |
| title_short |
Sparse deep neural network for encoding and decoding the structural connectome |
| title_full |
Sparse deep neural network for encoding and decoding the structural connectome |
| title_fullStr |
Sparse deep neural network for encoding and decoding the structural connectome |
| title_full_unstemmed |
Sparse deep neural network for encoding and decoding the structural connectome |
| title_sort |
sparse deep neural network for encoding and decoding the structural connectome |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/175759 |
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1806059743022678016 |