Abstract
Catchy but rigorous deep learning architectures were tailored for image super-resolution (SR), however, these fail to generalize to non-Euclidean data such as brain connectomes. Specifically, building generative models for super-resolving a low-resolution brain connectome at a higher resolution (i.e., adding new graph nodes/edges) remains unexplored —although this would circumvent the need for costly data collection and manual labelling of anatomical brain regions (i.e. parcellation). To fill this gap, we introduce GSR-Net (Graph Super-Resolution Network), the first super-resolution framework operating on graph-structured data that generates high-resolution brain graphs from low-resolution graphs. First, we adopt a U-Net like architecture based on graph convolution, pooling and unpooling operations specific to non-Euclidean data. However, unlike conventional U-Nets where graph nodes represent samples and node features are mapped to a low-dimensional space (encoding and decoding node attributes or sample features), our GSR-Net operates directly on a single connectome: a fully connected graph where conventionally, a node denotes a brain region, nodes have no features, and edge weights denote brain connectivity strength between two regions of interest (ROIs). In the absence of original node features, we initially assign identity feature vectors to each brain ROI (node) and then leverage the learned local receptive fields to learn node feature representations. Specifically, for each ROI, we learn a node feature embedding by locally averaging the features of its neighboring nodes based on their connectivity weights. Second, inspired by spectral theory, we break the symmetry of the U-Net architecture by topping it up with a graph super-resolution (GSR) layer and two graph convolutional network layers to predict a HR (high-resolution) graph while preserving the characteristics of the LR (low-resolution) input. Our proposed GSR-Net framework outperformed its variants for predicting high-resolution brain functional connectomes from low-resolution connectomes. Our Python GSR-Net code is available on BASIRA GitHub at https://github.com/basiralab/GSR-Net.
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References
Bahrami, K., Shi, F., Rekik, I., Gao, Y., Shen, D.: 7T-guided super-resolution of 3T mri. Med. Phys. 44, 1661–1677 (2017)
Chen, Y., Xie, Y., Zhou, Z., Shi, F., Christodoulou, A.G., Li, D.: Brain mri super resolution using 3d deep densely connected neural networks. In: 2018 IEEE 15th International Symposium on Biomedical Imaging (ISBI 2018), pp. 739–742. IEEE (2018)
Ebner, M., et al.: An automated framework for localization, segmentation and super-resolution reconstruction of fetal brain mri. NeuroImage 206, 116324 (2020)
Dong, C., Loy, C.C., He, K., Tang, X.: Image super-resolution using deep convolutional networks (2014)
Ledig, C., et al.: Photo-realistic single image super-resolution using a generative adversarial network. In: Proceedings of the IEEE conference on computer vision and pattern recognition, pp. 4681–4690 (2016)
Bahrami, K., Shi, F., Rekik, I.: Convolutional neural network for reconstruction of 7T-like images from 3T MRI using appearance and anatomical features. In: International Conference on Medical Image Computing and Computer-Assisted Intervention, (2016)
Lyu, Q., Shan, H., Wang, G.: Mri super-resolution with ensemble learning and complementary priors. IEEE Trans. Comput. Imaging 6, 615–624 (2020)
Bassett, D.S., Sporns, O.: Network neuroscience. Nat. Neurosci. 20, 353 (2017)
Fornito, A., Zalesky, A., Breakspear, M.: The connectomics of brain disorders. Nat. Rev. Neurosci. 16, 159–172 (2015)
Van den Heuvel, M.P., Sporns, O.: A cross-disorder connectome landscape of brain dysconnectivity. Nat. Rev. Neurosci. 20, 435–446 (2019)
Qi, S., Meesters, S., Nicolay, K., ter Haar Romeny, B.M., Ossenblok, P.: The influence of construction methodology on structural brain network measures: a review. J. Neurosci. Methods 253, 170–182 (2015)
Bressler, S.L., Menon, V.: Large-scale brain networks in cognition: emerging methods and principles. Trends Cognitive Sci. 14, 277–290 (2010)
Cui, P., Wang, X., Pei, J., Zhu, W.: A survey on network embedding. IEEE Trans. Knowl. Data Eng. 31(5), 833–852 (2017)
Gao, H., Ji, S.: Graph u-nets. In: Chaudhuri, K., Salakhutdinov, R., (eds.) Proceedings of the 36th International Conference on Machine Learning. Volume 97 of Proceedings of Machine Learning Research., Long Beach, CA, USA, PMLR, pp. 2083–2092 (2019)
Cengiz, K., Rekik, I.: Predicting high-resolution brain networks using hierarchically embedded and aligned multi-resolution neighborhoods. In: Rekik, I., Adeli, E., Park, S.H. (eds.) PRIME 2019. LNCS, vol. 11843, pp. 115–124. Springer, Cham (2019). https://doi.org/10.1007/978-3-030-32281-6_12
Mhiri, I., Khalifa, A.B., Mahjoub, M.A., Rekik, I.: Brain graph super-resolution for boosting neurological disorder diagnosis using unsupervised multi-topology connectional brain template learning. Med. Image Anal. 65, 101768 (2020)
Scarselli, F., Gori, M., Tsoi, A.C., Hagenbuchner, M., Monfardini, G.: The graph neural network model. IEEE Trans. Neural Netw. 20, 61–80 (2009)
Tanaka, Y.: Spectral domain sampling of graph signals. IEEE Trans. Signal Process. 66, 3752–3767 (2018)
Chepuri, S.P., Leus, G.: Subsampling for graph power spectrum estimation. In: 2016 IEEE Sensor Array and Multichannel Signal Processing Workshop (SAM), pp. 1–5. IEEE (2016)
Liu, W., et al.: Longitudinal test-retest neuroimaging data from healthy young adults in southwest china. Scientific Data. 4(1), 1–9 (2017)
Dosenbach, N.U., et al.: Prediction of individual brain maturity using fMRI. Sci. 329, 1358–1361 (2010)
Shen, X., Tokoglu, F., Papademetris, X., Constable, R.: Groupwise whole-brain parcellation from resting-state fMRI data for network node identification. NeuroImage 82, 403–415 (2013)
Van den Heuvel, M.P., Bullmore, E.T., Sporns, O.: Comparative connectomics. Trends Cognitive Sci. 20, 345–361 (2016)
Hammond, D.K., Vandergheynst, P., Gribonval, R.: Wavelets on graphs via spectral graph theory. Appl. Comput. Harmonic Anal. 30(2), 129–150 (2009)
Dhifallah, S., Rekik, I., Initiative, A.D.N., et al.: Estimation of connectional brain templates using selective multi-view network normalization. Med. Image Anal. 59, 101567 (2020)
Acknowledgement
This project has been funded by the 2232 International Fellowship for Outstanding Researchers Program of TUBITAK (Project No:118C288, http://basira-lab.com/reprime/) supporting I. Rekik. However, all scientific contributions made in this project are owned and approved solely by the authors.
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Isallari, M., Rekik, I. (2020). GSR-Net: Graph Super-Resolution Network for Predicting High-Resolution from Low-Resolution Functional Brain Connectomes. In: Liu, M., Yan, P., Lian, C., Cao, X. (eds) Machine Learning in Medical Imaging. MLMI 2020. Lecture Notes in Computer Science(), vol 12436. Springer, Cham. https://doi.org/10.1007/978-3-030-59861-7_15
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DOI: https://doi.org/10.1007/978-3-030-59861-7_15
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