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2021 | OriginalPaper | Chapter

StairwayGraphNet for Inter- and Intra-modality Multi-resolution Brain Graph Alignment and Synthesis

Authors : Islem Mhiri, Mohamed Ali Mahjoub, Islem Rekik

Published in: Machine Learning in Medical Imaging

Publisher: Springer International Publishing

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Abstract

Synthesizing multimodality medical data provides complementary knowledge and helps doctors make precise clinical decisions. Although promising, existing multimodal brain graph synthesis frameworks have several limitations. First, they mainly tackle only one problem (intra- or inter-modality), limiting their generalizability to synthesizing inter- and intra-modality simultaneously. Second, while few techniques work on super-resolving low-resolution brain graphs within a single modality (i.e., intra), inter-modality graph super-resolution remains unexplored though this would avoid the need for costly data collection and processing. More importantly, both target and source domains might have different distributions, which causes a domain fracture between them. To fill these gaps, we propose a multi-resolution StairwayGraphNet (SG-Net) framework to jointly infer a target graph modality based on a given modality and super-resolve brain graphs in both inter and intra domains. Our SG-Net is grounded in three main contributions: (i) predicting a target graph from a source one based on a novel graph generative adversarial network in both inter (e.g., morphological-functional) and intra (e.g., functional-functional) domains, (ii) generating high-resolution brain graphs without resorting to the time consuming and expensive MRI processing steps, and (iii) enforcing the source distribution to match that of the ground truth graphs using an inter-modality aligner to relax the loss function to optimize. Moreover, we design a new Ground Truth-Preserving loss function to guide both generators in learning the topological structure of ground truth brain graphs more accurately. Our comprehensive experiments on predicting target brain graphs from source graphs using a multi-resolution stairway showed the outperformance of our method in comparison with its variants and state-of-the-art method. SG-Net presents the first work for graph alignment and synthesis across varying modalities and resolutions, which handles graph size, distribution, and structure variations. Our Python TIS-Net code is available on BASIRA GitHub at https://github.com/basiralab/SG-Net.

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previous chapter Exploring Gyro-Sulcal Functional Connectivity Differences Across Task Domains via Anatomy-Guided Spatio-Temporal Graph Convolutional Networks

next chapter Multi-Feature Semi-Supervised Learning for COVID-19 Diagnosis from Chest X-Ray Images

Available only for authorised users

https://github.com/basiralab/SG-Net.

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Title: StairwayGraphNet for Inter- and Intra-modality Multi-resolution Brain Graph Alignment and Synthesis
Authors: Islem Mhiri
Mohamed Ali Mahjoub
Islem Rekik
Publisher: Springer International Publishing
Book: Machine Learning in Medical Imaging
Print ISBN: 978-3-030-87588-6

Electronic ISBN: 978-3-030-87589-3

Copyright Year: 2021
DOI: https://doi.org/10.1007/978-3-030-87589-3_15

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