Geometric deep learning reveals a structuro-temporal understanding of healthy and pathologic brain aging

Besson, Pierre; Rogalskı, Emily; Gill, Nathan; Zhang, Hui; Martersteck, Adam; Bandt, S. Kathleen

doi:10.3389/fnagi.2022.895535

Cited by 3 publications

(1 citation statement)

References 65 publications

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“…Finally, we mention the use of geometric deep learning techniques in neuroimaging and the study of the brain connectome (Gurbuz and Rekik, 2020 ; Huang et al, 2021 ; Williams et al, 2021 ), as well as the study on (i) the relationship of human brain structure to cognitive function (Wu et al, 2022 ), (ii) the topographic heterogeneity of cortical organisation as a necessary step toward precision modelling of neuropsychiatric disorders (Williams et al, 2021 ), (iii) brain aging (Besson et al, 2022 ).…”

Section: Geometric Deep Learningmentioning

confidence: 99%

Graph embedding and geometric deep learning relevance to network biology and structural chemistry

Lecca,

Lecca

2023

Front. Artif. Intell.

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Graphs are used as a model of complex relationships among data in biological science since the advent of systems biology in the early 2000. In particular, graph data analysis and graph data mining play an important role in biology interaction networks, where recent techniques of artificial intelligence, usually employed in other type of networks (e.g., social, citations, and trademark networks) aim to implement various data mining tasks including classification, clustering, recommendation, anomaly detection, and link prediction. The commitment and efforts of artificial intelligence research in network biology are motivated by the fact that machine learning techniques are often prohibitively computational demanding, low parallelizable, and ultimately inapplicable, since biological network of realistic size is a large system, which is characterised by a high density of interactions and often with a non-linear dynamics and a non-Euclidean latent geometry. Currently, graph embedding emerges as the new learning paradigm that shifts the tasks of building complex models for classification, clustering, and link prediction to learning an informative representation of the graph data in a vector space so that many graph mining and learning tasks can be more easily performed by employing efficient non-iterative traditional models (e.g., a linear support vector machine for the classification task). The great potential of graph embedding is the main reason of the flourishing of studies in this area and, in particular, the artificial intelligence learning techniques. In this mini review, we give a comprehensive summary of the main graph embedding algorithms in light of the recent burgeoning interest in geometric deep learning.

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Section: Geometric Deep Learningmentioning

confidence: 99%

Graph embedding and geometric deep learning relevance to network biology and structural chemistry

Lecca,

Lecca

2023

Front. Artif. Intell.

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Whole-brain radiotherapy associated with structural changes resembling aging as determined by anatomic surface-based deep learning

Ram-Mohan

Besson

et al. 2023

Neuro-Oncology

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Background Brain metastases are the most common intracranial tumors in adults and are associated with significant morbidity and mortality. Whole brain radiotherapy (WBRT) is used frequently in patients for palliation, but can result in neurocognitive deficits. While dose-dependent injury to individual areas such as the hippocampus have been demonstrated, global structural shape changes after WBRT remain to be studied. Methods We studied healthy controls and patients with brain metastases and examined MRI brain anatomic surface data before and after WBRT. We implemented a validated graph convolutional neural network model to estimate patient’s “brain age”. We further developed a mixed-effects linear model to compare estimated age of whole brain and substructures before and after WBRT. Results 4220 subjects were analyzed (4148 healthy controls and 72 patients). Median radiation dose was 30Gy (range 25 – 37.5Gy). The whole brain and substructures underwent structural change resembling rapid aging in radiated patients compared to healthy controls; the whole brain “aged” 9.32 times faster, the cortex 8.05 times faster, the subcortical structures 12.57 times faster, and the hippocampus 10.14 times faster. In a subset analysis, the hippocampus “aged” 8.88 times faster in patients after conventional WBRT versus after hippocampal avoidance (HA)-WBRT. Conclusions Our findings suggest that WBRT causes the brain and its substructures to undergo structural changes at a pace up to 13x of the normal aging pace, where hippocampal avoidance offers focal structural protection. Correlating these structural imaging changes with neurocognitive outcomes following WBRT or HA-WBRT would benefit from future analysis.

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Deep Age Estimation Using Structural MRI: Unveiling Neurological Patterns

Subbarayudu,

Michael,

Kumari

2024

2024 2nd International Conference on Networking and Communications (ICNWC)

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Geometric deep learning reveals a structuro-temporal understanding of healthy and pathologic brain aging

Cited by 3 publications

References 65 publications

Graph embedding and geometric deep learning relevance to network biology and structural chemistry

Graph embedding and geometric deep learning relevance to network biology and structural chemistry

Whole-brain radiotherapy associated with structural changes resembling aging as determined by anatomic surface-based deep learning

Deep Age Estimation Using Structural MRI: Unveiling Neurological Patterns

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