August 5, 2025
The GIST AI model uncovers and reconstructs hidden multi-entity relationships 
Gaby Clark
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Robert Egan
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Just like when multiple people gather simultaneously in a meeting room, higher-order interactions—where many entities interact at once—occur across various fields and reflect the complexity of real-world relationships. However, due to technical limitations, in many fields, only low-order pairwise interactions between entities can be observed and collected, which results in the loss of full context and restricts practical use.
KAIST researchers led by Professor Kijung Shin have developed the AI model "MARIOH" (Multiplicity-Aware Hypergraph Reconstruction), which can accurately reconstruct higher-order interactions from such low-order information, opening up innovative analytical possibilities in fields like social network analysis, neuroscience, and life sciences.
Reconstructing higher-order interactions is challenging because a vast number of higher-order interactions can arise from the same low-order structure.
The key idea behind MARIOH, developed by the research team, is to utilize multiplicity information of low-order interactions to drastically reduce the number of candidate higher-order interactions that could stem from a given structure.
In addition, by employing efficient search techniques, MARIOH quickly identifies promising interaction candidates and uses multiplicity-based deep learning to accurately predict the likelihood that each candidate represents an actual higher-order interaction.
Through experiments on ten diverse real-world datasets, the research team showed that MARIOH reconstructed higher-order interactions with up to 74% greater accuracy compared to existing methods.
For instance, in a dataset on co-authorship relations (source: DBLP), MARIOH achieved a reconstruction accuracy of over 98%, significantly outperforming existing methods, which reached only about 86%. Furthermore, leveraging the reconstructed higher-order structures led to improved performance in downstream tasks, including prediction and classification.
According to Kijung, "MARIOH moves beyond existing approaches that rely solely on simplified connection information, enabling precise analysis of the complex interconnections found in the real world." Furthermore, "it has broad potential applications in fields such as social network analysis for group chats or collaborative networks, life sciences for studying protein complexes or gene interactions, and neuroscience for tracking simultaneous activity across multiple brain regions."
The research was conducted by Kyuhan Lee (Integrated M.S.–Ph.D. program at the Kim Jaechul Graduate School of AI at KAIST; currently a software engineer at GraphAI), Geon Lee (Integrated M.S.–Ph.D. program at KAIST), and Professor Kijung Shin. It was presented at the 41st IEEE International Conference on Data Engineering, held in Hong Kong this past May.
More information: Kyuhan Lee et al, MARIOH: Multiplicity-Aware Hypergraph Reconstruction 2025 IEEE 41st International Conference on Data Engineering (ICDE) (2025). DOI: 10.1109/ICDE65448.2025.00233. www.computer.org/csdl/proceedi … 0300d113/26FZBtqbYzK
Provided by The Korea Advanced Institute of Science and Technology (KAIST) Citation: AI model uncovers and reconstructs hidden multi-entity relationships (2025, August 5) retrieved 5 August 2025 from https://techxplore.com/news/2025-08-ai-uncovers-reconstructs-hidden-multi.html This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.
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