BrainOmni: A Brain Foundation Model for Unified EEG and MEG Signals
- URL: http://arxiv.org/abs/2505.18185v1
- Date: Sun, 18 May 2025 14:07:14 GMT
- Title: BrainOmni: A Brain Foundation Model for Unified EEG and MEG Signals
- Authors: Qinfan Xiao, Ziyun Cui, Chi Zhang, Siqi Chen, Wen Wu, Andrew Thwaites, Alexandra Woolgar, Bowen Zhou, Chao Zhang,
- Abstract summary: This paper proposes Brain Omni, the first brain foundation model that generalises across heterogeneous EEG and MEG recordings.<n>To unify diverse data sources, we introduce BrainTokenizer, the first tokenizer that quantises neural brain activity into discrete representations.<n>A total of 1,997 hours of EEG and 656 hours of MEG data are curated and standardised from publicly available sources for pretraining.
- Score: 50.76802709706976
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Electroencephalography (EEG) and magnetoencephalography (MEG) measure neural activity non-invasively by capturing electromagnetic fields generated by dendritic currents. Although rooted in the same biophysics, EEG and MEG exhibit distinct signal patterns, further complicated by variations in sensor configurations across modalities and recording devices. Existing approaches typically rely on separate, modality- and dataset-specific models, which limits the performance and cross-domain scalability. This paper proposes BrainOmni, the first brain foundation model that generalises across heterogeneous EEG and MEG recordings. To unify diverse data sources, we introduce BrainTokenizer,the first tokenizer that quantises spatiotemporal brain activity into discrete representations. Central to BrainTokenizer is a novel Sensor Encoder that encodes sensor properties such as spatial layout, orientation, and type, enabling compatibility across devices and modalities. Building upon the discrete representations, BrainOmni learns unified semantic embeddings of brain signals by self-supervised pretraining. To the best of our knowledge, it is the first foundation model to support both EEG and MEG signals, as well as the first to incorporate large-scale MEG pretraining. A total of 1,997 hours of EEG and 656 hours of MEG data are curated and standardised from publicly available sources for pretraining. Experiments show that BrainOmni outperforms both existing foundation models and state-of-the-art task-specific models on a range of downstream tasks. It also demonstrates strong generalisation to unseen EEG and MEG devices. Further analysis reveals that joint EEG-MEG (EMEG) training yields consistent improvements across both modalities. Code and model checkpoints will be released upon acceptance.
Related papers
- CSBrain: A Cross-scale Spatiotemporal Brain Foundation Model for EEG Decoding [57.90382885533593]
We propose a Cross-scale Spatiotemporal Brain foundation model for generalized decoding EEG signals.<n>We show that CSBrain consistently outperforms task-specific and foundation model baselines.<n>These results establish cross-scale modeling as a key inductive bias and position CSBrain as a robust backbone for future brain-AI research.
arXiv Detail & Related papers (2025-06-29T03:29:34Z) - CodeBrain: Bridging Decoupled Tokenizer and Multi-Scale Architecture for EEG Foundation Model [33.550819280074826]
EEG foundation models struggle with limited heterogeneous representation capacity and inefficiency in capturing multi-scale brain dependencies.<n>We propose CodeBrain, an efficient EFM structurally aligned with brain organization, trained in two stages.<n>EEGSSM combines a structured global convolution architecture and a sliding window attention mechanism to jointly model sparse long-range and local dependencies.
arXiv Detail & Related papers (2025-06-10T17:20:39Z) - Large Cognition Model: Towards Pretrained EEG Foundation Model [0.0]
We propose a transformer-based foundation model designed to generalize across diverse EEG datasets and downstream tasks.<n>Our findings highlight the potential of pretrained EEG foundation models to accelerate advancements in neuroscience, personalized medicine, and BCI technology.
arXiv Detail & Related papers (2025-02-11T04:28:10Z) - CEReBrO: Compact Encoder for Representations of Brain Oscillations Using Efficient Alternating Attention [53.539020807256904]
We introduce a Compact for Representations of Brain Oscillations using alternating attention (CEReBrO)<n>Our tokenization scheme represents EEG signals at a per-channel patch.<n>We propose an alternating attention mechanism that jointly models intra-channel temporal dynamics and inter-channel spatial correlations, achieving 2x speed improvement with 6x less memory required compared to standard self-attention.
arXiv Detail & Related papers (2025-01-18T21:44:38Z) - CognitionCapturer: Decoding Visual Stimuli From Human EEG Signal With Multimodal Information [61.1904164368732]
We propose CognitionCapturer, a unified framework that fully leverages multimodal data to represent EEG signals.<n>Specifically, CognitionCapturer trains Modality Experts for each modality to extract cross-modal information from the EEG modality.<n>The framework does not require any fine-tuning of the generative models and can be extended to incorporate more modalities.
arXiv Detail & Related papers (2024-12-13T16:27:54Z) - FoME: A Foundation Model for EEG using Adaptive Temporal-Lateral Attention Scaling [19.85701025524892]
FoME (Foundation Model for EEG) is a novel approach using adaptive temporal-lateral attention scaling.
FoME is pre-trained on a diverse 1.7TB dataset of scalp and intracranial EEG recordings, comprising 745M parameters trained for 1,096k steps.
arXiv Detail & Related papers (2024-09-19T04:22:40Z) - BrainSegFounder: Towards 3D Foundation Models for Neuroimage Segmentation [6.5388528484686885]
This study introduces a novel approach towards the creation of medical foundation models.
Our method involves a novel two-stage pretraining approach using vision transformers.
BrainFounder demonstrates a significant performance gain, surpassing the achievements of previous winning solutions.
arXiv Detail & Related papers (2024-06-14T19:49:45Z) - Large Brain Model for Learning Generic Representations with Tremendous EEG Data in BCI [6.926908480247951]
We propose a unified foundation model for EEG called Large Brain Model (LaBraM)
LaBraM enables cross-dataset learning by segmenting the EEG signals into EEG channel patches.
We then pre-train neural Transformers by predicting the original neural codes for the masked EEG channel patches.
arXiv Detail & Related papers (2024-05-29T05:08:16Z) - A Knowledge-Driven Cross-view Contrastive Learning for EEG
Representation [48.85731427874065]
This paper proposes a knowledge-driven cross-view contrastive learning framework (KDC2) to extract effective representations from EEG with limited labels.
The KDC2 method creates scalp and neural views of EEG signals, simulating the internal and external representation of brain activity.
By modeling prior neural knowledge based on neural information consistency theory, the proposed method extracts invariant and complementary neural knowledge to generate combined representations.
arXiv Detail & Related papers (2023-09-21T08:53:51Z) - UniBrain: Universal Brain MRI Diagnosis with Hierarchical
Knowledge-enhanced Pre-training [66.16134293168535]
We propose a hierarchical knowledge-enhanced pre-training framework for the universal brain MRI diagnosis, termed as UniBrain.
Specifically, UniBrain leverages a large-scale dataset of 24,770 imaging-report pairs from routine diagnostics.
arXiv Detail & Related papers (2023-09-13T09:22:49Z) - Neuro-BERT: Rethinking Masked Autoencoding for Self-supervised Neurological Pretraining [24.641328814546842]
We present Neuro-BERT, a self-supervised pre-training framework of neurological signals based on masked autoencoding in the Fourier domain.
We propose a novel pre-training task dubbed Fourier Inversion Prediction (FIP), which randomly masks out a portion of the input signal and then predicts the missing information.
By evaluating our method on several benchmark datasets, we show that Neuro-BERT improves downstream neurological-related tasks by a large margin.
arXiv Detail & Related papers (2022-04-20T16:48:18Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.