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Karim Jerbi

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24 papers
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24

NeurIPS Conference 2025 Conference Paper

REVE: A Foundation Model for EEG - Adapting to Any Setup with Large-Scale Pretraining on 25,000 Subjects

  • Yassine El Ouahidi
  • Jonathan Lys
  • Philipp Thölke
  • Nicolas Farrugia
  • Bastien Pasdeloup
  • Vincent Gripon
  • Karim Jerbi
  • Giulia Lioi

Foundation models have transformed AI by reducing reliance on task-specific data through large-scale pretraining. While successful in language and vision, their adoption in EEG has lagged due to the heterogeneity of public datasets, which are collected under varying protocols, devices, and electrode configurations. Existing EEG foundation models struggle to generalize across these variations, often restricting pretraining to a single setup, resulting in suboptimal performance, in particular under linear probing. We present REVE (Representation for EEG with Versatile Embeddings), a pretrained model explicitly designed to generalize across diverse EEG signals. REVE introduces a novel 4D positional encoding scheme that enables it to process signals of arbitrary length and electrode arrangement. Using a masked autoencoding objective, we pretrain REVE on over 60, 000 hours of EEG data from 92 datasets spanning 25, 000 subjects, representing the largest EEG pretraining effort to date. REVE achieves state-of-the-art results on 10 downstream EEG tasks, including motor imagery classification, seizure detection, sleep staging, cognitive load estimation, and emotion recognition. With little to no fine-tuning, it demonstrates strong generalization, and nuanced spatio-temporal modeling. We release code, pretrained weights, and tutorials to support standardized EEG research and accelerate progress in clinical neuroscience.

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RLDM Conference 2019 Conference Abstract

Decoding the neural dynamics of dynamic decision making in humans

  • Thomas Thiery
  • Pierre Rainville
  • Paul Cisek
  • Karim Jerbi

Imagine you are driving to a new destination, deciding on the best route. As you drive, your decision is informed by road signs, advice from your passengers, your GPS, etc. Crucially, as you approach a potential turn, you are urged to make your decision even if you are not yet fully confident. In ecological settings, the available information for making a choice can change without warning, and the urgency to choose one way or another is among many factors influencing the decision process. Recently, neurophys- iological studies in monkeys performing perceptual decision-making tasks, combined with computational models, have paved the way for theories about how the brain makes decisions in a constantly changing en- vironment. However, the underlying mechanisms and whole-brain dynamics involved in processing sensory information and making a variety of trade-offs between the speed of a decision and its accuracy in humans are still poorly understood. For the first time, this study sheds light on the role of whole-brain rhythmic synchronization during deliberation and commitment during dynamic decision-making in human (n = 30) using magnetoencephalography. Here, we show that source-reconstructed local field potentials in the beta band [15-30 Hz]) in the precentral gyrus build up in an evidence-related manner, reflecting the competition between response options biased by sensory information. We also observe that beta oscillations are sensitive to the urgency signal, and build-up earlier in fast blocks than in slow blocks.

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RLDM Conference 2019 Conference Abstract

Decoding the neural dynamics of Free Choice

  • Thomas Thiery
  • Anne-Lise Saive
  • Etienne Combrisson
  • Philippe Kahane
  • Alain Berthoz
  • Philippe Lachaux
  • Karim Jerbi

How does the human brain decide what to do when we face maximally competing alternatives that we are free to choose between? Planning actions to select an alternative is associated with changes in patterns of rhythmic neuronal activity across widely distributed brain areas, but little is known about the spatiotemporal brain dynamics that give rise to motor decisions in humans. We address this question with unprecedented resolution thanks to intracerebral EEG recordings from 778 sites across six medically intractable epilepsy patients while they performed a delayed oculomotor task. We use a data-driven ap- proach to identify temporal, spatial, and spectral signatures of human cortical networks engaged in active and intrinsically motivated viewing behavior at the single-trial level. We find that sustained high gamma (HG) activity (60-140 Hz) in fronto-parietal areas reflect the intrinsically driven process of selection among competing behavioral alternatives during free choice, while instructed saccade planning is characterized by an early transient increase in HG activity, accompanied by a suppression of β oscillations (16-30 Hz), thus leading to a fast encoding of a motor plan. Furthermore, we show that HG activity during saccade execution is tightly coupled to reaction times and action selection processes during the planning phase.

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