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| Main Authors: | , , , , , , |
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| Format: | Preprint |
| Published: |
2025
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2511.20522 |
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| _version_ | 1866911286515728384 |
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| author | Flynn, Andrew McCafferty, Cian Lehnertz, Klaus David, François Crunelli, Vincenzo Marnane, William P. Wieczorek, Sebastian |
| author_facet | Flynn, Andrew McCafferty, Cian Lehnertz, Klaus David, François Crunelli, Vincenzo Marnane, William P. Wieczorek, Sebastian |
| contents | Understanding how the brain switches from normal activity to an epileptic seizure is essential for improving seizure therapy, yet the underlying mechanisms remain largely unknown. In particular, seizure onset can be described as a critical transition (CT), but there is no consensus on whether (i) bifurcation-induced, (ii) noise-induced, or (iii) bifurcation/noise-induced CTs are responsible. To clarify this, we develop a versatile CT-classification framework that can be applied to seizures in both animals and humans. First, we identify a canonical mathematical model which displays CTs that closely resemble voltage recordings of real seizures and can be of the three types mentioned above. We then identify distinctive properties of each CT-type in the model's output and use them to train a machine learning CT-type classifier. Finally, we apply the model-trained classifier to voltage recordings from epileptic rodents. We find that the largest proportion of analysed seizures are classified as noise-induced CTs. This challenges the conventional view that seizures are predominantly bifurcation-induced and could inform new therapeutic strategies for seizures. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2511_20522 |
| institution | arXiv |
| publishDate | 2025 |
| record_format | arxiv |
| spellingShingle | Classifying seizure generation mechanisms: A critical transitions framework Flynn, Andrew McCafferty, Cian Lehnertz, Klaus David, François Crunelli, Vincenzo Marnane, William P. Wieczorek, Sebastian Dynamical Systems Understanding how the brain switches from normal activity to an epileptic seizure is essential for improving seizure therapy, yet the underlying mechanisms remain largely unknown. In particular, seizure onset can be described as a critical transition (CT), but there is no consensus on whether (i) bifurcation-induced, (ii) noise-induced, or (iii) bifurcation/noise-induced CTs are responsible. To clarify this, we develop a versatile CT-classification framework that can be applied to seizures in both animals and humans. First, we identify a canonical mathematical model which displays CTs that closely resemble voltage recordings of real seizures and can be of the three types mentioned above. We then identify distinctive properties of each CT-type in the model's output and use them to train a machine learning CT-type classifier. Finally, we apply the model-trained classifier to voltage recordings from epileptic rodents. We find that the largest proportion of analysed seizures are classified as noise-induced CTs. This challenges the conventional view that seizures are predominantly bifurcation-induced and could inform new therapeutic strategies for seizures. |
| title | Classifying seizure generation mechanisms: A critical transitions framework |
| topic | Dynamical Systems |
| url | https://arxiv.org/abs/2511.20522 |