Your search keyword '"Christelle, Larzabal"' showing total 3 results

1. Author response for 'Long-term stability of the chronic epidural wireless recorder WIMAGINE in tetraplegic patients'

Author

Tatiana Aksenova, Fabien Sauter-Starace, Vincent Auboiroux, Thomas Costecalde, Guillaume Charvet, Stephan Chabardes, Stéphane Bonnet, and Christelle Larzabal

Subjects

medicine.medical_specialty, Physical medicine and rehabilitation, business.industry, medicine, Wireless, business, Term (time)

Published

2021

2. Space–Time–Frequency Multi-Sensor Analysis for Motor Cortex Localization Using Magnetoencephalography

Author

Victor Rohu, Nana Arizumi, Alim-Louis Benabid, Christelle Larzabal, Lilia Langar, Etienne Labyt, Vincent Auboiroux, Tetiana Aksenova, and Ales Mishchenko

Subjects

magnetoencephalography, Computer science, Electroencephalography, lcsh:Chemical technology, Biochemistry, Signal, Article, 050105 experimental psychology, localization, Analytical Chemistry, 03 medical and health sciences, symbols.namesake, source imaging, Spatio-Temporal Analysis, 0302 clinical medicine, medicine, Humans, 0501 psychology and cognitive sciences, lcsh:TP1-1185, multi-sensor, Electrical and Electronic Engineering, Instrumentation, Brain Mapping, medicine.diagnostic_test, business.industry, 05 social sciences, Motor Cortex, time–frequency, Pattern recognition, Magnetoencephalography, Inverse problem, coefficient of determination, Atomic and Molecular Physics, and Optics, Pearson product-moment correlation coefficient, Time–frequency analysis, cortex, Electro encephalography, symbols, linear regression, Artificial intelligence, business, 030217 neurology & neurosurgery

Abstract

Brain source imaging and time frequency mapping (TFM) are commonly used in magneto/electro encephalography (M/EEG) imaging. However, these methods suffer from important limitations. Source imaging is based on an ill-posed inverse problem leading to instability of source localization solutions, has a limited capacity to localize high frequency oscillations and loses its robustness for induced responses (ill-defined trigger). The drawback of TFM is that it involves independent analysis of signals from a number of frequency bands, and from co-localized sensors. In the present article, a regression-based multi-sensor space&ndash, time&ndash, frequency analysis (MSA) approach, which integrates co-localized sensors and/or multi-frequency information, is proposed. To estimate task-specific brain activations, MSA uses cross-validated, shifted, multiple Pearson correlation, calculated from the time&ndash, frequency transformed brain signal and the binary signal of stimuli. The results are projected from the sensor space onto the cortical surface. To assess MSA performance, the proposed method was compared to the weighted minimum norm estimate (wMNE) source imaging method, in terms of spatial selectivity and robustness against an ill-defined trigger. Magnetoencephalography (MEG) recordings were performed in fourteen subjects during two motor tasks: finger tapping and elbow flexion/extension. In particular, our results show that the MSA approach provides good localization performance when compared to wMNE and statistically significant improvement of robustness against ill-defined trigger.

Published

2020

3. Long-term stability of the chronic epidural wireless recorder WIMAGINE in tetraplegic patients

Author

Christelle Larzabal, Guillaume Charvet, Vincent Auboiroux, Tetiana Aksenova, Thomas Costecalde, Stephan Chabardes, Stéphane Bonnet, and Fabien Sauter-Starace

Subjects

Epidural Space, medicine.medical_specialty, business.industry, Biomedical Engineering, Brain, Electroencephalography, Context (language use), Audiology, medicine.disease, Signal, Electrodes, Implanted, Cellular and Molecular Neuroscience, Motor imagery, Signal-to-noise ratio, Brain-Computer Interfaces, Humans, Medicine, Electrocorticography, Implant, Spectral edge frequency, business, Wireless Technology, Spinal cord injury, Brain–computer interface

Abstract

Objective.The evaluation of the long-term stability of ElectroCorticoGram (ECoG) signals is an important scientific question as new implantable recording devices can be used for medical purposes such as Brain-Computer Interface (BCI) or brain monitoring.Approach.The long-term clinical validation of wireless implantable multi-channel acquisition system for generic interface with neurons (WIMAGINE), a wireless 64-channel epidural ECoG recorder was investigated. The WIMAGINE device was implanted in two quadriplegic patients within the context of a BCI protocol. This study focused on the ECoG signal stability in two patients bilaterally implanted in June 2017 (P1) and in November 2019 (P2).Methods. The ECoG signal was recorded at rest prior to each BCI session resulting in a 32 month and in a 14 month follow-up for P1 and P2 respectively. State-of-the-art signal evaluation metrics such as root mean square (RMS), the band power (BP), the signal to noise ratio (SNR), the effective bandwidth (EBW) and the spectral edge frequency (SEF) were used to evaluate stability of signal over the implantation time course. The time-frequency maps obtained from task-related motor activations were also studied to investigate the long-term selectivity of the electrodes.Mainresults.Based on temporal linear regressions, we report a limited decrease of the signal average level (RMS), spectral distribution (BP) and SNR, and a remarkable steadiness of the EBW and SEF. Time-frequency maps obtained during motor imagery, showed a high level of discrimination 1 month after surgery and also after 2 years.Conclusions.The WIMAGINE epidural device showed high stability over time. The signal evaluation metrics of two quadriplegic patients during 32 months and 14 months respectively provide strong evidence that this wireless implant is well-suited for long-term ECoG recording.Significance.These findings are relevant for the future of implantable BCIs, and could benefit other patients with spinal cord injury, amyotrophic lateral sclerosis, neuromuscular diseases or drug-resistant epilepsy.

Published

2021