Your search keyword '"Zachary V. Freudenburg"' showing total 6 results

1. Open multimodal iEEG-fMRI dataset from naturalistic stimulation with a short audiovisual film

Author

Julia Berezutskaya, Mariska J. Vansteensel, Erik J. Aarnoutse, Zachary V. Freudenburg, Giovanni Piantoni, Mariana P. Branco, and Nick F. Ramsey

Subjects

Science

Abstract

Measurement(s) brain activity measurement Technology Type(s) Intracranial EEG • functional magnetic resonance imaging Factor Type(s) Short audiovisual film stimulus Sample Characteristic - Organism Homo sapiens

Published

2022

2. Detailed somatotopy of tongue movement in the human sensorimotor cortex: A case study

Author

Anouck Schippers, Mariska J. Vansteensel, Zachary V. Freudenburg, Frans S.S. Leijten, and Nick F. Ramsey

Subjects

Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2021

3. Sensorimotor ECoG Signal Features for BCI Control: A Comparison Between People With Locked-In Syndrome and Able-Bodied Controls

Author

Zachary V. Freudenburg, Mariana P. Branco, Sacha Leinders, Benny H. van der Vijgh, Elmar G. M. Pels, Timothy Denison, Leonard H. van den Berg, Kai J. Miller, Erik J. Aarnoutse, Nick F. Ramsey, and Mariska J. Vansteensel

Subjects

brain-computer interface, implant, sensorimotor cortex, amyotrophic lateral sclerosis, brain stem stroke, electrocorticography, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The sensorimotor cortex is a frequently targeted brain area for the development of Brain-Computer Interfaces (BCIs) for communication in people with severe paralysis and communication problems (locked-in syndrome; LIS). It is widely acknowledged that this area displays an increase in high-frequency band (HFB) power and a decrease in the power of the low frequency band (LFB) during movement of, for example, the hand. Upon termination of hand movement, activity in the LFB band typically shows a short increase (rebound). The ability to modulate the neural signal in the sensorimotor cortex by imagining or attempting to move is crucial for the implementation of sensorimotor BCI in people who are unable to execute movements. This may not always be self-evident, since the most common causes of LIS, amyotrophic lateral sclerosis (ALS) and brain stem stroke, are associated with significant damage to the brain, potentially affecting the generation of baseline neural activity in the sensorimotor cortex and the modulation thereof by imagined or attempted hand movement. In the Utrecht NeuroProsthesis (UNP) study, a participant with LIS caused by ALS and a participant with LIS due to brain stem stroke were implanted with a fully implantable BCI, including subdural electrocorticography (ECoG) electrodes over the sensorimotor area, with the purpose of achieving ECoG-BCI-based communication. We noted differences between these participants in the spectral power changes generated by attempted movement of the hand. To better understand the nature and origin of these differences, we compared the baseline spectral features and task-induced modulation of the neural signal of the LIS participants, with those of a group of able-bodied people with epilepsy who received a subchronic implant with ECoG electrodes for diagnostic purposes. Our data show that baseline LFB oscillatory components and changes generated in the LFB power of the sensorimotor cortex by (attempted) hand movement differ between participants, despite consistent HFB responses in this area. We conclude that the etiology of LIS may have significant effects on the LFB spectral components in the sensorimotor cortex, which is relevant for the development of communication-BCIs for this population.

Published

2019

4. High-frequency band temporal dynamics in response to a grasp force task.

Author

Mariana P Branco, Simon H Geukes, Erik J Aarnoutse, Mariska J Vansteensel, Zachary V Freudenburg, and Nick F Ramsey

Published

2019

5. Optimization of sampling rate and smoothing improves classification of high frequency power in electrocorticographic brain signals.

Author

Mariana P Branco, Zachary V Freudenburg, Erik J Aarnoutse, Mariska J Vansteensel, and Nick F Ramsey

Published

2018

6. Brain-optimized extraction of complex sound features that drive continuous auditory perception.

Author

Julia Berezutskaya, Zachary V Freudenburg, Umut Güçlü, Marcel A J van Gerven, and Nick F Ramsey

Subjects

Biology (General), QH301-705.5

Abstract

Understanding how the human brain processes auditory input remains a challenge. Traditionally, a distinction between lower- and higher-level sound features is made, but their definition depends on a specific theoretical framework and might not match the neural representation of sound. Here, we postulate that constructing a data-driven neural model of auditory perception, with a minimum of theoretical assumptions about the relevant sound features, could provide an alternative approach and possibly a better match to the neural responses. We collected electrocorticography recordings from six patients who watched a long-duration feature film. The raw movie soundtrack was used to train an artificial neural network model to predict the associated neural responses. The model achieved high prediction accuracy and generalized well to a second dataset, where new participants watched a different film. The extracted bottom-up features captured acoustic properties that were specific to the type of sound and were associated with various response latency profiles and distinct cortical distributions. Specifically, several features encoded speech-related acoustic properties with some features exhibiting shorter latency profiles (associated with responses in posterior perisylvian cortex) and others exhibiting longer latency profiles (associated with responses in anterior perisylvian cortex). Our results support and extend the current view on speech perception by demonstrating the presence of temporal hierarchies in the perisylvian cortex and involvement of cortical sites outside of this region during audiovisual speech perception.

Published

2020