Intraoperative microseizure detection using a high-density micro-electrocorticography electrode array

Sun, James; Barth, Katrina J.; Qiao, Shaoyu; Chiang, Chia‐Han; Wang, Charles; Rahimpour, Shervin; Trumpis, Michael; Duraivel, Suseendrakumar; Dubey, Agrita; Wingel, Katie E.; Rachinskiy, Iakov; Voinas, Alex S.; Ferrentino, Breonna; Southwell, Derek G.; Haglund, Michael M.; Friedman, Allan H.; Lad, Shivanand P.; Doyle, Werner; Solzbacher, Florian; Cogan, Gregory B.; Sinha, Saurabh; Devore, Sasha; Devinsky, Orrin; Friedman, Daniel; Pesaran, Bijan; Viventi, Jonathan

doi:10.1101/2021.09.13.21263449

Cited by 3 publications

(5 citation statements)

References 36 publications

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“…Our high-density μECoG arrays recorded neural signals in SMC that produced significantly higher fidelity HG-ESNR as compared to standard intracranial methods (ECoG/SEEG). This result is in keeping with previous work that sampled microscale epileptic activity using high-density μECoG arrays, which revealed a striking heterogeneity in the spatio-temporal dynamics of interictal events 47,48 . Importantly, microseizures were observed occurring on just two electrodes spaced 750 μm apart, and were not visible on neighboring electrodes.…”

Section: Discussionsupporting

confidence: 92%

“…2D ) at <2mm spacing, which both extends previous work with coarser spatial sampling and demonstrates the informative nature of signals at the millimeter scale 26,27 . This result is also in keeping with previous work that sampled microscale epileptic activity using high-density μECoG arrays which revealed a striking heterogeneity in the spatio-temporal dynamics of interictal events 48,49 . Importantly, in that work, microseizures were most often observed occurring on just one to two electrodes spaced 750 μm apart and were not visible on neighboring electrodes.…”

Section: Discussionsupporting

confidence: 91%

“…This result is in keeping with previous work that sampled microscale epileptic activity using high-density µECoG arrays, which revealed a striking heterogeneity in the spatiotemporal dynamics of interictal events 45,46 . Importantly, microseizures were observed occurring on just two electrodes spaced 750 µm apart, and were not visible on neighboring electrodes.…”

Section: Discussionsupporting

confidence: 91%

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High-resolution neural recordings improve the accuracy of speech decoding

Duraivel

Rahimpour

Chiang

et al. 2022

Preprint

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Patients suffering from debilitating neurodegenerative diseases often lose the ability to communicate, detrimentally affecting their quality of life. One promising solution to restore communication is to decode signals directly from the brain to enable neural speech prostheses. However, decoding has been limited by coarse recordings, which inadequately capture the rich spatio-temporal structure of human brain signals. To resolve this limitation, we performed novel high-resolution, micro-electrocorticographic (µECoG) neural recordings during speech production. We obtained neural signals with 56× spatial resolution and 2.5× higher signal-to-noise ratio compared to standard invasive recordings. This increased signal quality nearly doubled decoding accuracy compared to standard intracranial signals. Accurate decoding was dependent on the high-spatial resolution of the neural interface. Further, non-linear decoding models designed to utilize enhanced spatio-temporal neural information produced better results than standard techniques. We show for the first time that micro-scale neural interfaces can enable high-quality speech decoding for neural speech prostheses.

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Section: Discussionsupporting

confidence: 92%

Section: Discussionsupporting

confidence: 91%

Section: Discussionsupporting

confidence: 91%

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High-resolution neural recordings improve the accuracy of speech decoding

Duraivel

Rahimpour

Chiang

et al. 2022

Preprint

Self Cite

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“…[10][11][12][13] These micro-ECoG (μECoG) arrays with micro-scale spatial resolution (<1 mm) have become an enabling technology for neuroscience research, providing access to localized information not available with standard methods. [12][13][14][15][16][17][18] For instance, μECoG arrays have revealed the possibility of capturing action potentials from the surface of the human cortex with nonpenetrating electrodes, [12] as well as other novel cortical signals not locked to rhythmic brain activity. [14] Furthermore, their highresolution and broad-area coverage allows for the exploration of neural processing and functional interactions across local and broadly distributed networks during different stages of neural computation.…”

Section: Introductionmentioning

confidence: 99%

“…In the context of drug-resistant epilepsy, high-channel count arrays could significantly improve the delineation of functional and pathological tissue boundaries for surgical recession by offering more refined biomarkers, such as microscale seizures and high-frequency oscillations, not detectable with clinical ECoG grids. [15][16][17] Additionally, these arrays hold the potential to significantly enhance the performance of future brain-computer interface systems. For example, advanced μECoG arrays have been instrumental in the development of high-performance speech neuroprostheses, as their broad cortical coverage and high spatial density have proven essential in improving speech decoding from articulatory vocaltract representations distributed throughout the sensorimotor cortex.…”

Section: Introductionmentioning

confidence: 99%

Multiplexed Surface Electrode Arrays Based on Metal Oxide Thin‐Film Electronics for High‐Resolution Cortical Mapping

Londoño‐Ramírez,

Huang,

Cools

et al. 2023

Advanced Science

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Electrode grids are used in neuroscience research and clinical practice to record electrical activity from the surface of the brain. However, existing passive electrocorticography (ECoG) technologies are unable to offer both high spatial resolution and wide cortical coverage, while ensuring a compact acquisition system. The electrode count and density are restricted by the fact that each electrode must be individually wired. This work presents an active micro‐electrocorticography (µECoG) implant that tackles this limitation by incorporating metal oxide thin‐film transistors (TFTs) into a flexible electrode array, allowing to address multiple electrodes through a single shared readout line. By combining the array with an incremental‐ΔΣ readout integrated circuit (ROIC), the system is capable of recording from up to 256 electrodes virtually simultaneously, thanks to the implemented 16:1 time‐division multiplexing scheme, offering lower noise levels than existing active µECoG arrays. In vivo validation is demonstrated acutely in mice by recording spontaneous activity and somatosensory evoked potentials over a cortical surface of ≈8×8 mm2. The proposed neural interface overcomes the wiring bottleneck limiting ECoG arrays, holding promise as a powerful tool for improved mapping of the cerebral cortex and as an enabling technology for future brain‐machine interfaces.

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