Optimal Multichannel Artifact Prediction and Removal for Brain Machine Interfaces and Neural Prosthetics

M, Sadeghi Najafabadi; Chen, Longtu; Dutta, Kelsey; Norris, Ashley; Feng, Bin; Schnupp, JW; Roßkothen-Kuhl, Nicole; Read, Heather L.; Escabı́, Monty A.

doi:10.1101/809640

Cited by 1 publication

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References 26 publications

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“…The authors would like to thank Dr. A. Buck and Ms. Kongyan Li for their assistance with the acquisition of the binaural cochlear implant data presented in this manuscript. An earlier version of this manuscript has been released as a Pre-Print at BioRxiv.org (Sadeghi et al, 2019).…”

Section: Acknowledgmentsmentioning

confidence: 99%

Optimal Multichannel Artifact Prediction and Removal for Neural Stimulation and Brain Machine Interfaces

et al. 2020

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Neural implants that deliver multi-site electrical stimulation to the nervous systems are no longer the last resort but routine treatment options for various neurological disorders. Multi-site electrical stimulation is also widely used to study nervous system function and neural circuit transformations. These technologies increasingly demand dynamic electrical stimulation and closed-loop feedback control for real-time assessment of neural function, which is technically challenging since stimulus-evoked artifacts overwhelm the small neural signals of interest. We report a novel and versatile artifact removal method that can be applied in a variety of settings, from single-to multisite stimulation and recording and for current waveforms of arbitrary shape and size. The method capitalizes on linear electrical coupling between stimulating currents and recording artifacts, which allows us to estimate a multi-channel linear Wiener filter to predict and subsequently remove artifacts via subtraction. We confirm and verify the linearity assumption and demonstrate feasibility in a variety of recording modalities, including in vitro sciatic nerve stimulation, bilateral cochlear implant stimulation, and multi-channel stimulation and recording between the auditory midbrain and cortex. We demonstrate a vast enhancement in the recording quality with a typical artifact reduction of 25−40 dB. The method is efficient and can be scaled to arbitrary number of stimulus and recording sites, making it ideal for applications in large-scale arrays, closed-loop implants, and high-resolution multi-channel brain-machine interfaces.

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Section: Acknowledgmentsmentioning

confidence: 99%