Bi-directional brain-computer interfaces (BCIs) require simultaneous stimulation and recording to achieve closed-loop operation. It is therefore important that the interface be able to distinguish between neural signals of interest and stimulation artifacts. Current bi-directional BCIs address this problem by temporally multiplexing stimulation and recording. This approach, however, is suboptimal in many BCI applications. Alternative artifact mitigation methods can be devised by investigating the mechanics of artifact propagation. To characterize stimulation artifact behaviors, we collected and analyzed electrocorticography (ECoG) data from eloquent cortex mapping. Ratcheting and phase-locking of stimulation artifacts were observed, as well as dipole-like properties. Artifacts as large as ±1,100 μV appeared as far as 15-37 mm away from the stimulating channel when stimulating at 10 mA. Analysis also showed that the majority of the artifact power was concentrated at the stimulation pulse train frequency (50 Hz) and its super-harmonics (100, 150, 200 Hz). Lower frequencies (0-32 Hz) experienced minimal artifact contamination. These findings could inform the design of future bi-directional ECoG-based BCIs.
more »
« less
Artifact propagation in electrocorticography stimulation
Introduction:Current brain-computer interfaces (BCIs) primarily rely on visual feedback. However, visual
feedback may not be sufficient for applications such as movement restoration, where somatosensory
feedback plays a crucial role. For electrocorticography (ECoG)-based BCIs, somatosensory feedback can
be elicited by cortical surface electro-stimulation [1]. However, simultaneous cortical stimulation and
recording is challenging due to stimulation artifacts. Depending on the orientation of stimulating
electrodes, their distance to the recording site, and the stimulation intensity, these artifacts may
overwhelm the neural signals of interest and saturate the recording bioamplifiers, making it impossible
to recover the underlying information [2]. To understand how these factors affect artifact propagation,
we performed a preliminary characterization of ECoG signals during cortical
stimulation.Materials/Methods/ResultsECoG electrodes were implanted in a 39-year old epilepsy
patient as shown in Fig. 1. Pairs of adjacent electrodes were stimulated as a part of language cortical
mapping. For each stimulating pair, a charge-balanced biphasic square pulse train of current at 50 Hz
was delivered for five seconds at 2, 4, 6, 8 and 10 mA. ECoG signals were recorded at 512 Hz. The signals
were then high-pass filtered (≥1.5 Hz, zero phase), and the 5-second stimulation epochs were
segmented. Within each epoch, artifact-induced peaks were detected for each electrode, except the
stimulating pair, where signals were clipped due to amplifier saturation. These peaks were phase-locked
across electrodes and were 20 ms apart, thus matching the pulse train frequency. The response was
characterized by calculating the median peak within the 5-second epochs. Fig. 1 shows a representative
response of the right temporal grid (RTG), with the stimulation channel at RTG electrodes 14 and 15. It
also shows a hypothetical amplifier saturation contour of an implantable, bi-directional, ECoG-based BCI
prototype [2], assuming the supply voltage of 2.2 V and a gain of 66 dB. Finally, we quantify the worstcase
scenario by calculating the largest distance between the saturation contour and the midpoint of
each stimulating channel.Discussion:Our results indicate that artifact propagation follows a dipole
potential distribution with the extent of the saturation region (the interior of the white contour)
proportional to the stimulation amplitude. In general, the artifacts propagated farthest when a 10 mA
current was applied with the saturation regions extending from 17 to 32 mm away from the midpoint of
the dipole. Consistent with the electric dipole model, this maximum spread happened along the
direction of the dipole moment. An exception occurred at stimulation channel RTG11-16, for which an
additional saturation contour emerged away from the dipole contour (not shown), extending the
saturation region to 41 mm. Also, the worst-case scenario was observed at 6 mA stimulation amplitude.
This departure could be a sign of a nonlinear, switch-like behavior, wherein additional conduction
pathways could become engaged in response to sufficiently high stimulation.Significance:While ECoG
stimulation is routinely performed in the clinical setting, quantitative studies of the resulting signals are
lacking. Our preliminary study demonstrates that stimulation artifacts largely obey dipole distributions,
suggesting that the dipole model could be used to predict artifact propagation. Further studies are
necessary to ascertain whether these results hold across other subjects and combinations of
stimulation/recording grids. Once completed, these studies will reveal practical design constraints for
future implantable bi-directional ECoG-based BCIs. These include parameters such as the distances
between and relative orientations of the stimulating and recording electrodes, the choice of the
stimulating electrodes, the optimal placement of the reference electrode, and the maximum stimulation
amplitude. These findings would also have important implications for the design of custom, low-power bioamplifiers for implantable bi-directional ECoG-based BCIs.References:[1] Hiremath, S. V., et al.
"Human perception of electrical stimulation on the surface of somatosensory cortex." PloS one 12.5
(2017): e0176020.[2] Rouse, A. G., et al. "A chronic generalized bi-directional brain-machine interface."
Journal of Neural Engineering 8.3 (2011): 036018
more »
« less
- Award ID(s):
- 1646275
- NSF-PAR ID:
- 10108390
- Date Published:
- Journal Name:
- Seventh International BCI Meeting, Abstract Book
- Page Range / eLocation ID:
- 220 - 222
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
More Like this
-
-
Introduction Bi-directional brain-computer interfaces (BD-BCI) to restore movement and sensation must achieve concurrent operation of recording and decoding of motor commands from the brain and stimulating the brain with somatosensory feedback. Methods A custom programmable direct cortical stimulator (DCS) capable of eliciting artificial sensorimotor response was integrated into an embedded BCI system to form a safe, independent, wireless, and battery powered testbed to explore BD-BCI concepts at a low cost. The BD-BCI stimulator output was tested in phantom brain tissue by assessing its ability to deliver electrical stimulation equivalent to an FDA-approved commercial electrical cortical stimulator. Subsequently, the stimulator was tested in an epilepsy patient with subcortical electrocorticographic (ECoG) implants covering the sensorimotor cortex to assess its ability to elicit equivalent responses as the FDA-approved counterpart. Additional safety features (impedance monitoring, artifact mitigation, and passive and active charge balancing mechanisms) were also implemeneted and tested in phantom brain tissue. Finally, concurrent operation with interleaved stimulation and BCI decoding was tested in a phantom brain as a proof-of-concept operation of BD-BCI system. Results The benchtop prototype BD-BCI stimulator's basic output features (current amplitude, pulse frequency, pulse width, train duration) were validated by demonstrating the output-equivalency to an FDA-approved commercial cortical electrical stimulator ( R 2 > 0.99). Charge-neutral stimulation was demonstrated with pulse-width modulation-based correction algorithm preventing steady state voltage deviation. Artifact mitigation achieved a 64.5% peak voltage reduction. Highly accurate impedance monitoring was achieved with R 2 > 0.99 between measured and actual impedance, which in-turn enabled accurate charge density monitoring. An online BCI decoding accuracy of 93.2% between instructional cues and decoded states was achieved while delivering interleaved stimulation. The brain stimulation mapping via ECoG grids in an epilepsy patient showed that the two stimulators elicit equivalent responses. Significance This study demonstrates clinical validation of a fully-programmable electrical stimulator, integrated into an embedded BCI system. This low-cost BD-BCI system is safe and readily applicable as a testbed for BD-BCI research. In particular, it provides an all-inclusive hardware platform that approximates the limitations in a near-future implantable BD-BCI. This successful benchtop/human validation of the programmable electrical stimulator in a BD-BCI system is a critical milestone toward fully-implantable BD-BCI systems.more » « less
-
more » « less
Cortical stimulation
via electrocorticography (ECoG) may be an effective method for inducing artificial sensation in bi-directional brain-computer interfaces (BD-BCIs). However, strong electrical artifacts caused by electrostimulation may significantly degrade or obscure neural information. A detailed understanding of stimulation artifact propagation through relevant tissues may improve existing artifact suppression techniques or inspire the development of novel artifact mitigation strategies. Our work thus seeks to comprehensively characterize and model the propagation of artifacts in subdural ECoG stimulation. To this end, we collected and analyzed data from eloquent cortex mapping procedures of four subjects with epilepsy who were implanted with subdural ECoG electrodes. From this data, we observed that artifacts exhibited phase-locking and ratcheting characteristics in the time domain across all subjects. In the frequency domain, stimulation caused broadband power increases, as well as power bursts at the fundamental stimulation frequency and its super-harmonics. The spatial distribution of artifacts followed the potential distribution of an electric dipole with a median goodness-of-fit ofR 2= 0.80 across all subjects and stimulation channels. Artifacts as large as ±1,100 μV appeared anywhere from 4.43 to 38.34 mm from the stimulation channel. These temporal, spectral and spatial characteristics can be utilized to improve existing artifact suppression techniques, inspire new strategies for artifact mitigation, and aid in the development of novel cortical stimulation protocols. Taken together, these findings deepen our understanding of cortical electrostimulation and provide critical design specifications for future BD-BCI systems. -
Fully-implantable, bi-directional brain-computer interfaces (BCIs) necessitate simultaneous cortical recording and stimulation. This is challenging since electrostimulation of cortical tissue typically causes strong artifacts that may saturate ultra-low power (ULP) analog front-ends of fully-implantable BCIs. To address this problem, we propose an efficient hardware-based method for artifact suppression that employs an auxiliary stimulator with polarity opposite to that of the primary stimulator. The feasibility of this method was explored first in simulations, and then experimentally with brain phantom tissue and electrocorticogram (ECoG) electrode grids. We find that the canceling stimulator can reduce stimulation artifacts below the saturation limit of a typical ULP front-end, while delivering only ~10% of the primary stimulator's voltage.more » « less
-
more » « less
Abstract Objective. Invasive brain–computer interfaces (BCIs) have shown promise in restoring motor function to those paralyzed by neurological injuries. These systems also have the ability to restore sensation via cortical electrostimulation. Cortical stimulation produces strong artifacts that can obscure neural signals or saturate recording amplifiers. While front-end hardware techniques can alleviate this problem, residual artifacts generally persist and must be suppressed by back-end methods.Approach. We have developed a technique based on pre-whitening and null projection (PWNP) and tested its ability to suppress stimulation artifacts in electroencephalogram (EEG), electrocorticogram (ECoG) and microelectrode array (MEA) signals from five human subjects.Main results. In EEG signals contaminated by narrow-band stimulation artifacts, the PWNP method achieved average artifact suppression between 32 and 34 dB, as measured by an increase in signal-to-interference ratio. In ECoG and MEA signals contaminated by broadband stimulation artifacts, our method suppressed artifacts by 78%–80% and 85%, respectively, as measured by a reduction in interference index. When compared to independent component analysis, which is considered the state-of-the-art technique for artifact suppression, our method achieved superior results, while being significantly easier to implement.Significance. PWNP can potentially act as an efficient method of artifact suppression to enable simultaneous stimulation and recording in bi-directional BCIs to biomimetically restore motor function.
- Free Publicly Accessible Full Text
-
Accepted Manuscript1.0
- Conference Paper:
- The DOI is not currently available.
