Physiological Artifacts and the Implications for Brain-Machine-Interface Design

The accurate measurement of brain activity by Brain-Machine-Interfaces (BMI) and closed-loop Deep Brain Stimulators (DBS) is one of the most important steps in communicating between the brain and subsequent processing blocks. In conventional chest-mounted systems, frequently used in DBS, a significant amount of artifact can be induced in the sensing interface, often as a common-mode signal applied between the case and the sensing electrodes. Attenuating this common-mode signal can be a serious challenge in these systems due to finite common-mode-rejection-ratio (CMRR) capability in the interface. Emerging BMI and DBS devices are being developed which can mount on the skull. Mounting the system on the cranial region can potentially suppress these induced physiological signals by limiting the artifact amplitude. In this study, we model the effect of artifacts by focusing on cardiac activity, using a current- source dipole model in a torso-shaped volume conductor. Performing finite element simulation with the different DBS architectures, we estimate the ECG common mode artifacts for several device architectures. Using this model helps define the overall requirements for the total system CMRR to maintain resolution of brain activity. The results of the simulations estimate that the cardiac artifacts for skull-mounted systems will have a significantly lower effect than non-cranial systems that include the pectoral region. It is expected that with a pectoral mounted device, a minimum of 60-80 dB CMRR is required to suppress the ECG artifact, depending on device placement relative to the cardiac dipole, while in cranially mounted devices, a 0 dB CMRR is sufficient, in the worst-case scenario. In addition, the model suggests existing commercial devices could optimize performance with a right-hand side placement. The methods used for estimating cardiac artifacts can be extended to other sources such as motion/muscle sources. The susceptibility of the device to artifacts has significant implications for the practical translation of closed-loop DBS and BMI, including the choice of biomarkers, the system design requirements, and the surgical placement of the device relative to artifact sources.

[1]  Marie-Claude Trudel,et al.  Simulation of QRST integral maps with a membrane-based computer heart model employing parallel processing , 2004, IEEE Transactions on Biomedical Engineering.

[2]  Robert A Gaunt,et al.  Artifact-free recordings in human bidirectional brain–computer interfaces , 2018, Journal of neural engineering.

[3]  F. Amzica,et al.  Electropolymerized Poly(3,4-ethylenedioxythiophene) (PEDOT) Coatings for Implantable Deep-Brain-Stimulating Microelectrodes. , 2019, ACS applied materials & interfaces.

[4]  Hadi Veladi,et al.  Measurement of Transcranial Magnetic Stimulation Resolution in 3-D Spaces , 2018 .

[5]  Alexander R. Kent,et al.  Measurement of Evoked Potentials During Thalamic Deep Brain Stimulation , 2015, Brain Stimulation.

[6]  Vincent Jacquemet,et al.  Modeling left and right atrial contributions to the ECG: A dipole-current source approach , 2015, Comput. Biol. Medicine.

[7]  A.-T. Avestruz,et al.  A 2 $\mu\hbox{W}$ 100 nV/rtHz Chopper-Stabilized Instrumentation Amplifier for Chronic Measurement of Neural Field Potentials , 2007, IEEE Journal of Solid-State Circuits.

[8]  A. Priori,et al.  An electronic device for artefact suppression in human local field potential recordings during deep brain stimulation , 2007, Journal of neural engineering.

[9]  Angelo Brayner,et al.  Classical and Modern Features for Interpretation of ECG Signal , 2019, Developments and Applications for ECG Signal Processing.

[10]  Benjamin C. Johnson,et al.  Toward true closed-loop neuromodulation: artifact-free recording during stimulation , 2018, Current Opinion in Neurobiology.

[11]  Majid Memarian Sorkhabi,et al.  Emotion Detection from EEG signals with Continuous Wavelet Analyzing , 2014 .

[12]  L. Fekete,et al.  Diamond/Porous Titanium Nitride Electrodes With Superior Electrochemical Performance for Neural Interfacing , 2018, Front. Bioeng. Biotechnol..

[13]  Hartmut Bossel,et al.  Modeling and simulation , 1994 .

[14]  Hugh J. McDermott,et al.  Deep brain stimulation for Parkinson's disease modulates high-frequency evoked and spontaneous neural activity , 2019, Neurobiology of Disease.

[15]  D. Geselowitz,et al.  DIPOLE THEORY IN ELECTROCARDIOGRAPHY. , 1964, The American journal of cardiology.

[16]  Shuichi Nishio,et al.  Neuromagnetic Decoding of Simultaneous Bilateral Hand Movements for Multidimensional Brain–Machine Interfaces , 2018, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[17]  Hadi Veladi,et al.  Deep-Brain Transcranial Stimulation: A Novel Approach for High 3-D Resolution , 2017, IEEE Access.

[18]  Felice T. Sun,et al.  The RNS System: responsive cortical stimulation for the treatment of refractory partial epilepsy , 2014, Expert review of medical devices.

[19]  A. Priori,et al.  Adaptive deep brain stimulation (aDBS) controlled by local field potential oscillations , 2013, Experimental Neurology.

[20]  G. Calcagnini,et al.  ANMCO/AIIC/SIT Consensus Information Document: definition, precision, and suitability of electrocardiographic signals of electrocardiographs, ergometry, Holter electrocardiogram, telemetry, and bedside monitoring systems , 2017, European heart journal supplements : journal of the European Society of Cardiology.

[21]  Single moving dipole obtained from magnetic field of the heart in patients with left ventricular hypertrophy , 1992, Clinical cardiology.

[22]  P. Brown,et al.  Adaptive Deep Brain Stimulation In Advanced Parkinson Disease , 2013, Annals of neurology.

[23]  Benjamin H. Brinkmann,et al.  A Chronically Implantable Neural Coprocessor for Investigating the Treatment of Neurological Disorders , 2018, IEEE Transactions on Biomedical Circuits and Systems.

[24]  Timothy Denison,et al.  Temporally Interfering TMS: Focal and Dynamic Stimulation Location , 2020, 2020 42nd Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC).

[25]  Tipu Z. Aziz,et al.  DyNeuMo Mk-1: A Fully-Implantable, Motion-Adaptive Neurostimulator with Configurable Response Algorithms , 2020, bioRxiv.