Your search keyword '"Chad E. Bouton"' showing total 33 results

1. Neuroprosthetic-enabled control of graded arm muscle contraction in a paralyzed human

Author

David A. Friedenberg, Michael A. Schwemmer, Andrew J. Landgraf, Nicholas V. Annetta, Marcia A. Bockbrader, Chad E. Bouton, Mingming Zhang, Ali R. Rezai, W. Jerry Mysiw, Herbert S. Bresler, and Gaurav Sharma

Subjects

Medicine, Science

Abstract

Abstract Neuroprosthetics that combine a brain computer interface (BCI) with functional electrical stimulation (FES) can restore voluntary control of a patients’ own paralyzed limbs. To date, human studies have demonstrated an “all-or-none” type of control for a fixed number of pre-determined states, like hand-open and hand-closed. To be practical for everyday use, a BCI-FES system should enable smooth control of limb movements through a continuum of states and generate situationally appropriate, graded muscle contractions. Crucially, this functionality will allow users of BCI-FES neuroprosthetics to manipulate objects of different sizes and weights without dropping or crushing them. In this study, we present the first evidence that using a BCI-FES system, a human with tetraplegia can regain volitional, graded control of muscle contraction in his paralyzed limb. In addition, we show the critical ability of the system to generalize beyond training states and accurately generate wrist flexion states that are intermediate to training levels. These innovations provide the groundwork for enabling enhanced and more natural fine motor control of paralyzed limbs by BCI-FES neuroprosthetics.

Published

2017

2. Neuroprotective Effects of Trigeminal Nerve Stimulation in Severe Traumatic Brain Injury

Author

Amrit Chiluwal, Raj K. Narayan, Wayne Chaung, Neal Mehan, Ping Wang, Chad E. Bouton, Eugene V. Golanov, and Chunyan Li

Subjects

Medicine, Science

Abstract

Abstract Following traumatic brain injury (TBI), ischemia and hypoxia play a major role in further worsening of the damage, a process referred to as ‘secondary injury’. Protecting neurons from causative factors of secondary injury has been the guiding principle of modern TBI management. Stimulation of trigeminal nerve induces pressor response and improves cerebral blood flow (CBF) by activating the rostral ventrolateral medulla. Moreover, it causes cerebrovasodilation through the trigemino-cerebrovascular system and trigemino-parasympathetic reflex. These effects are capable of increasing cerebral perfusion, making trigeminal nerve stimulation (TNS) a promising strategy for TBI management. Here, we investigated the use of electrical TNS for improving CBF and brain oxygen tension (PbrO2), with the goal of decreasing secondary injury. Severe TBI was produced using controlled cortical impact (CCI) in a rat model, and TNS treatment was delivered for the first hour after CCI. In comparison to TBI group, TBI animals with TNS treatment demonstrated significantly increased systemic blood pressure, CBF and PbrO2 at the hyperacute phase of TBI. Furthermore, rats in TNS-treatment group showed significantly reduced brain edema, blood-brain barrier disruption, lesion volume, and brain cortical levels of TNF-α and IL-6. These data provide strong early evidence that TNS could be an effective neuroprotective strategy.

Published

2017

3. Evoking highly focal percepts in the fingertips through targeted stimulation of sulcal regions of the brain for sensory restoration

Author

Matthew F. Glasser, Chad E. Bouton, Nikunj Bhagat, Elizabeth Espinal, Santosh Chandrasekaran, Richard Ramdeo, Stephan Bickel, Noah Markowitz, Junqian Xu, Ashesh D. Mehta, Jose L. Herrero, and Joo Won Kim

Subjects

Biophysics, Neurosciences. Biological psychiatry. Neuropsychiatry, Stimulation, Sensory system, Fingertip representation, Somatosensory system, Sensory restoration, Stereoelectroencephalography, Sensation, Humans, Medicine, Electrocorticography, Brain–computer interface, Sensory stimulation therapy, medicine.diagnostic_test, Stereoelectroencephalography depth electrodes, business.industry, General Neuroscience, Somatosensory Cortex, Hand, Electric Stimulation, Electrodes, Implanted, nervous system, Brain-computer interface, Touch, Neurology (clinical), Sensory percepts, business, Neuroscience, RC321-571

Abstract

Background Paralysis and neuropathy, affecting millions of people worldwide, can be accompanied by significant loss of somatosensation. With tactile sensation being central to achieving dexterous movement, brain-computer interface (BCI) researchers have used intracortical and cortical surface electrical stimulation to restore somatotopically-relevant sensation to the hand. However, these approaches are restricted to stimulating the gyral areas of the brain. Since representation of distal regions of the hand extends into the sulcal regions of human primary somatosensory cortex (S1), it has been challenging to evoke sensory percepts localized to the fingertips. Objective/hypothesis Targeted stimulation of sulcal regions of S1, using stereoelectroencephalography (SEEG) depth electrodes, can evoke focal sensory percepts in the fingertips. Methods Two participants with intractable epilepsy received cortical stimulation both at the gyri via high-density electrocorticography (HD-ECoG) grids and in the sulci via SEEG depth electrode leads. We characterized the evoked sensory percepts localized to the hand. Results We show that highly focal percepts can be evoked in the fingertips of the hand through sulcal stimulation. fMRI, myelin content, and cortical thickness maps from the Human Connectome Project elucidated specific cortical areas and sub-regions within S1 that evoked these focal percepts. Within-participant comparisons showed that percepts evoked by sulcal stimulation via SEEG electrodes were significantly more focal (80% less area; p = 0.02) and localized to the fingertips more often, than by gyral stimulation via HD-ECoG electrodes. Finally, sulcal locations with consistent modulation of high-frequency neural activity during mechanical tactile stimulation of the fingertips showed the same somatotopic correspondence as cortical stimulation. Conclusions Our findings indicate minimally invasive sulcal stimulation via SEEG electrodes could be a clinically viable approach to restoring sensation.

Published

2021

4. Case Study: Mapping Evoked Fields in Primary Motor and Sensory Areas via Magnetoencephalography in Tetraplegia

Author

Stephen T. Foldes, Santosh Chandrasekaran, Joseph Camerone, James Lowe, Richard Ramdeo, John Ebersole, and Chad E. Bouton

Subjects

magnetoencephalography, Neuroprosthetics, medicine.diagnostic_test, business.industry, Brain activity and meditation, medicine.medical_treatment, neuroprosthetics, Sensory system, paralysis, Magnetoencephalography, medicine.disease, Somatosensory system, Neurology, brain–computer interfaces folds, Medicine, Neurology. Diseases of the nervous system, Neurology (clinical), RC346-429, business, sensorimotor cortex, Neuroscience, Tetraplegia, Craniotomy, Brain–computer interface

Abstract

Devices interfacing with the brain through implantation in cortical or subcortical structures have great potential for restoration and rehabilitation in patients with sensory or motor dysfunction. Typical implantation surgeries are planned based on maps of brain activity generated from intact function. However, mapping brain activity for planning implantation surgeries is challenging in the target population due to abnormal residual function and, increasingly often, existing MRI-incompatible implanted hardware. Here, we present methods and results for mapping impaired somatosensory and motor function in an individual with paralysis and an existing brain–computer interface (BCI) device. Magnetoencephalography (MEG) was used to directly map the neural activity evoked during transcutaneous electrical stimulation and attempted movement of the impaired hand. Evoked fields were found to align with the expected anatomy and somatotopic organization. This approach may be valuable for guiding implants in other applications, such as cortical stimulation for pain and to improve implant targeting to help reduce the craniotomy size.

Published

2021

5. Closed-loop neuromuscular electrical stimulation using feedforward-feedback control and textile electrodes to regulate grasp force in quadriplegia

Author

Chad E. Bouton, Kevin King, Richard Ramdeo, Todd J. Levy, John Ciancibello, Malgorzata Straka, Subash Padmanaban, and Milad Alizadeh Meghrazi

Subjects

medicine.medical_specialty, Steady state (electronics), lcsh:Medical technology, Computer science, Feedback control, 0206 medical engineering, GRASP, Short Report, Feed forward, Stimulation, 02 engineering and technology, 020601 biomedical engineering, Contact force, body regions, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, lcsh:R855-855.5, medicine, General Earth and Planetary Sciences, Closed loop, 030217 neurology & neurosurgery, Functional movement, General Environmental Science

Abstract

Background Transcutaneous neuromuscular electrical stimulation is routinely used in physical rehabilitation and more recently in brain-computer interface applications for restoring movement in paralyzed limbs. Due to variable muscle responses to repeated or sustained stimulation, grasp force levels can change significantly over time. Here we develop and assess closed-loop methods to regulate individual finger forces to facilitate functional movement. We combined this approach with custom textile-based electrodes to form a light-weight, wearable device and evaluated in paralyzed study participants. Methods A textile-based electrode sleeve was developed by the study team and Myant, Corp. (Toronto, ON, Canada) and evaluated in a study involving three able-body participants and two participants with quadriplegia. A feedforward-feedback control structure was designed and implemented to accurately maintain finger force levels in a quadriplegic study participant. Results Individual finger flexion and extension movements, along with functional grasping, were evoked during neuromuscular electrical stimulation. Closed-loop control methods allowed accurate steady state performance ( Conclusions Textile-based electrodes were identified to be a feasible alternative to conventional electrodes and facilitated individual finger movement and functional grasping. Furthermore, closed-loop methods demonstrated accurate control of individual finger flexion force. This approach may be a viable solution for enabling grasp force regulation in quadriplegia. Trial registration NCT, NCT03385005. Registered Dec. 28, 2017

Published

2019

6. Mapping evoked fields in primary motor and sensory areas via magnetoencephalography in tetraplegia

Author

Stephen T. Foldes, Chad E. Bouton, John S. Ebersole, James Lowe, Joseph Camerone, Santosh Chandrasekaran, and Richard Ramdeo

Subjects

medicine.diagnostic_test, Brain activity and meditation, business.industry, medicine.medical_treatment, Stimulation, Sensory system, Magnetoencephalography, Somatosensory system, medicine.disease, medicine, business, Neuroscience, Tetraplegia, Craniotomy, Brain–computer interface

Abstract

1AbstractDevices interfacing with the brain through implantation in cortical or subcortical structures have great potential for restoration and rehabilitation in patients with sensory or motor dysfunction. Typical implantation surgeries are planned based on maps of brain activity generated from intact function. However, mapping brain activity for planning implantation surgeries is challenging in the target population due to abnormal residual function and, increasingly often, existing MRI-incompatible implanted hardware. Here, we present methods and results for mapping impaired somatosensory and motor function in an individual with paralysis and an existing brain-computer interface (BCI) device. Magnetoencephalography (MEG) was used to directly map the neural activity evoked during transcutaneous electrical stimulation and attempted movement of the impaired hand. Evoked fields were found to align with the expected anatomy and somatotopic organization. This approach may be valuable for guiding implants in other applications, such as cortical stimulation for pain and to improve implant targeting to help reduce the craniotomy size.

Published

2021

7. Decoding Neural Activity in Sulcal and White Matter Areas of the Brain to Accurately Predict Individual Finger Movement and Tactile Stimuli of the Human Hand

Author

Santosh Chandrasekaran, Ashesh D. Mehta, Noah Markowitz, Stephan Bickel, Matthew F. Glasser, Joo Won Kim, Richard Ramdeo, Junqian Xu, Nikunj Bhagat, Elizabeth Espinal, Chad E. Bouton, and Jose L. Herrero

Subjects

medicine.diagnostic_test, business.industry, Computer science, Deep learning, Feature selection, Pattern recognition, Sensory system, Somatosensory system, Stereoelectroencephalography, Recurrent neural network, medicine, Artificial intelligence, business, Electrocorticography, Brain–computer interface

Abstract

Millions of people worldwide suffer motor or sensory impairment due to stroke, spinal cord injury, multiple sclerosis, traumatic brain injury, diabetes, and motor neuron diseases such as ALS (amyotrophic lateral sclerosis). A brain-computer interface (BCI), which links the brain directly to a computer, offers a new way to study the brain and potentially restore these losses in patients living with debilitating conditions. One of the challenges currently facing BCI technology, however, is how to minimize surgical risk. Minimally invasive techniques, such as stereoelectroencephalography (SEEG) have become more widely used in clinical applications since they can lead to fewer complications. SEEG electrodes also give access to sulcal and white matter areas of the brain but have not been widely studied in brain-computer interfaces. We therefore investigated the viability of using SEEG electrodes in a BCI for recording and decoding neural signals related to movement and the sense of touch and compared its performance to electrocorticography electrodes (ECoG) placed on gyri. Initial poor decoding performance and the observation that most neural modulation patterns were highly variable trial-to-trial and transient (significantly shorter than the sustained finger movements studied), led to the development of a feature selection method based on a repeatability metric using temporal correlation. An algorithm based on temporal correlation was developed to isolate features that consistently repeated (required for accurate decoding) and possessed information content related to movement or touch-related stimuli. We subsequently used these features, along with deep learning methods, to automatically classify various motor and sensory events for individual fingers with high accuracy. Repeating features were found in sulcal, gyral, and white matter areas and were predominantly phasic or phasic-tonic across a wide frequency range for both HD (high density) ECoG and SEEG recordings. These findings motivated the use of long short-term memory (LSTM) recurrent neural networks (RNNs) which are well-suited to handling both transient and sustained input features. Combining temporal correlation-based feature selection with LSTM yielded decoding accuracies of up to 92.04 +/-1.51% for hand movements, up to 91.69 +/-0.49% for individual finger movements, and up to 80.64 +/-1.64% for focal tactile stimuli to the finger pads and palm while using a relatively small number of SEEG electrodes. These findings may lead to a new class of minimally invasive brain-computer interface systems in the future, increasing its applicability to a wider variety of conditions.

Published

2021

8. Evoking highly focal percepts in the fingertips through targeted stimulation of sulcal regions of the brain for sensory restoration

Author

Richard Ramdeo, Ashesh D. Mehta, Elizabeth Espinal, Chad E. Bouton, Junqian Xu, Nikunj Bhagat, Santosh Chandrasekaran, Stephan Bickel, Jose L. Herrero, Matthew F. Glasser, Noah Markowitz, and Joo Won Kim

Subjects

Functional imaging, Sensory stimulation therapy, medicine.diagnostic_test, business.industry, Sensation, Medicine, Sensory system, Stimulation, business, Somatosensory system, Neuroscience, Electrocorticography, Stereoelectroencephalography

Abstract

Paralysis and neuropathy, affecting millions of people worldwide, can be accompanied by a significant loss of somatosensation. With tactile sensation being central to achieving dexterous movement, brain-computer interface (BCI) researchers have explored the use of intracortical electrical stimulation to restore sensation to the hand. However, current approaches have been restricted to stimulating the gyral areas of the brain while functional imaging suggests that the representation of fingertips lie predominantly in the sulcal regions. Here we show, for the first time, highly focal percepts can be evoked in the fingertips of the hand through electrical stimulation of the sulcal areas of the brain. To this end, we mapped and compared sensations elicited in the hand by stimulating both gyral and sulcal areas of the human primary somatosensory cortex (S1). Two participants with intractable epilepsy were implanted with stereoelectroencephalography (SEEG) and high-density electrocorticography (HD-ECoG) electrodes in S1 guided by high-resolution functional imaging. Using myelin content and cortical thickness maps developed by the Human Connectome Project, we elucidated the specific sub-regions of S1 where focal percepts were evoked. Within-participant comparisons showed that sulcal stimulation using SEEG electrodes evoked percepts that are significantly more focal, with 80% less area of spread (p=0.02) and localized to the fingertips more often than in gyral stimulation via HD-ECoG electrodes. Finally, sulcal locations exhibiting repeated modulation patterns of high-frequency neural activity during mechanical tactile stimulation of the hand showed the same somatotopic correspondence as sulcal stimulation. These findings show that minimally-invasive sulcal stimulation could lead to a clinically viable approach to restoring sensation in those living with sensory impairment.SignificanceIntracortical or cortical surface stimulation of the primary somatosensory cortex (S1) offers the promise of restoring somatotopically-relevant sensation in people with sensory impairment. However, evoking percepts in the fingertips has been challenging as their representation has been shown to be predominantly located within sulcal regions of S1 – inaccessible by these stimulation approaches. We evoked highly focal percepts in the fingertips of the hand by stimulating the sulcal regions of S1 in people with intractable epilepsy using stereoelectroencephalography (SEEG) depth electrodes. Sensory percepts in the fingertips were more focal and more frequently evoked by SEEG electrodes than by high-density electrocorticography (HD-ECoG) grids evidenced by within-participant comparisons. Our results suggest that fingertip representations are more readily targeted within the sulcal regions. SEEG electrodes potentially offer a clinically viable approach to access the sulcal regions for sensory neuroprostheses that can aid dexterous motor control.

Published

2020

9. Determining grasp selection from arm trajectories via deep learning to enable functional hand movement in tetraplegia

Author

Richard Ramdeo, Kevin King, Chad E. Bouton, Adam Stein, and Nikunj Bhagat

Subjects

Dynamic time warping, lcsh:Medical technology, Computer science, Wearable, Short Report, Spinal cord injury, Inertial measurement unit, Machine learning, medicine, Computer vision, Tetraplegia, General Environmental Science, Artificial neural network, business.industry, Deep learning, GRASP, medicine.disease, IMU, Neuromuscular stimulation, Recurrent neural network, lcsh:R855-855.5, Trajectory, General Earth and Planetary Sciences, Artificial intelligence, business, Neural networks

Abstract

Background Cervical spinal cord injury severely affects grasping ability of its survivors. Fortunately, many individuals with tetraplegia retain residual arm movements that allow them to reach for objects. We propose a wearable technology that utilizes arm movement trajectory information and deep learning methods to determine grasp selection. Furthermore, we combined this approach with neuromuscular stimulation to determine if self-driven functional hand movement could be enabled in spinal cord injury participants. Methods Two cervical SCI participants performed arbitrary and natural reaching movements toward target objects in three-dimensional space, which were recorded using an inertial sensor worn on their wrist. Time series classifiers were trained to recognize the trajectories using either a Dynamic Time Warping (DTW) algorithm or a Long Short-Term Memory (LSTM) recurrent neural network. As an initial proof-of-concept, we demonstrate real-time classification of the arbitrary movements using DTW only (due to its implementation simplicity), which when used in combination with a high density neuromuscular stimulation sleeve with textile electrodes, enabled participants to perform functional grasping. Results Participants were able to consistently perform arbitrary two-dimensional and three-dimensional arm movements which could be classified with high accuracy. Furthermore, it was found that natural reaching trajectories for two different target objects (requiring two different grasp types) were distinct and also discriminable with high accuracy. In offline comparisons, LSTM (mean accuracies 99%) performed significantly better than DTW (mean accuracies 86 and 83%) for both arbitrary and natural reaching movements, respectively. Type I and II errors occurred more frequently for DTW (up to 60 and 15%, respectively), whereas it stayed under 5% for LSTM. Also, DTW achieved online accuracy of 79%. Conclusions We demonstrate the feasibility of utilizing arm trajectory information to determine grasp selection using a wearable inertial sensor along with DTW and deep learning methods. Importantly, this technology can be successfully used to control neuromuscular stimulation and restore functional independence to individuals living with paralysis. Trial registration NCT, NCT03385005. Registered September 26, 2017

Published

2020

10. Inferring Grasp Intentions from Arm Trajectories via Deep Learning to Enable Functional Movement in Quadriplegia Revised Title Determining Grasp Selection from Arm Trajectories via Deep Learning to Enable Functional Hand Movement in Tetraplegia

Author

Kevin King, Richard Ramdeo, Chad E. Bouton, Nikunj Bhagat, and Adam Stein

Subjects

business.industry, Computer science, Movement (music), Human–computer interaction, Deep learning, GRASP, medicine, Artificial intelligence, medicine.disease, business, Tetraplegia, Selection (genetic algorithm), Functional movement

Abstract

Background: Cervical spinal cord injury severely affects grasping ability of its survivors. Fortunately, many individuals with tetraplegia retain residual arm movements that allow them to reach for objects. We propose a wearable technology that utilizes arm movement trajectory information and deep learning methods to determine grasp selection. Furthermore, we combined this approach with neuromuscular stimulation to determine if self-driven functional hand movement could be enabled in spinal cord injury participants.Methods: Two cervical SCI participants performed arbitrary and natural reaching movements toward target objects in three-dimensional space, which were recorded using an inertial sensor worn on their wrist. Time series classifiers were trained to recognize the trajectories using either a Dynamic Time Warping (DTW) algorithm or a Long Short-Term Memory (LSTM) recurrent neural network. As an initial proof-of-concept, we demonstrate real-time classification of the arbitrary movements using DTW only (due to its implementation simplicity), which when used in combination with a high density neuromuscular stimulation sleeve with textile electrodes, enabled participants to perform functional grasping.Results: Participants were able to consistently perform arbitrary two-dimensional and three-dimensional arm movements which could be classified with high accuracy. Furthermore, it was found that natural reaching trajectories for two different target objects (requiring two different grasp types) were distinct and also discriminable with high accuracy. In offline comparisons, LSTM (mean accuracies 99%) performed significantly better than DTW (mean accuracies 86% and 83%) for both arbitrary and natural reaching movements, respectively. Type I and II errors occurred more frequently for DTW (up to 60% and 15%, respectively), whereas it stayed under 5% for LSTM. Also, DTW achieved online accuracy of 79%. Conclusions: We demonstrate the feasibility of utilizing arm trajectory information to determine grasp selection using a wearable inertial sensor along with DTW and deep learning methods. Importantly, this technology can be successfully used to control neuromuscular stimulation and restore functional independence to individuals living with paralysis.

Published

2020

11. A novel microwire interface for small diameter peripheral nerves in a chronic, awake murine model

Author

Malgorzata Straka, Laura Goldman, Chad E. Bouton, Jessica D. Falcone, Tristan Liu, Harbaljit S. Sohal, Pogue David D, and Loren Rieth

Subjects

Small diameter, 0206 medical engineering, Biomedical Engineering, Action Potentials, Stimulation, 02 engineering and technology, 03 medical and health sciences, Cellular and Molecular Neuroscience, Neural activity, Mice, 0302 clinical medicine, Medicine, Animals, Peripheral Nerves, Wakefulness, business.industry, Cuff electrode, 020601 biomedical engineering, Peripheral, Vagus nerve, Electrodes, Implanted, Disease Models, Animal, Murine model, business, 030217 neurology & neurosurgery, Biomedical engineering

Abstract

OBJECTIVE The vagus nerve has been implicated in a variety of immune responses, and the number of studies using mouse models to unravel key mechanisms has increased. However, as of yet, there is no electrode that can chronically record neural activity from the mouse vagus nerve due to its small diameter. Such recordings are critical to understand the role of these biomarkers for translational research. APPROACH In this study, we developed a methodology for surgically implanting the wrappable microwires onto the vagus nerve of mice. Similar to a cuff electrode, we wrapped de-insulated ends of microwires around the vagus nerve and re-insulated them on the nerve with Kwik-Sil. The recording fidelity of the wrappable microwire on the vagus nerve was validated in an acute, anesthetized model by comparing performance to commercially-available electrodes. A chronic, awake mouse model was then developed to record spontaneous compound action potentials (CAPs). MAIN RESULTS In an acute setting, the wrappable microwire successfully recorded spontaneous CAPs with similar signal-to-noise ratios (SNR) and peak-to-peak amplitude to commercially available electrodes. In chronic, awake recordings, viable SNRs were obtained from the wrappable microwires between 30 and 60 d (n = 8). Weekly impedance measurements showed no correlation with SNR or time, indicating device stability, and the electrodes recorded CAPs for the duration of the recording period. SIGNIFICANCE To the best of our knowledge, this is the first reported chronic, awake neural interface with the mouse vagus nerve. This approach can facilitate clinical translation for bioelectronic medicine in preclinical disease models of interest with the creation of more clinically relevant preclinical models.

Published

2020

12. Transcutaneous auricular vagus nerve stimulation reduces pain and fatigue in patients with systemic lupus erythematosus: a randomised, double-blind, sham-controlled pilot trial

Author

Yemil Atish-Fregoso, Meggan Mackay, Erik Anderson, Sangeeta S. Chavan, Betty Diamond, Chad E. Bouton, Martin Lesser, Cynthia Aranow, Theodoros P. Zanos, Timir Datta-Chaudhuri, and Kevin J. Tracey

Subjects

Adult, Vagus Nerve Stimulation, Visual analogue scale, medicine.medical_treatment, Immunology, Inflammation, Stimulation, Substance P, Pilot Projects, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Rheumatology, Double-Blind Method, Musculoskeletal Pain, medicine, Immunology and Allergy, Humans, Lupus Erythematosus, Systemic, In patient, Fatigue, Aged, Pain Measurement, 030203 arthritis & rheumatology, Lupus erythematosus, business.industry, Middle Aged, medicine.disease, Vagus nerve, Treatment Outcome, chemistry, Anesthesia, Transcutaneous Electric Nerve Stimulation, Female, medicine.symptom, business, 030217 neurology & neurosurgery, Vagus nerve stimulation

Abstract

ObjectivesMusculoskeletal pain and fatigue are common features in systemic lupus erythematosus (SLE). The cholinergic anti-inflammatory pathway is a physiological mechanism diminishing inflammation, engaged by stimulating the vagus nerve. We evaluated the effects of non-invasive vagus nerve stimulation in patients with SLE and with musculoskeletal pain.Methods18 patients with SLE and with musculoskeletal pain ≥4 on a 10 cm Visual Analogue Scale were randomised (2:1) in this double-blind study to receive transcutaneous auricular vagus nerve stimulation (taVNS) or sham stimulation (SS) for 4 consecutive days. Evaluations at baseline, day 5 and day 12 included patient assessments of pain, disease activity (PtGA) and fatigue. Tender and swollen joint counts and the Physician Global Assessment (PGA) were completed by a physician blinded to the patient’s therapy. Potential biomarkers were evaluated.ResultstaVNS and SS were well tolerated. Subjects receiving taVNS had a significant decrease in pain and fatigue compared with SS and were more likely (OR=25, p=0.02) to experience a clinically significant reduction in pain. PtGA, joint counts and PGA also improved. Pain reduction and improvement of fatigue correlated with the cumulative current received. In general, responses were maintained through day 12. Plasma levels of substance P were significantly reduced at day 5 compared with baseline following taVNS but other neuropeptides, serum and whole blood-stimulated inflammatory mediators, and kynurenine metabolites showed no significant change at days 5 or 12 compared with baseline.ConclusiontaVNS resulted in significantly reduced pain, fatigue and joint scores in SLE. Additional studies evaluating this intervention and its mechanisms are warranted.

Published

2020

13. Specific vagus nerve stimulation parameters alter serum cytokine levels in the absence of inflammation

Author

Sangeeta S. Chavan, Tea Tsaava, Harold A. Silverman, Emily Battinelli Masi, Justin Newman, Timir Datta-Chaudhuri, Meghan E. Addorisio, Gavin H Imperato, Kevin J. Tracey, Eric H. Chang, and Chad E. Bouton

Subjects

0301 basic medicine, medicine.medical_specialty, lcsh:Medical technology, Tumor necrosis factor, medicine.medical_treatment, Inflammatory reflex, Stimulation, Proinflammatory cytokine, 03 medical and health sciences, 0302 clinical medicine, Internal medicine, medicine, General Environmental Science, business.industry, Neuromodulation, Symptomatic relief, Neuromodulation (medicine), Vagus nerve, Interleukin-10, 030104 developmental biology, Cytokine, Endocrinology, lcsh:R855-855.5, General Earth and Planetary Sciences, business, 030217 neurology & neurosurgery, Vagus nerve stimulation, Research Article

Abstract

Background Electrical stimulation of peripheral nerves is a widely used technique to treat a variety of conditions including chronic pain, motor impairment, headaches, and epilepsy. Nerve stimulation to achieve efficacious symptomatic relief depends on the proper selection of electrical stimulation parameters to recruit the appropriate fibers within a nerve. Recently, electrical stimulation of the vagus nerve has shown promise for controlling inflammation and clinical trials have demonstrated efficacy for the treatment of inflammatory disorders. This application of vagus nerve stimulation activates the inflammatory reflex, reducing levels of inflammatory cytokines during inflammation. Methods Here, we wanted to test whether altering the parameters of electrical vagus nerve stimulation would change circulating cytokine levels of normal healthy animals in the absence of increased inflammation. To examine this, we systematically tested a set of electrical stimulation parameters and measured serum cytokine levels in healthy mice. Results Surprisingly, we found that specific combinations of pulse width, pulse amplitude, and frequency produced significant increases of the pro-inflammatory cytokine tumor necrosis factor (TNF), while other parameters selectively lowered serum TNF levels, as compared to sham-stimulated mice. In addition, serum levels of the anti-inflammatory cytokine interleukin-10 (IL-10) were significantly increased by select parameters of electrical stimulation but remained unchanged with others. Conclusions These results indicate that electrical stimulation parameter selection is critically important for the modulation of cytokines via the cervical vagus nerve and that specific cytokines can be increased by electrical stimulation in the absence of inflammation. As the next generation of bioelectronic therapies and devices are developed to capitalize on the neural regulation of inflammation, the selection of nerve stimulation parameters will be a critically important variable for achieving cytokine-specific changes.

Published

2020

14. Serum cytokine levels are modulated by specific frequencies, amplitudes, and pulse widths of vagus nerve stimulation

Author

Sangeeta S. Chavan, Eric H. Chang, Harold A. Silverman, Tea Tsaava, Timir Datta-Chaudhuri, Gavin H Imperato, Kevin J. Tracey, Justin Newman, Emily Battinelli Masi, Chad E. Bouton, and Meghan E. Addorisio

Subjects

0303 health sciences, medicine.medical_specialty, business.industry, medicine.medical_treatment, Inflammatory reflex, Stimulation, Inflammation, Symptomatic relief, 3. Good health, Proinflammatory cytokine, Vagus nerve, 03 medical and health sciences, 0302 clinical medicine, Cytokine, Endocrinology, Internal medicine, medicine, medicine.symptom, business, 030217 neurology & neurosurgery, Vagus nerve stimulation, 030304 developmental biology

Abstract

Electrical stimulation of peripheral nerves is a widely used technique to treat a variety of conditions including chronic pain, motor impairment, headaches, and epilepsy. Nerve stimulation to achieve efficacious symptomatic relief depends on the proper selection of electrical stimulation parameters to recruit the appropriate fibers within a nerve. Recently, electrical stimulation of the vagus nerve has shown promise for controlling inflammation and clinical trials have demonstrated efficacy for the treatment of inflammatory disorders. This application of vagus nerve stimulation activates the inflammatory reflex, reducing levels of inflammatory cytokines during inflammation. Here, we wanted to test whether altering the parameters of electrical vagus nerve stimulation would change circulating cytokine levels of normal healthy animals in the absence of increased inflammation. To examine this, we systematically tested a set of electrical stimulation parameters and measured serum cytokine levels in healthy mice. Surprisingly, we found that specific combinations of pulse width, pulse amplitude, and frequency produced significant increases of the pro-inflammatory cytokine tumor necrosis factor alpha (TNFα), while other parameters selectively lowered serum TNFα levels, as compared to sham-stimulated mice. In addition, serum levels of the anti-inflammatory cytokine interleukin-10 (IL-10) were significantly increased by select parameters of electrical stimulation but remained unchanged with others. These results indicate that electrical stimulation parameter selection is critically important for the modulation of cytokines via the cervical vagus nerve and that specific cytokines can be increased by electrical stimulation in the absence of inflammation. As the next generation of bioelectronic therapies and devices are developed to capitalize on the neural regulation of inflammation, the selection of nerve stimulation parameters will be a critically important variable for achieving cytokine-specific changes.

Published

2020

15. Bioelectronic medicine: an unexpected path to new therapies

Author

Chad E. Bouton and Peder S. Olofsson

Subjects

business.industry, Path (graph theory), Internal Medicine, Medicine, business, Computer network

Published

2019

16. Cracking the neural code, treating paralysis and the future of bioelectronic medicine

Author

Chad E. Bouton

Subjects

0301 basic medicine, Nervous system, medicine.medical_specialty, Brain activity and meditation, medicine.medical_treatment, Electric Stimulation Therapy, Sensory system, Biosensing Techniques, Synaptic Transmission, 03 medical and health sciences, 0302 clinical medicine, Internal Medicine, Paralysis, medicine, Humans, Neurostimulation, Neurons, business.industry, Brain, Electronics, Medical, Surgery, 030104 developmental biology, medicine.anatomical_structure, DECIPHER, medicine.symptom, Neural coding, business, Neuroscience, 030217 neurology & neurosurgery, Biotechnology, Forecasting, Neural decoding

Abstract

The human nervous system is a vast network carrying not only sensory and movement information, but also information to and from our organs, intimately linking it to our overall health. Scientists and engineers have been working for decades to tap into this network and 'crack the neural code' by decoding neural signals and learning how to 'speak' the language of the nervous system. Progress has been made in developing neural decoding methods to decipher brain activity and bioelectronic technologies to treat rheumatoid arthritis, paralysis, epilepsy and for diagnosing brain-related diseases such as Parkinson's and Alzheimer's disease. In a recent first-in-human study involving paralysis, a paralysed male study participant regained movement in his hand, years after his injury, through the use of a bioelectronic neural bypass. This work combined neural decoding and neurostimulation methods to translate and re-route signals around damaged neural pathways within the central nervous system. By extending these methods to decipher neural messages in the peripheral nervous system, status information from our bodily functions and specific organs could be gained. This, one day, could allow real-time diagnostics to be performed to give us a deeper insight into a patient's condition, or potentially even predict disease or allow early diagnosis. The future of bioelectronic medicine is extremely bright and is wide open as new diagnostic and treatment options are developed for patients around the world.

Published

2017

17. Restoring Movement in Paralysis with a Bioelectronic Neural Bypass Approach: Current State and Future Directions

Author

Chad E. Bouton

Subjects

0301 basic medicine, Computer science, Electric Stimulation Therapy, Biosensing Techniques, Synaptic Transmission, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Neural activity, 0302 clinical medicine, Paralysis, medicine, Humans, Electric stimulation therapy, Brain–computer interface, Neurons, Treatment options, Brain, Neuromodulation (medicine), Electronics, Medical, 030104 developmental biology, State (computer science), medicine.symptom, Neuroscience, 030217 neurology & neurosurgery, Perspectives, Forecasting

Abstract

Bioelectronic medicine is a rapidly growing field that explores targeted neuromodulation in new treatment options addressing both disease and injury. New bioelectronic methods are being developed to monitor and modulate neural activity directly. The therapeutic benefit of these approaches has been validated in recent clinical studies in various conditions, including paralysis. By using decoding and modulation strategies together, it is possible to restore lost function to those living with paralysis and other debilitating conditions by interpreting and rerouting signals around the affected portion of the nervous system. This, in effect, creates a bioelectronic "neural bypass" to serve the function of the damaged/degenerated network. By learning the language of neurons and using neural interface technology to tap into critical networks, new approaches to repairing or restoring function in areas impacted by disease or injury may become a reality.

Published

2019

18. Identification of hypoglycemia-specific neural signals by decoding murine vagus nerve activity

Author

Chad E. Bouton, Sangeeta S. Chavan, Todd J. Levy, Theodoros P. Zanos, Tea Tsaava, Kevin J. Tracey, and Emily Battinelli Masi

Subjects

lcsh:Medical technology, business.industry, Decoding, Insulin, medicine.medical_treatment, TRPV1, Sensory system, Hypoglycemia, medicine.disease, Vagus nerve, Bioelectronic medicine, Glucose, lcsh:R855-855.5, medicine, Nociceptor, Reflex, General Earth and Planetary Sciences, Energy source, business, Neuroscience, Research Article, General Environmental Science

Abstract

Background Glucose is a crucial energy source. In humans, it is the primary sugar for high energy demanding cells in brain, muscle and peripheral neurons. Deviations of blood glucose levels from normal levels for an extended period of time is dangerous or even fatal, so regulation of blood glucose levels is a biological imperative. The vagus nerve, comprised of sensory and motor fibres, provides a major anatomical substrate for regulating metabolism. While prior studies have implicated the vagus nerve in the neurometabolic interface, its specific role in either the afferent or efferent arc of this reflex remains elusive. Methods Here we use recently developed methods to isolate and decode specific neural signals acquired from the surface of the vagus nerve in BALB/c wild type mice to identify those that respond robustly to hypoglycemia. We also attempted to decode neural signals related to hyperglycemia. In addition to wild type mice, we analyzed the responses to acute hypo- and hyperglycemia in transient receptor potential cation channel subfamily V member 1 (TRPV1) cell depleted mice. The decoding algorithm uses neural signals as input and reconstructs blood glucose levels. Results Our algorithm was able to reconstruct the blood glucose levels with high accuracy (median error 18.6 mg/dl). Hyperglycemia did not induce robust vagus nerve responses, and deletion of TRPV1 nociceptors attenuated the hypoglycemia-dependent vagus nerve signals. Conclusion These results provide insight to the sensory vagal signaling that encodes hypoglycemic states and suggest a method to measure blood glucose levels by decoding nerve signals. Trial registration Not applicable.

Published

2019

19. Cytokine-specific Neurograms in the Sensory Vagus Nerve

Author

Tea Tsaava, Sangeeta S. Chavan, Benjamin E. Steinberg, Harold A. Silverman, Emily Battinelli, Manojkumar Gunasekaran, Sergio Robbiati, Chad E. Bouton, Kevin J. Tracey, Patricio T. Huerta, and Andrew Stiegler

Subjects

0301 basic medicine, Nervous system, lcsh:Medical technology, medicine.medical_treatment, Central nervous system, Nodose Ganglion, Inflammation, Biology, Article, Proinflammatory cytokine, Vagus nerve, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Cytokine, lcsh:R855-855.5, nervous system, medicine, General Earth and Planetary Sciences, Tumor necrosis factor alpha, medicine.symptom, Neuroscience, 030217 neurology & neurosurgery, General Environmental Science

Abstract

The axons of the sensory, or afferent, vagus nerve transmit action potentials to the central nervous system in response to changes in the body’s metabolic and physiological status. Recent advances in identifying neural circuits that regulate immune responses to infection, inflammation and injury have revealed that vagus nerve signals regulate the release of cytokines and other factors produced by macrophages. Here we record compound action potentials in the cervical vagus nerve of adult mice and reveal the specific activity that occurs following administration of the proinflammatory cytokines tumor necrosis factor (TNF) and interleukin 1β (IL-1β). Importantly, the afferent vagus neurograms generated by TNF exposure are abolished in double knockout mice lacking TNF receptors 1 and 2 (TNF-R1/2KO), whereas IL-1 β-specific neurograms are eliminated in knockout mice lacking IL-1 β receptor (IL-1RKO). Conversely, TNF neurograms are preserved in IL-1RKO mice, and IL-1 β neurograms are unchanged in TNF-R1/2KO mice. Analysis of the temporal dynamics and power spectral characteristics of afferent vagus neurograms for TNF and IL-1β reveals cytokine-selective signals. The nodose ganglion contains the cell bodies of the sensory neurons whose axons run through the vagus nerve. The nodose neurons express receptors for TNF and IL-1β, and we show that exposing them to TNF and IL-1β significantly stimulates their calcium uptake. Together these results indicate that afferent vagus signals in response to cytokines provide a basic model of nervous system sensing of immune responses.

Published

2016

20. A wrappable microwire electrode for awake, chronic interfacing with small diameter autonomic peripheral nerves

Author

Loren Rieth, Malgorzata Straka, Laura Goldman, Jessica D. Falcone, Pogue Dd, Liu T, Chad E. Bouton, and Harbaljit S. Sohal

Subjects

Nerve activity, Small diameter, business.industry, Electrode, Medicine, Stimulation, business, Vagus nerve, Biomedical engineering, Peripheral

Abstract

Bioelectronic medicine requires the ability to monitor and modulate nerve activity in awake patients over time. The vagus nerve is a promising stimulation target, and preclinical models often use mice. However, an awake, chronic mouse vagus nerve interface has yet to be demonstrated. Here, we developed a functional wrappable microwire electrode to chronically interface with the small diameter mouse cervical vagus nerve (∼100 μm). In an acute setting, the wrappable microwire had similar recording performance to commercially available electrodes. A chronic, awake mouse model was then developed to record spontaneous compound action potentials (CAPs). Viable signal-to-noise ratios (SNRs) were obtained from the wrappable microwires between 30 and 60 days (n = 8). Weekly impedance measurements showed no correlation between SNR or time. The wrappable microwires successfully interfaced with small diameter nerves and has been validated in a chronic, awake preclinical model, which can better facilitate clinical translation for bioelectronic medicine.

Published

2018

21. Identification of cytokine-specific sensory neural signals by decoding murine vagus nerve activity

Author

Sangeeta S. Chavan, Theodoros P. Zanos, Kevin J. Tracey, Tea Tsaava, Jeffrey Michael Ashe, Todd J. Levy, Peter William Lorraine, Harold A. Silverman, Chad E. Bouton, and Emily Battinelli

Subjects

0301 basic medicine, Nervous system, Male, Sensory Receptor Cells, medicine.medical_treatment, Interleukin-1beta, Action Potentials, TRPV Cation Channels, Sensory system, Proinflammatory cytokine, 03 medical and health sciences, Mice, 0302 clinical medicine, medicine, Animals, Mice, Knockout, Receptors, Interleukin-1 Type I, Mice, Inbred BALB C, Multidisciplinary, business.industry, Tumor Necrosis Factor-alpha, Bayes Theorem, Vagus Nerve, Vagus nerve, Mice, Inbred C57BL, 030104 developmental biology, medicine.anatomical_structure, Reflex, Nerve block, Brainstem, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

The nervous system maintains physiological homeostasis through reflex pathways that modulate organ function. This process begins when changes in the internal milieu (e.g., blood pressure, temperature, or pH) activate visceral sensory neurons that transmit action potentials along the vagus nerve to the brainstem. IL-1β and TNF, inflammatory cytokines produced by immune cells during infection and injury, and other inflammatory mediators have been implicated in activating sensory action potentials in the vagus nerve. However, it remains unclear whether neural responses encode cytokine-specific information. Here we develop methods to isolate and decode specific neural signals to discriminate between two different cytokines. Nerve impulses recorded from the vagus nerve of mice exposed to IL-1β and TNF were sorted into groups based on their shape and amplitude, and their respective firing rates were computed. This revealed sensory neural groups responding specifically to TNF and IL-1β in a dose-dependent manner. These cytokine-mediated responses were subsequently decoded using a Naive Bayes algorithm that discriminated between no exposure and exposures to IL-1β and TNF (mean successful identification rate 82.9 ± 17.8%, chance level 33%). Recordings obtained in IL-1 receptor-KO mice were devoid of IL-1β-related signals but retained their responses to TNF. Genetic ablation of TRPV1 neurons attenuated the vagus neural signals mediated by IL-1β, and distal lidocaine nerve block attenuated all vagus neural signals recorded. The results obtained in this study using the methodological framework suggest that cytokine-specific information is present in sensory neural signals within the vagus nerve.

Published

2018

22. Clinically Significant Gains in Skillful Grasp Coordination by an Individual With Tetraplegia Using an Implanted Brain-Computer Interface With Forearm Transcutaneous Muscle Stimulation

Author

Mingming Zhang, Gaurav Sharma, David A. Friedenberg, Michael A. Schwemmer, Samuel C. Colachis, Nicholas V. Annetta, Walter J. Mysiw, Nicholas D. Skomrock, Ali R. Rezai, Chad E. Bouton, and Marcie Bockbrader

Subjects

Adult, Male, 030506 rehabilitation, medicine.medical_specialty, Neuroprosthetics, medicine.medical_treatment, Physical Therapy, Sports Therapy and Rehabilitation, Electric Stimulation Therapy, Quadriplegia, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, Forearm, Hand strength, Medicine, Functional electrical stimulation, Humans, Tetraplegia, Spinal cord injury, Rehabilitation, Hand Strength, business.industry, Motor control, medicine.disease, medicine.anatomical_structure, Brain-Computer Interfaces, 0305 other medical science, business, 030217 neurology & neurosurgery

Abstract

Objective To demonstrate naturalistic motor control speed, coordinated grasp, and carryover from trained to novel objects by an individual with tetraplegia using a brain-computer interface (BCI)-controlled neuroprosthetic. Design Phase I trial for an intracortical BCI integrated with forearm functional electrical stimulation (FES). Data reported span postimplant days 137 to 1478. Setting Tertiary care outpatient rehabilitation center. Participant A 27-year-old man with C5 class A (on the American Spinal Injury Association Impairment Scale) traumatic spinal cord injury Interventions After array implantation in his left (dominant) motor cortex, the participant trained with BCI-FES to control dynamic, coordinated forearm, wrist, and hand movements. Main Outcome Measures Performance on standardized tests of arm motor ability (Graded Redefined Assessment of Strength, Sensibility, and Prehension [GRASSP], Action Research Arm Test [ARAT], Grasp and Release Test [GRT], Box and Block Test), grip myometry, and functional activity measures (Capabilities of Upper Extremity Test [CUE-T], Quadriplegia Index of Function-Short Form [QIF-SF], Spinal Cord Independence Measure–Self-Report [SCIM-SR]) with and without the BCI-FES. Results With BCI-FES, scores improved from baseline on the following: Grip force (2.9 kg); ARAT cup, cylinders, ball, bar, and blocks; GRT can, fork, peg, weight, and tape; GRASSP strength and prehension (unscrewing lids, pouring from a bottle, transferring pegs); and CUE-T wrist and hand skills. QIF-SF and SCIM-SR eating, grooming, and toileting activities were expected to improve with home use of BCI-FES. Pincer grips and mobility were unaffected. BCI-FES grip skills enabled the participant to play an adapted “Battleship” game and manipulate household objects. Conclusions Using BCI-FES, the participant performed skillful and coordinated grasps and made clinically significant gains in tests of upper limb function. Practice generalized from training objects to household items and leisure activities. Motor ability improved for palmar, lateral, and tip-to-tip grips. The expects eventual home use to confer greater independence for activities of daily living, consistent with observed neurologic level gains from C5-6 to C7-T1. This marks a critical translational step toward clinical viability for BCI neuroprosthetics.

Published

2018

23. Standardization of methods to record Vagus nerve activity in mice

Author

Chad E. Bouton, Benjamin E. Steinberg, Sergio Robbiati, Tea Tsaava, Kevin J. Tracey, Patricio T. Huerta, Emily Battinelli Masi, Justin Newman, Andrew Stiegler, Harold A. Silverman, and Sangeeta S. Chavan

Subjects

0301 basic medicine, lcsh:Medical technology, TLR4KO, Inflammation, 03 medical and health sciences, 0302 clinical medicine, Immunity, medicine, Neurogram, Receptor, Murine, General Environmental Science, 2. Zero hunger, business.industry, digestive, oral, and skin physiology, Vagus nerve, Vagus nerve recording, Electrophysiology, 030104 developmental biology, lcsh:R855-855.5, nervous system, Knockout mouse, TLR4, Reflex, General Earth and Planetary Sciences, medicine.symptom, business, Neuroscience, hormones, hormone substitutes, and hormone antagonists, 030217 neurology & neurosurgery, Research Article

Abstract

Background The vagus nerve plays an important role in the regulation of organ function, including reflex pathways that regulate immunity and inflammation. Recent studies using genetically modified mice have improved our understanding of molecular mechanisms in the neural control of immunity. However, mapping neural signals transmitted in the vagus nerve in mice has been limited by technical challenges. Here, we have standardized an experimental protocol to record compound action potentials transmitted in the vagus nerve. Methods The vagus nerve was isolated in Balb/c and B6.129S mice, and placed either on a hook or cuff electrode. The electrical signals from the vagus nerve were digitized using either a Neuralynx or Plexon data acquisition system. Changes in the vagus nerve activity in response to anesthesia, feeding and administration of bacterial endotoxin were analyzed. Results We have developed an electrophysiological recording system to record compound action potentials from the cervical vagus nerve in mice. Cuff electrodes significantly reduce background noise and increase the signal to noise ratio as compared to hook electrodes. Baseline vagus nerve activity varies in response to anesthesia depth and food intake. Analysis of vagus neurograms in different mouse strains (Balb/c and C57BL/6) reveal no significant differences in baseline activity. Importantly, vagus neurogramactivity in wild type and TLR4 receptor knock out mice exhibits receptor dependency of endotoxin mediated signals. Conclusions These methods for recording vagus neurogram in mice provide a useful tool to further delineate the role of vagus neural pathways in a standardized murine disease model.

Published

2018

24. Time Stability and Coherence Analysis of Multiunit, Single-Unit and Local Field Potential Neuronal Signals in Chronically Implanted Brain Electrodes

Author

David A. Friedenberg, Tony Blanco, Nicholas V. Annetta, Chad E. Bouton, Ammar Shaikhouni, Gaurav Sharma, Ali R. Rezai, and Daphne Vasconcelos

Subjects

education.field_of_study, Materials science, Population, Local field potential, Signal, medicine.anatomical_structure, Temporal resolution, Electrode, medicine, General Earth and Planetary Sciences, education, Image resolution, Decoding methods, General Environmental Science, Biomedical engineering, Motor cortex

Abstract

Introducing neural sensing and decoding to open-loop neurostimulation technologies has the potential to significantly improve the diagnosis and treatment of a wide variety of diseases treated through bioelectronic medicine. Chronically implanted multi-electrode arrays (MEA) can be used for such neural sensing and are critical for obtaining data of high spatial and temporal resolution to provide accurate decoding. Signals recorded from these arrays include local field potentials (LFP), and multiunit (MU) and single-unit (SU) activity. LFP offer signal stability over time, but at the expense of decreased spatial resolution. SU activity, on the other hand, offers better spatial resolution, but is considered less stable in chronic applications. MU activity, which represents an aggregate spiking activity of a population of neurons on the order of several hundred microns away from the recording tip, is considered a signal that can offer a compromise between the two signals. Here we used a wavelet decomposition method to extract and characterize the LFP, MU and SU signals obtained from a 96-channel MEA implanted in the motor cortex of a nonhuman primate over a 7.5-month period. We observed that not only are the MU signals more stable over time compared with SU activity, but that they are also significantly less correlated among electrodes compared with LFP over the spatial scale of the implanted array. Histological analysis of tissue sections also revealed a 51% reduction in the number of neuronal cell bodies within a radius around the electrode tips of the implanted tissue compared with control tissue. Our results indicate that MU activity offers long-term signal stability with less correlated signals, potentially providing an effective signal for neural sensing in bioelectronic medicine.

Published

2015

25. Neuroprosthetic-enabled control of graded arm muscle contraction in a paralyzed human

Author

Nicholas V. Annetta, Marcia A. Bockbrader, Mingming Zhang, David A. Friedenberg, Herbert S. Bresler, Michael A. Schwemmer, W. Jerry Mysiw, Ali R. Rezai, Andrew J. Landgraf, Gaurav Sharma, and Chad E. Bouton

Subjects

Adult, Male, Volition, 0301 basic medicine, medicine.medical_specialty, Neuroprosthetics, Computer science, Movement, Science, Quadriplegia, Article, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, Arm muscle, medicine, Humans, Functional electrical stimulation, Tetraplegia, Brain–computer interface, Multidisciplinary, Prostheses and Implants, medicine.disease, Electric Stimulation, 030104 developmental biology, Brain-Computer Interfaces, Arm, Medicine, medicine.symptom, 030217 neurology & neurosurgery, Muscle Contraction, Muscle contraction

Abstract

Neuroprosthetics that combine a brain computer interface (BCI) with functional electrical stimulation (FES) can restore voluntary control of a patients’ own paralyzed limbs. To date, human studies have demonstrated an “all-or-none” type of control for a fixed number of pre-determined states, like hand-open and hand-closed. To be practical for everyday use, a BCI-FES system should enable smooth control of limb movements through a continuum of states and generate situationally appropriate, graded muscle contractions. Crucially, this functionality will allow users of BCI-FES neuroprosthetics to manipulate objects of different sizes and weights without dropping or crushing them. In this study, we present the first evidence that using a BCI-FES system, a human with tetraplegia can regain volitional, graded control of muscle contraction in his paralyzed limb. In addition, we show the critical ability of the system to generalize beyond training states and accurately generate wrist flexion states that are intermediate to training levels. These innovations provide the groundwork for enabling enhanced and more natural fine motor control of paralyzed limbs by BCI-FES neuroprosthetics.

Published

2017

26. Neuroprotective Effects of Trigeminal Nerve Stimulation in Severe Traumatic Brain Injury

Author

Eugene V. Golanov, Ping Wang, Chunyan Li, Chad E. Bouton, Neal Mehan, Wayne W. Chaung, Amrit Chiluwal, and Raj K. Narayan

Subjects

Male, 0301 basic medicine, Traumatic brain injury, Science, Ischemia, Electric Stimulation Therapy, Neuroprotection, Article, Rats, Sprague-Dawley, 03 medical and health sciences, Oxygen Consumption, 0302 clinical medicine, Brain Injuries, Traumatic, medicine, Animals, Trigeminal Nerve, Cerebral perfusion pressure, Trigeminal nerve, Multidisciplinary, Interleukin-6, Tumor Necrosis Factor-alpha, business.industry, Rostral ventrolateral medulla, medicine.disease, Rats, nervous system diseases, Oxygen tension, 030104 developmental biology, nervous system, Cerebral blood flow, Cerebrovascular Circulation, Anesthesia, Medicine, business, 030217 neurology & neurosurgery

Abstract

Following traumatic brain injury (TBI), ischemia and hypoxia play a major role in further worsening of the damage, a process referred to as ‘secondary injury’. Protecting neurons from causative factors of secondary injury has been the guiding principle of modern TBI management. Stimulation of trigeminal nerve induces pressor response and improves cerebral blood flow (CBF) by activating the rostral ventrolateral medulla. Moreover, it causes cerebrovasodilation through the trigemino-cerebrovascular system and trigemino-parasympathetic reflex. These effects are capable of increasing cerebral perfusion, making trigeminal nerve stimulation (TNS) a promising strategy for TBI management. Here, we investigated the use of electrical TNS for improving CBF and brain oxygen tension (PbrO2), with the goal of decreasing secondary injury. Severe TBI was produced using controlled cortical impact (CCI) in a rat model, and TNS treatment was delivered for the first hour after CCI. In comparison to TBI group, TBI animals with TNS treatment demonstrated significantly increased systemic blood pressure, CBF and PbrO2 at the hyperacute phase of TBI. Furthermore, rats in TNS-treatment group showed significantly reduced brain edema, blood-brain barrier disruption, lesion volume, and brain cortical levels of TNF-α and IL-6. These data provide strong early evidence that TNS could be an effective neuroprotective strategy.

Published

2017

27. Development of a brain monitoring system for multimodality investigation in awake rats

Author

Amrit K Chiluwal, Kanokwan Limnuson, Ping Wang, Raj K. Narayan, Chad E. Bouton, and Chunyan Li

Subjects

Male, Movement, Central nervous system, Brain monitoring, 01 natural sciences, Signal, 03 medical and health sciences, 0302 clinical medicine, Medicine, Animals, Wakefulness, Electrocorticography, Neurons, medicine.diagnostic_test, business.industry, 010401 analytical chemistry, Continuous monitoring, Temperature, Brain, Neurophysiological Monitoring, 0104 chemical sciences, Oxygen tension, Rats, Electrophysiology, medicine.anatomical_structure, Cerebral blood flow, Cerebrovascular Circulation, Blood Gas Analysis, business, Artifacts, Neuroscience, Microelectrodes, 030217 neurology & neurosurgery, Biomedical engineering

Abstract

Multimodal brain monitoring is an important approach to gain insight into brain function, modulation, and pathology. We have developed a unique micromachined neural probe capable of real-time continuous monitoring of multiple physiological, biochemical and electrophysiological variables. However, to date, it has only been used in anesthetized animals due to a lack of an appropriate interface for awake animals. We have developed a versatile headstage for recording the small neural signal and bridging the sensors to the remote sensing units for multimodal brain monitoring in awake rats. The developed system has been successfully validated in awake rats by simultaneously measuring four cerebral variables: electrocorticography, oxygen tension, temperature and cerebral blood flow. Reliable signal recordings were obtained with minimal artifacts from movement and environmental noise. For the first time, multiple variables of cerebral function and metabolism were simultaneously recorded from awake rats using a single neural probe. The system is envisioned for studying the effects of pharmacologic treatments, mapping the development of central nervous system diseases, and better understanding normal cerebral physiology.

Published

2017

28. Big data challenges in decoding cortical activity in a human with quadriplegia to inform a brain computer interface

Author

W. Jerry Mysiw, Mingming Zhang, Gaurav Sharma, Nicholas V. Annetta, Herbert S. Bresler, David A. Friedenberg, Ali R. Rezai, Michael A. Schwemmer, Nicholas D. Skomrock, Chad E. Bouton, and Marcia A. Bockbrader

Subjects

0301 basic medicine, Male, Time Factors, Computer science, Big data, Electroencephalography, Machine learning, computer.software_genre, Quadriplegia, 03 medical and health sciences, 0302 clinical medicine, medicine, Humans, Information Science, Brain–computer interface, medicine.diagnostic_test, business.industry, Process (computing), Motor Cortex, Brain, Signal Processing, Computer-Assisted, Multielectrode array, Human brain, 030104 developmental biology, medicine.anatomical_structure, Brain-Computer Interfaces, Artificial intelligence, business, computer, 030217 neurology & neurosurgery, Decoding methods, Algorithms, Motor cortex

Abstract

Recent advances in Brain Computer Interfaces (BCIs) have created hope that one day paralyzed patients will be able to regain control of their paralyzed limbs. As part of an ongoing clinical study, we have implanted a 96-electrode Utah array in the motor cortex of a paralyzed human. The array generates almost 3 million data points from the brain every second. This presents several big data challenges towards developing algorithms that should not only process the data in real-time (for the BCI to be responsive) but are also robust to temporal variations and non-stationarities in the sensor data. We demonstrate an algorithmic approach to analyze such data and present a novel method to evaluate such algorithms. We present our methodology with examples of decoding human brain data in real-time to inform a BCI.

Published

2017

29. Using an Artificial Neural Bypass to Restore Cortical Control of Rhythmic Movements in a Human with Quadriplegia

Author

Chad E. Bouton, W. Jerry Mysiw, Stephanie Domas, David A. Friedenberg, Connor Majstorovic, Bradley C. Glenn, Nicholas V. Annetta, Marcie Bockbrader, Ali R. Rezai, and Gaurav Sharma

Subjects

0301 basic medicine, Multidisciplinary, Artificial neural network, Computer science, Central pattern generator, Anatomy, Spinal cord, Article, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Rhythm, Cortical control, Paralysis, medicine, medicine.symptom, Neuroscience, 030217 neurology & neurosurgery

Abstract

Neuroprosthetic technology has been used to restore cortical control of discrete (non-rhythmic) hand movements in a paralyzed person. However, cortical control of rhythmic movements which originate in the brain but are coordinated by Central Pattern Generator (CPG) neural networks in the spinal cord has not been demonstrated previously. Here we show a demonstration of an artificial neural bypass technology that decodes cortical activity and emulates spinal cord CPG function allowing volitional rhythmic hand movement. The technology uses a combination of signals recorded from the brain, machine-learning algorithms to decode the signals, a numerical model of CPG network, and a neuromuscular electrical stimulation system to evoke rhythmic movements. Using the neural bypass, a quadriplegic participant was able to initiate, sustain, and switch between rhythmic and discrete finger movements, using his thoughts alone. These results have implications in advancing neuroprosthetic technology to restore complex movements in people living with paralysis.

Published

2016

30. Experimental Detection of Subcutaneous Contrast Extravasation Using Radio Frequency Permittivity Sensing

Author

Felicia R. Hobson, Gregory Stark, Chad E. Bouton, and Thomas Lombardi

Subjects

Adult, Male, Permittivity, medicine.medical_specialty, Antecubital Fossa, Contrast Media, Early detection, Sensitivity and Specificity, Injections, Upper Extremity, Image Interpretation, Computer-Assisted, medicine, Humans, Contrast extravasation, False Positive Reactions, Radiology, Nuclear Medicine and imaging, medicine.diagnostic_test, business.industry, Magnetic resonance imaging, Middle Aged, Magnetic Resonance Imaging, Extravasation, Confidence interval, Female, Radiology, Radio frequency, Tomography, X-Ray Computed, business, Extravasation of Diagnostic and Therapeutic Materials

Abstract

A new method for early detection of extravasations during contrast-enhanced computed tomographic procedures is evaluated. The new method uses radio frequency permittivity-based sensing to detect the onset of an extravasation with high sensitivity and specificity. There were 66 subcutaneous injections performed at the antecubital fossa in 35 volunteers to evaluate the new method. Sensitivity was found to be 98.8% (95% confidence interval, 97.6%-100%), whereas specificity was found to be 99.97% (95% confidence interval, 99.90%-100%).

Published

2009

31. Restoring cortical control of functional movement in a human with quadriplegia

Author

Austin Morgan, Marcia A. Bockbrader, Nicholas V. Annetta, Ammar Shaikhouni, Milind Deogaonkar, Dylan M. Nielson, Ali R. Rezai, Chad E. Bouton, David A. Friedenberg, Per B. Sederberg, Bradley C. Glenn, W. Jerry Mysiw, and Gaurav Sharma

Subjects

0301 basic medicine, Nervous system, Male, Movement, Quadriplegia, Machine Learning, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Forearm, Hand strength, Activities of Daily Living, medicine, Paralysis, Premovement neuronal activity, Humans, Muscle, Skeletal, Functional movement, Spinal Cord Injuries, Brain–computer interface, Multidisciplinary, Hand Strength, business.industry, Motor Cortex, Cervical Cord, Hand, Magnetic Resonance Imaging, Electric Stimulation, Electrodes, Implanted, 030104 developmental biology, medicine.anatomical_structure, Imagination, medicine.symptom, business, Neuroscience, Microelectrodes, 030217 neurology & neurosurgery, Algorithms, Motor cortex

Abstract

Millions of people worldwide suffer from diseases that lead to paralysis through disruption of signal pathways between the brain and the muscles. Neuroprosthetic devices are designed to restore lost function and could be used to form an electronic 'neural bypass' to circumvent disconnected pathways in the nervous system. It has previously been shown that intracortically recorded signals can be decoded to extract information related to motion, allowing non-human primates and paralysed humans to control computers and robotic arms through imagined movements. In non-human primates, these types of signal have also been used to drive activation of chemically paralysed arm muscles. Here we show that intracortically recorded signals can be linked in real-time to muscle activation to restore movement in a paralysed human. We used a chronically implanted intracortical microelectrode array to record multiunit activity from the motor cortex in a study participant with quadriplegia from cervical spinal cord injury. We applied machine-learning algorithms to decode the neuronal activity and control activation of the participant's forearm muscles through a custom-built high-resolution neuromuscular electrical stimulation system. The system provided isolated finger movements and the participant achieved continuous cortical control of six different wrist and hand motions. Furthermore, he was able to use the system to complete functional tasks relevant to daily living. Clinical assessment showed that, when using the system, his motor impairment improved from the fifth to the sixth cervical (C5-C6) to the seventh cervical to first thoracic (C7-T1) level unilaterally, conferring on him the critical abilities to grasp, manipulate, and release objects. This is the first demonstration to our knowledge of successful control of muscle activation using intracortically recorded signals in a paralysed human. These results have significant implications in advancing neuroprosthetic technology for people worldwide living with the effects of paralysis.

Published

2015

32. A novel flexible cuff-like microelectrode for dual purpose, acute and chronic electrical interfacing with the mouse cervical vagus nerve

Author

Edward S. Boyden, Laura Goldman, April S. Caravaca, Sangeeta S. Chavan, Kevin J. Tracey, Peder S. Olofsson, Robert Desimone, Gary Riggott, Chad E. Bouton, Harold A. Silverman, Tea Tsaava, and Harbaljit S. Sohal

Subjects

Male, 0301 basic medicine, Vagus Nerve Stimulation, medicine.medical_treatment, Biomedical Engineering, Action Potentials, Stimulation, Inflammation, Article, Mice, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Animals, Medicine, Mice, Inbred BALB C, business.industry, Vagus Nerve, Neurophysiology, Electric Stimulation, Electrodes, Implanted, Vagus nerve, Mice, Inbred C57BL, Microelectrode, 030104 developmental biology, Cervical Vertebrae, Reflex, Tumor necrosis factor alpha, medicine.symptom, business, Microelectrodes, Neuroscience, 030217 neurology & neurosurgery, Vagus nerve stimulation

Abstract

Objective. Neural reflexes regulate immune responses and homeostasis. Advances in bioelectronic medicine indicate that electrical stimulation of the vagus nerve can be used to treat inflammatory disease, yet the understanding of neural signals that regulate inflammation is incomplete. Current interfaces with the vagus nerve do not permit effective chronic stimulation or recording in mouse models, which is vital to studying the molecular and neurophysiological mechanisms that control inflammation homeostasis in health and disease. We developed an implantable, dual purpose, multi-channel, flexible 'microelectrode' array, for recording and stimulation of the mouse vagus nerve. Approach. The array was microfabricated on an 8 µm layer of highly biocompatible parylene configured with 16 sites. The microelectrode was evaluated by studying the recording and stimulation performance. Mice were chronically implanted with devices for up to 12 weeks. Main results. Using the microelectrode in vivo, high fidelity signals were recorded during physiological challenges (e.g potassium chloride and interleukin-1β), and electrical stimulation of the vagus nerve produced the expected significant reduction of blood levels of tumor necrosis factor (TNF) in endotoxemia. Inflammatory cell infiltration at the microelectrode 12 weeks of implantation was limited according to radial distribution analysis of inflammatory cells. Significance. This novel device provides an important step towards a viable chronic interface for cervical vagus nerve stimulation and recording in mice.

Published

2017

33. 'Decoding neural activity from an intracortical implant in humans with tetraplegia'

Author

Chad E. Bouton

Subjects

Engineering, medicine.medical_specialty, business.industry, Neurophysiology, medicine.disease, Wheelchair, Physical medicine and rehabilitation, Personal computer, medicine, Electrode array, Primary motor cortex, business, Neuroscience, Tetraplegia, Decoding methods, Neural decoding

Abstract

This work was part of a pilot clinical study that involved the placement of an intracortical implant in the primary motor cortex of human subjects. The study, the first of its kind, involved the implantation of a 96 electrode array in the human brain for up to a full year. The work described here involved two of the subjects in the study, one of which was a stroke victim, and the other had ALS. Both subjects were tetraplegic and also unable to speak. The intent of this work was to determine if intended/imagined movements would evoke neural activity that could be successfully decoded and allow the subjects to control various devices in their environment and communicate through a personal computer. Neural decoding algorithms were developed to interpret the intracortical activity in the primary motor cortex of both subjects. Adaptive support vector machine methods were developed and employed during this study. A large set of intended/imagined movements was successfully decoded and discriminated between with the first subject. Also, both imagined shoulder and wrist movements were decoded in the second subject. Finally, the algorithms developed in this work allowed, for the first time, control of a motorized wheelchair through intended/imagined movements in a human with an intracortical electrode array implant.

Published

2009