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1. An electroencephalogram microdisplay to visualize neuronal activity on the brain surface.

Author

Cleary, Daniel, Pizarro, Patricia, Tonsfeldt, Karen, Lee, Keundong, Chen, Po, Bourhis, Andrew, Galton, Ian, Coughlin, Brian, Yang, Jimmy, Paulk, Angelique, Halgren, Eric, Cash, Sydney, Dayeh, Shadi, Tchoe, Youngbin, Wu, Tianhai, U, Hoi, Roth, David, Kim, Dongwoo, and Lee, Jihwan

Subjects
Animals, Brain, Electroencephalography, Swine, Rats, Neurons, Brain Mapping, Rats, Sprague-Dawley, Electrocorticography, Male
Abstract

Functional mapping during brain surgery is applied to define brain areas that control critical functions and cannot be removed. Currently, these procedures rely on verbal interactions between the neurosurgeon and electrophysiologist, which can be time-consuming. In addition, the electrode grids that are used to measure brain activity and to identify the boundaries of pathological versus functional brain regions have low resolution and limited conformity to the brain surface. Here, we present the development of an intracranial electroencephalogram (iEEG)-microdisplay that consists of freestanding arrays of 2048 GaN light-emitting diodes laminated on the back of micro-electrocorticography electrode grids. With a series of proof-of-concept experiments in rats and pigs, we demonstrate that these iEEG-microdisplays allowed us to perform real-time iEEG recordings and display cortical activities by spatially corresponding light patterns on the surface of the brain in the surgical field. Furthermore, iEEG-microdisplays allowed us to identify and display cortical landmarks and pathological activities from rat and pig models. Using a dual-color iEEG-microdisplay, we demonstrated coregistration of the functional cortical boundaries with one color and displayed the evolution of electrical potentials associated with epileptiform activity with another color. The iEEG-microdisplay holds promise to facilitate monitoring of pathological brain activity in clinical settings.

Published
2024

2. Intraoperative application and early experience with novel high-resolution, high-channel-count thin-film electrodes for human microelectrocorticography.

Author

Tan, Hao, Paulk, Angelique, Stedelin, Brittany, Cleary, Daniel, Nerison, Caleb, Tchoe, Youngbin, Brown, Erik, Bourhis, Andrew, Russman, Samantha, Tonsfeldt, Karen, Yang, Jimmy, Oh, Hongseok, Ro, Yun, Lee, Keundong, Ganji, Mehran, Galton, Ian, Siler, Dominic, Han, Seunggu, Collins, Kelly, Ben-Haim, Sharona, Halgren, Eric, Cash, Sydney, Dayeh, Shadi, Raslan, Ahmed, and Lee, Jihwan

Subjects
cortical, electrocorticography, functional neurosurgery, gamma band, high resolution, intraoperative, mapping, passive, Humans, Microelectrodes, Computer Systems, Craniotomy, Language, Peroxides
Abstract

OBJECTIVE: The study objective was to evaluate intraoperative experience with newly developed high-spatial-resolution microelectrode grids composed of poly(3,4-ethylenedioxythiophene) with polystyrene sulfonate (PEDOT:PSS), and those composed of platinum nanorods (PtNRs). METHODS: A cohort of patients who underwent craniotomy for pathological tissue resection and who had high-spatial-resolution microelectrode grids placed intraoperatively were evaluated. Patient demographic and baseline clinical variables as well as relevant microelectrode grid characteristic data were collected. The primary and secondary outcome measures of interest were successful microelectrode grid utilization with usable resting-state or task-related data, and grid-related adverse intraoperative events and/or grid dysfunction. RESULTS: Included in the analysis were 89 cases of patients who underwent a craniotomy for resection of neoplasms (n = 58) or epileptogenic tissue (n = 31). These cases accounted for 94 grids: 58 PEDOT:PSS and 36 PtNR grids. Of these 94 grids, 86 were functional and used successfully to obtain cortical recordings from 82 patients. The mean cortical grid recording duration was 15.3 ± 1.15 minutes. Most recordings in patients were obtained during experimental tasks (n = 52, 58.4%), involving language and sensorimotor testing paradigms, or were obtained passively during resting state (n = 32, 36.0%). There were no intraoperative adverse events related to grid placement. However, there were instances of PtNR grid dysfunction (n = 8) related to damage incurred by suboptimal preoperative sterilization (n = 7) and improper handling (n = 1); intraoperative recordings were not performed. Vaporized peroxide sterilization was the most optimal sterilization method for PtNR grids, providing a significantly greater number of usable channels poststerilization than did steam-based sterilization techniques (median 905.0 [IQR 650.8-935.5] vs 356.0 [IQR 18.0-597.8], p = 0.0031). CONCLUSIONS: High-spatial-resolution microelectrode grids can be readily incorporated into appropriately selected craniotomy cases for clinical and research purposes. Grids are reliable when preoperative handling and sterilization considerations are accounted for. Future investigations should compare the diagnostic utility of these high-resolution grids to commercially available counterparts and assess whether diagnostic discrepancies relate to clinical outcomes.

Published
2024

3. Flexible, scalable, high channel count stereo-electrode for recording in the human brain

Author

Lee, Keundong, Paulk, Angelique C, Ro, Yun Goo, Cleary, Daniel R, Tonsfeldt, Karen J, Kfir, Yoav, Pezaris, John S, Tchoe, Youngbin, Lee, Jihwan, Bourhis, Andrew M, Vatsyayan, Ritwik, Martin, Joel R, Russman, Samantha M, Yang, Jimmy C, Baohan, Amy, Richardson, R Mark, Williams, Ziv M, Fried, Shelley I, Hoi Sang, U, Raslan, Ahmed M, Ben-Haim, Sharona, Halgren, Eric, Cash, Sydney S, and Dayeh, Shadi A

Subjects
Engineering, Biomedical Engineering, Brain Disorders, Neurosciences, Bioengineering, Mental health, Neurological, Humans, Brain, Electrodes, Action Potentials, Neurons, Electrodes, Implanted
Abstract

Over the past decade, stereotactically placed electrodes have become the gold standard for deep brain recording and stimulation for a wide variety of neurological and psychiatric diseases. Current electrodes, however, are limited in their spatial resolution and ability to record from small populations of neurons, let alone individual neurons. Here, we report on an innovative, customizable, monolithically integrated human-grade flexible depth electrode capable of recording from up to 128 channels and able to record at a depth of 10 cm in brain tissue. This thin, stylet-guided depth electrode is capable of recording local field potentials and single unit neuronal activity (action potentials), validated across species. This device represents an advance in manufacturing and design approaches which extends the capabilities of a mainstay technology in clinical neurology.

Published
2024

4. Synthesis of PEDOT:PSS Brushes Grafted from Gold Using ATRP for Increased Electrochemical and Mechanical Stability

Author

Tuermer-Lee, Jason X, Lim, Allison, Ah, Louis, Blau, Rachel, Qie, Yi, Shipley, Wade, Kayser, Laure V, Russman, Samantha M, Tao, Andrea R, Dayeh, Shadi A, and Lipomi, Darren J

Abstract

We report PEDOT:PSS brushes grafted from gold using surface-initiated atom-transfer radical polymerization (SI-ATRP) which demonstrate significantly enhanced mechanical stability against sonication and electrochemical cycling compared to spincoated analogues as well as lower impedances than bare gold at frequencies from 0.1 to 105Hz. These results suggest SI-ATRP PEDOT:PSS to be a promising candidate for use in microelectrodes for neural activity recording. Spin-coated, electrodeposited, and drop-cast PEDOT:PSS have already been shown to reduce impedance and improve biocompatibility of microelectrodes, but the lack of strong chemical bonds of the physisorbed polymer film to the metal leads to disintegration under required operational stresses including cyclic mechanical loads, abrasion, and electrochemical cycling. Rather than modifying the metal electrode or introducing cross-linkers or other additives to improve the stability of the polymer film, this work chemically tethers the polymer to the surface, offering a simple, scalable solution for functional bioelectronic interfaces.

Published
2023

5. Conductive electrospun polymer improves stem cell-derived cardiomyocyte function and maturation

Author

Gonzalez, Gisselle, Nelson, Aileena C, Holman, Alyssa R, Whitehead, Alexander J, LaMontagne, Erin, Lian, Rachel, Vatsyayan, Ritwik, Dayeh, Shadi A, and Engler, Adam J

Subjects
Engineering, Biomedical Engineering, Cardiovascular, Regenerative Medicine, Stem Cell Research, Stem Cell Research - Induced Pluripotent Stem Cell, Stem Cell Research - Embryonic - Human, Stem Cell Research - Induced Pluripotent Stem Cell - Human, Heart Disease, 5.2 Cellular and gene therapies, Humans, Myocytes, Cardiac, Polymers, Pluripotent Stem Cells, Cell Line, Cell Differentiation, Electric Conductivity, sulfonate, poly(vinyl) alcohol, Desmoplakin, Sarcomere organization, Calcium handling, FluoVolt, poly(3, 4-ethylenedioxythiophene):polystyrene, poly(3, 4-ethylenedioxythiophene):polystyrene sulfonate
Abstract

Despite numerous efforts to generate mature human pluripotent stem cell-derived cardiomyocytes (hPSC-CMs), cells often remain immature, electrically isolated, and may not reflect adult biology. Conductive polymers are attractive candidates to facilitate electrical communication between hPSC-CMs, especially at sub-confluent cell densities or diseased cells lacking cell-cell junctions. Here we electrospun conductive polymers to create a conductive fiber mesh and assess if electrical signal propagation is improved in hPSC-CMs seeded on the mesh network. Matrix characterization indicated fiber structure remained stable over weeks in buffer, scaffold stiffness remained near in vivo cardiac stiffness, and electrical conductivity scaled with conductive polymer concentration. Cells remained adherent and viable on the scaffolds for at least 5 days. Transcriptomic profiling of hPSC-CMs cultured on conductive substrates for 3 days showed upregulation of cardiac and muscle-related genes versus non-conductive fibers. Structural proteins were more organized and calcium handling was improved on conductive substrates, even at sub-confluent cell densities; prolonged culture on conductive scaffolds improved membrane depolarization compared to non-conductive substrates. Taken together, these data suggest that blended, conductive scaffolds are stable, supportive of electrical coupling in hPSC-CMs, and promote maturation, which may improve our ability to model cardiac diseases and develop targeted therapies.

Published
2023

6. Electrochemical and electrophysiological considerations for clinical high channel count neural interfaces

Author

Vatsyayan, Ritwik, Lee, Jihwan, Bourhis, Andrew M, Tchoe, Youngbin, Cleary, Daniel R, Tonsfeldt, Karen J, Lee, Keundong, Montgomery-Walsh, Rhea, Paulk, Angelique C, U, Hoi Sang, Cash, Sydney S, and Dayeh, Shadi A

Subjects
Engineering, Biomedical Engineering, Neurosciences, Bioengineering, Neurological, Electrophysiology, Impedance, Electrocorticography, High-density electrodes, Macromolecular and Materials Chemistry, Materials Engineering, Mechanical Engineering, Applied Physics, Materials engineering, Nanotechnology
Abstract

Electrophysiological recording and stimulation are the gold standard for functional mapping during surgical and therapeutic interventions as well as capturing cellular activity in the intact human brain. A critical component probing human brain activity is the interface material at the electrode contact that electrochemically transduces brain signals to and from free charge carriers in the measurement system. Here, we summarize state-of-the-art electrode array systems in the context of translation for use in recording and stimulating human brain activity. We leverage parametric studies with multiple electrode materials to shed light on the varied levels of suitability to enable high signal-to-noise electrophysiological recordings as well as safe electrophysiological stimulation delivery. We discuss the effects of electrode scaling for recording and stimulation in pursuit of high spatial resolution, channel count electrode interfaces, delineating the electrode-tissue circuit components that dictate the electrode performance. Finally, we summarize recent efforts in the connectorization and packaging for high channel count electrode arrays and provide a brief account of efforts toward wireless neuronal monitoring systems.

Published
2023

7. Constructing 2D maps of human spinal cord activity and isolating the functional midline with high-density microelectrode arrays

Author

Russman, Samantha M, Cleary, Daniel R, Tchoe, Youngbin, Bourhis, Andrew M, Stedelin, Brittany, Martin, Joel, Brown, Erik C, Zhang, Xinlian, Kawamoto, Aaron, Ryu, Won Hyung A, Raslan, Ahmed M, Ciacci, Joseph D, and Dayeh, Shadi A

Subjects
Neurodegenerative, Physical Injury - Accidents and Adverse Effects, Traumatic Head and Spine Injury, Clinical Research, Spinal Cord Injury, Neurosciences, Bioengineering, Neurological, Evoked Potentials, Motor, Evoked Potentials, Somatosensory, Humans, Microelectrodes, Neurosurgical Procedures, Retrospective Studies, Spinal Cord, Biological Sciences, Medical and Health Sciences
Abstract

Intraoperative neuromonitoring (IONM) is a widely used practice in spine surgery for early detection and minimization of neurological injury. IONM is most commonly conducted by indirectly recording motor and somatosensory evoked potentials from either muscles or the scalp, which requires large-amplitude electrical stimulation and provides limited spatiotemporal information. IONM may inform of inadvertent events during neurosurgery after they occur, but it does not guide safe surgical procedures when the anatomy of the diseased spinal cord is distorted. To overcome these limitations and to increase our understanding of human spinal cord neurophysiology, we applied a microelectrode array with hundreds of channels to the exposed spinal cord during surgery and resolved spatiotemporal dynamics with high definition. We used this method to construct two-dimensional maps of responsive channels and define with submillimeter precision the electrophysiological midline of the spinal cord. The high sensitivity of our microelectrode array allowed us to record both epidural and subdural responses at stimulation currents that are well below those used clinically and to resolve postoperative evoked potentials when IONM could not. Together, these advances highlight the potential of our microelectrode arrays to capture previously unexplored spinal cord neural activity and its spatiotemporal dynamics at high resolution, offering better electrophysiological markers that can transform IONM.

Published
2022

8. Ultra‐Sharp Nanowire Arrays Natively Permeate, Record, and Stimulate Intracellular Activity in Neuronal and Cardiac Networks

Author

Liu, Ren, Lee, Jihwan, Tchoe, Youngbin, Pre, Deborah, Bourhis, Andrew M, D'Antonio‐Chronowska, Agnieszka, Robin, Gaelle, Lee, Sang Heon, Ro, Yun Goo, Vatsyayan, Ritwik, Tonsfeldt, Karen J, Hossain, Lorraine A, Phipps, M Lisa, Yoo, Jinkyoung, Nogan, John, Martinez, Jennifer S, Frazer, Kelly A, Bang, Anne G, and Dayeh, Shadi A

Subjects
Engineering, Biomedical Engineering, Cardiovascular, Heart Disease, Biotechnology, cardiomyocytes, culture, intracellular, nanowires, neurons, tissues, cardiomyocyte, nanowire, neuron, tissue, Physical Sciences, Chemical Sciences, Materials, Chemical sciences, Physical sciences
Abstract

We report innovative scalable, vertical, ultra-sharp nanowire arrays that are individually addressable to enable long-term, native recordings of intracellular potentials. Stable amplitudes of intracellular potentials from 3D tissue-like networks of neurons and cardiomyocytes are obtained. Individual electrical addressability is necessary for high-fidelity intracellular electrophysiological recordings. This study paves the way toward predictive, high-throughput, and low-cost electrophysiological drug screening platforms.

Published
2022

9. Ultra-Sharp Nanowire Arrays Natively Permeate, Record, and Stimulate Intracellular Activity in Neuronal and Cardiac Networks

Author

Liu, Ren, Lee, Jihwan, Tchoe, Youngbin, Pre, Deborah, Bourhis, Andrew M., D'Antonio-Chronowska, Agnieszka, Robin, Gaelle, Lee, Sang Heon, Ro, Yun Goo, Vatsyayan, Ritwik, Tonsfeldt, Karen J., Hossain, Lorraine A., Phipps, M. Lisa, Yoo, Jinkyoung, Nogan, John, Martinez, Jennifer S., Frazer, Kelly A., Bang, Anne G., and Dayeh, Shadi A.

Subjects
Condensed Matter - Materials Science, Physics - Biological Physics, Physics - Medical Physics, Quantitative Biology - Cell Behavior, Quantitative Biology - Neurons and Cognition
Abstract

Intracellular access with high spatiotemporal resolution can enhance our understanding of how neurons or cardiomyocytes regulate and orchestrate network activity, and how this activity can be affected with pharmacology or other interventional modalities. Nanoscale devices often employ electroporation to transiently permeate the cell membrane and record intracellular potentials, which tend to decrease rapidly to extracellular potential amplitudes with time. Here, we report innovative scalable, vertical, ultra-sharp nanowire arrays that are individually addressable to enable long-term, native recordings of intracellular potentials. We report large action potential amplitudes that are indicative of intracellular access from 3D tissue-like networks of neurons and cardiomyocytes across recording days and that do not decrease to extracellular amplitudes for the duration of the recording of several minutes. Our findings are validated with cross-sectional microscopy, pharmacology, and electrical interventions. Our experiments and simulations demonstrate that individual electrical addressability of nanowires is necessary for high-fidelity intracellular electrophysiological recordings. This study advances our understanding of and control over high-quality multi-channel intracellular recordings, and paves the way toward predictive, high-throughput, and low-cost electrophysiological drug screening platforms., Comment: Main manuscript: 33 pages, 4 figures, Supporting information: 43 pages, 27 figures, Submitted to Advanced Materials

Published
2021

10. Human Brain Mapping with Multi-Thousand Channel PtNRGrids Resolves Novel Spatiotemporal Dynamics

Author

Tchoe, Youngbin, Bourhis, Andrew M., Cleary, Daniel R., Stedelin, Brittany, Lee, Jihwan, Tonsfeldt, Karen J., Brown, Erik C., Siler, Dominic, Paulk, Angelique C., Yang, Jimmy C., Oh, Hongseok, Ro, Yun Goo, Choi, Woojin, Lee, Keundong, Russman, Samantha, Ganji, Mehran, Galton, Ian, Ben-Haim, Sharona, Raslan, Ahmed M., and Dayeh, Shadi A.

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science, Physics - Biological Physics, Physics - Medical Physics
Abstract

Electrophysiological devices are critical for mapping eloquent and diseased brain regions and for therapeutic neuromodulation in clinical settings and are extensively utilized for research in brain-machine interfaces. However, the existing devices are often limited in either spatial resolution or cortical coverage, even including those with thousands of channels used in animal experiments. Here, we developed scalable manufacturing processes and dense connectorization to achieve reconfigurable thin-film, multi-thousand channel neurophysiological recording grids using platinum-nanorods (PtNRGrids). With PtNRGrids, we have achieved a multi-thousand channel array of small (30 {\mu}m) contacts with low impedance, providing unparalleled spatial and temporal resolution over a large cortical area. We demonstrate that PtNRGrids can resolve sub-millimeter functional organization of the barrel cortex in anesthetized rats that captured the histochemically-demonstrated structure. In the clinical setting, PtNRGrids resolved fine, complex temporal dynamics from the cortical surface in an awake human patient performing grasping tasks. Additionally, the PtNRGrids identified the spatial spread and dynamics of epileptic discharges in a patient undergoing epilepsy surgery at 1 mm spatial resolution, including activity induced by direct electrical stimulation. Collectively, these findings demonstrate the power of the PtNRGrids to transform clinical mapping and research with brain-machine interfaces and highlights a path toward novel therapeutics., Comment: Main manuscript: 28 pages, 5 figures, Supporting information: 63 pages, 41 figures

Published
2021

11. Scalable tactile sensor arrays on flexible substrates with high spatiotemporal resolution enabling slip and grip for closed-loop robotics

Author

Oh, Hongseok, Yi, Gyu-Chul, Yip, Michael, and Dayeh, Shadi A

Subjects
Bioengineering, Neurosciences
Abstract

We report large-scale and multiplexed tactile sensors with submillimeter-scale shear sensation and autonomous and real-time closed-loop grip adjustment. We leveraged dual-gate piezoelectric zinc oxide (ZnO) thin-film transistors (TFTs) fabricated on flexible substrates to record normal and shear forces with high sensitivity over a broad range of forces. An individual ZnO TFT can intrinsically sense, amplify, and multiplex force signals, allowing ease of scalability for multiplexing from hundreds of elements with 100-μm spatial and sub-10-ms temporal resolutions. Notably, exclusive feedback from the tactile sensor array enabled rapid adjustment of grip force to slip, enabling the direct autonomous robotic tactile perception with a single modality. For biomedical and implantable device applications, pulse sensing and underwater flow detection were demonstrated. This robust technology, with its reproducible and reliable performance, can be immediately translated for use in industrial and surgical robotics, neuroprosthetics, implantables, and beyond.

Published
2020

13. Correlation Structure in Micro-ECoG Recordings is Described by Spatially Coherent Components.

Author

Rogers, Nicholas, Hermiz, John, Ganji, Mehran, Kaestner, Erik, Kılıç, Kıvılcım, Hossain, Lorraine, Thunemann, Martin, Cleary, Daniel R, Carter, Bob S, Barba, David, Devor, Anna, Halgren, Eric, Dayeh, Shadi A, and Gilja, Vikash

Subjects
Cerebral Cortex, Animals, Humans, Mice, Polymers, Electroencephalography, Records, Electrodes, Implanted, Microelectrodes, Electric Conductivity, Electrophysiological Phenomena, Brain-Computer Interfaces, Electrocorticography, Electrodes, Implanted, Bioinformatics, Mathematical Sciences, Biological Sciences, Information and Computing Sciences
Abstract

Electrocorticography (ECoG) is becoming more prevalent due to improvements in fabrication and recording technology as well as its ease of implantation compared to intracortical electrophysiology, larger cortical coverage, and potential advantages for use in long term chronic implantation. Given the flexibility in the design of ECoG grids, which is only increasing, it remains an open question what geometry of the electrodes is optimal for an application. Conductive polymer, PEDOT:PSS, coated microelectrodes have an advantage that they can be made very small without losing low impedance. This makes them suitable for evaluating the required granularity of ECoG recording in humans and experimental animals. We used two-dimensional (2D) micro-ECoG grids to record intra-operatively in humans and during acute implantations in mouse with separation distance between neighboring electrodes (i.e., pitch) of 0.4 mm and 0.2/0.25 mm respectively. To assess the spatial properties of the signals, we used the average correlation between electrodes as a function of the pitch. In agreement with prior studies, we find a strong frequency dependence in the spatial scale of correlation. By applying independent component analysis (ICA), we find that the spatial pattern of correlation is largely due to contributions from multiple spatially extended, time-locked sources present at any given time. Our analysis indicates the presence of spatially structured activity down to the sub-millimeter spatial scale in ECoG despite the effects of volume conduction, justifying the use of dense micro-ECoG grids.

Published
2019

14. Surface‐Grafted Biocompatible Polymer Conductors for Stable and Compliant Electrodes for Brain Interfaces.

Author

Blau, Rachel, Russman, Samantha M., Qie, Yi, Shipley, Wade, Lim, Allison, Chen, Alexander X., Nyayachavadi, Audithya, Ah, Louis, Abdal, Abdulhameed, Esparza, Guillermo L., Edmunds, Samuel J., Vatsyayan, Ritwik, Dunfield, Sean P., Halder, Moumita, Jokerst, Jesse V., Fenning, David P., Tao, Andrea R., Dayeh, Shadi A., and Lipomi, Darren J.

Published
2024
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16. Conductive block copolymer elastomers and psychophysical thresholding for accurate haptic effects

Author

Blau, Rachel, primary, Abdal, Abdulhameed, additional, Root, Nicholas, additional, Chen, Alexander X., additional, Rafeedi, Tarek, additional, Ramji, Robert, additional, Qie, Yi, additional, Kim, Taewoo, additional, Navarro, Anthony, additional, Chin, Jason, additional, Becerra, Laura L., additional, Edmunds, Samuel J., additional, Russman, Samantha M., additional, Dayeh, Shadi A., additional, Fenning, David P., additional, Rouw, Romke, additional, and Lipomi, Darren J., additional

Published
2024
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18. Microscale dynamics of electrophysiological markers of epilepsy

Author

Yang, Jimmy C., Paulk, Angelique C., Salami, Pariya, Lee, Sang Heon, Ganji, Mehran, Soper, Daniel J., Cleary, Daniel, Simon, Mirela, Maus, Douglas, Lee, Jong Woo, Nahed, Brian V., Jones, Pamela S., Cahill, Daniel P., Cosgrove, Garth Rees, Chu, Catherine J., Williams, Ziv, Halgren, Eric, Dayeh, Shadi, and Cash, Sydney S.

Published
2021
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19. Magnetic Field Evolution of Spin Blockade in Ge/Si Nanowire Double Quantum Dots

Author

Zarassi, Azarin, Su, Zhaoen, Danon, Jeroen, Schwenderling, Jens, Hocevar, Moira, Nguyen, Binh-Minh, Yoo, Jinkyoung, Dayeh, Shadi A., and Frolov, Sergey M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We perform transport measurements on double quantum dots defined in Ge/Si core/shell nanowires and focus on Pauli spin blockade in the regime where tens of holes occupy each dot. We identify spin blockade through the magnetic field dependence of leakage current. We find both a dip and a peak in the leakage current at zero field. We analyze this behavior in terms of the quantum dot parameters such as coupling to the leads, interdot tunnel coupling as well as spin-orbit interaction. We find a lower bound for spin-orbit interaction with $l_{\rm so}=500$ nm. We also extract large and anisotropic effective Land$\rm \acute{e}$ g-factors, with larger g-factors in the direction perpendicular to the nanowire axis in agreement with previous studies and experiments but with larger values reported here.

Published
2016
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20. High critical magnetic field superconducting contacts to Ge/Si core/shell nanowires

Author

Su, Zhaoen, Zarassi, Azarin, Nguyen, Binh-Minh, Yoo, Jinkyoung, Dayeh, Shadi A., and Frolov, Sergey M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity
Abstract

Contacts between high critical field superconductors and semiconductor nanowires are important in the context of topological quantum circuits in which superconductivity must be sustained to high magnetic fields. Here we demonstrate gate-tunable supercurrent in NbTiN-Ge/Si core/shell nanowire-NbTiN junctions. We observe supercurrents up to magnetic fields of 800 mT. The induced soft superconducting gap measured by co-tunneling through a quantum dot is 220 {\mu}eV. To improve contact transparency, we deposit an aluminum interlayer prior to NbTiN and observe a systematic change in the device pinch-off voltages with aluminum thickness. We inform future multi-step device fabrication by observing that aluminum anneals with the Ge/Si nanowire at 180{\deg} celsius, the baking temperature of common electron beam lithography resists.

Published
2016

21. High Density Individually Addressable Nanowire Arrays Record Intracellular Activity from Primary Rodent and Human Stem Cell Derived Neurons

Author

Liu, Ren, Chen, Renjie, Elthakeb, Ahmed T, Lee, Sang Heon, Hinckley, Sandy, Khraiche, Massoud L, Scott, John, Pre, Deborah, Hwang, Yoontae, Tanaka, Atsunori, Ro, Yun Goo, Matsushita, Albert K, Dai, Xing, Soci, Cesare, Biesmans, Steven, James, Anthony, Nogan, John, Jungjohann, Katherine L, Pete, Douglas V, Webb, Denise B, Zou, Yimin, Bang, Anne G, and Dayeh, Shadi A

Published
2017

23. Freestanding High-Power GaN Multi-Fin Camel Diode Varactors for Wideband Telecom Tunable Filters

Author

Chen, Po Chun, Dayeh, Shadi A.1, Chen, Po Chun, Chen, Po Chun, Dayeh, Shadi A.1, and Chen, Po Chun

Abstract

This dissertation accentuates the significance of high-power gallium nitride (GaN) camel diode varactors for RF transmitter applications. Modern RF transmitters favor compact adaptive circuits for cost and power efficiency. Adaptive circuits include tunable filters, tunable matching networks, and antenna tuners, facilitating adjustments in resonate frequency or impedance. Crucially, these components need to exhibit robust power handling capability when operating below 6 GHz. Vertical Schottky diodes stand out as tuning elements in these high-power adaptive circuits due to their compactness, high power handling, and superior quality factor, with GaN holds promise for achieving the highest quality factor figure of merit (QFOM) owing to its outstanding breakdown electric field and favorable electron mobility.Popularly pursued GaN Schottky diode varactors suffer from leakage currents at high reverse voltage biases at their junctions and because of inherent threading dislocations in thin GaN layers on foreign substrates. We devised a novel device architecture to address these limitations. We employ an interdigitated anti-series multi-Fin camel diode structure composed of a thin p+-GaN top layer situated between the Schottky metal and an n-type GaN drift layer. The p-GaN layer raises the barrier height to suppress reverse leakage current to maintain a high Q factor at higher reverse biases than Schottky diodes. Additionally, we utilize GaN on Qromis Substrate Technology (QST) wafers that permit the growth of thick GaN layers with lower dislocation densities and lower leakage currents than GaN-on-Si and that are comparable to GaN-on-GaN. In this dissertation, we first propose a universal design flow for power varactors. Secondly, we experimentally validate the proposed methods for suppressing leakage current. Subsequently, a significant portion of this dissertation is dedicated to device optimizations encompassing epi-structure and device aspects. Detailed iterations of ex

Published
2024

24. Syllable processing is organized in discrete subregions of the human superior temporal gyrus.

Author

Cleary, Daniel R., Tchoe, Youngbin, Bourhis, Andrew, Dickey, Charles W., Stedelin, Brittany, Ganji, Mehran, Lee, Sang Heon, Lee, Jihweean, Siler, Dominic A., Brown, Erik C., Rosen, Burke Q., Kaestner, Erik, Yang, Jimmy C., Soper, Daniel J., Han, Seunggu Jude, Paulk, Angelique C., Cash, Sydney S., Raslan, Ahmed M., Dayeh, Shadi A., and Halgren, Eric

Subjects
TEMPORAL lobe, SPEECH, CRANIOTOMY, INFORMATION processing, ELECTRODES
Abstract

Modular organization at approximately 1 mm scale could be fundamental to cortical processing, but its presence in human association cortex is unknown. Using custom-built, high-density electrode arrays placed on the cortical surface of 7 patients undergoing awake craniotomy for tumor excision, we investigated receptive speech processing in the left (dominant) human posterior superior temporal gyrus. Responses to consonant-vowel syllables and noise-vocoded controls recorded with 1,024 channel micro-grids at 200 μm pitch demonstrated roughly circular domains approximately 1.7 mm in diameter, with sharp boundaries observed in 128 channel linear arrays at 50 μm pitch, possibly consistent with a columnar organization. Peak latencies to syllables in different modules were bimodally distributed centered at 252 and 386 ms. Adjacent modules were sharply delineated from each other by their distinct time courses and stimulus selectivity. We suggest that receptive language cortex may be organized in discrete processing modules. The brain is anatomically organized in columns, but how these columns relate to function in the human association cortex is not clear. This study reveals that the human superior temporal gyrus is functionally organized in ~1.7-mm diameter modules that process language information. [ABSTRACT FROM AUTHOR]

Published
2024
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26. Modular Phoneme Processing in Human Superior Temporal Gyrus

Author

Cleary, Daniel R, primary, Tchoe, Youngbin, additional, Bourhis, Andrew, additional, Dickey, Charles, additional, Stedelin, Brittany, additional, Ganji, Mehran, additional, Lee, Sang Hoen, additional, Lee, Jihwan, additional, Siler, Dominic, additional, Brown, Erik C, additional, Rosen, Burke Q, additional, Kaestner, Erik J, additional, Yang, Jimmy C, additional, Soper, Daniel J, additional, Han, Seunggu Jude, additional, Paulk, Angelique C, additional, Cash, Sydney S, additional, Raslan, Ahmed M, additional, Dayeh, Shadi A, additional, and Halgren, Eric, additional

Published
2024
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27. Gibbs–Thomson Effect in Planar Nanowires: Orientation and Doping Modulated Growth

Author

Shen, Youde, Chen, Renjie, Yu, Xuechao, Wang, Qijie, Jungjohann, Katherine L, Dayeh, Shadi A, and Wu, Tom

Subjects
nanowire, In2O3, ITO, Gibbs-Thomson effect, vapor-liquid-solid mechanism, surface energy, Gibbs−Thomson effect, vapor−liquid−solid mechanism, Nanoscience & Nanotechnology
Abstract

Epitaxy-enabled bottom-up synthesis of self-assembled planar nanowires via the vapor-liquid-solid mechanism is an emerging and promising approach toward large-scale direct integration of nanowire-based devices without postgrowth alignment. Here, by examining large assemblies of indium tin oxide nanowires on yttria-stabilized zirconia substrate, we demonstrate for the first time that the growth dynamics of planar nanowires follows a modified version of the Gibbs-Thomson mechanism, which has been known for the past decades to govern the correlations between thermodynamic supersaturation, growth speed, and nanowire morphology. Furthermore, the substrate orientation strongly influences the growth characteristics of epitaxial planar nanowires as opposed to impact at only the initial nucleation stage in the growth of vertical nanowires. The rich nanowire morphology can be described by a surface-energy-dependent growth model within the Gibbs-Thomson framework, which is further modulated by the tin doping concentration. Our experiments also reveal that the cutoff nanowire diameter depends on the substrate orientation and decreases with increasing tin doping concentration. These results enable a deeper understanding and control over the growth of planar nanowires, and the insights will help advance the fabrication of self-assembled nanowire devices.

Published
2016

28. Nanowire/nanotube array tandem cells for overall solar neutral water splitting

Author

Kargar, Alireza, Khamwannah, Jirapon, Liu, Chin–Hung, Park, Namseok, Wang, Deli, Dayeh, Shadi A, and Jin, Sungho

Subjects
Affordable and Clean Energy, Core/shell/hierarchical nanowires, Core/shell nanotubes, Photoelectrochemical (PEC) tandem cell, Overall solar water splitting, Neutral pH water, Macromolecular and Materials Chemistry, Materials Engineering, Nanotechnology
Abstract

In this study, we report the fabrication and characterization of a novel PEC tandem cell, consisting of p-Si/TiO2/Fe2O3 core/shell/hierarchical nanowire (csh-NW) array photocathode and TiO2/TiO2 core/shell nanotube (cs-NT) array photoanode, for overall solar water splitting in a neutral pH water. The p-Si/n-TiO2/n-Fe2O3 csh-NWs, made mainly by solution-processed methods, offer significantly improved performance in the neutral pH water with a low (positive) onset potential and photoactivity at zero bias, due to the increased reaction surface area, effective energy band alignment among p-Si, n-TiO2 and n-Fe2O3 enhancing the charge separation, improved optical absorption, and enhanced gas evolution. Nitrogen modification (annealing under N2) is used to further enhance the csh-NWs photocathodic performance. The PEC tandem cell is then able to handle overall solar water splitting in the neutral pH water with a solar-to-hydrogen (STH) efficiency of ~0.18%. The achieved results demonstrate initial steps toward the realization of full PEC devices using earth-abundant materials for solar hydrogen generation suggesting competitive performance when solar matched photoanode core material and co-catalysts are used.

Published
2016

29. Strain engineering and epitaxial stabilization of halide perovskites

Author

Chen, Yimu, Lei, Yusheng, Li, Yuheng, Yu, Yugang, Cai, Jinze, Chiu, Ming-Hui, Rao, Rahul, Gu, Yue, Wang, Chunfeng, Choi, Woojin, Hu, Hongjie, Wang, Chonghe, Li, Yang, Song, Jiawei, Zhang, Jingxin, Qi, Baiyan, Lin, Muyang, Zhang, Zhuorui, Islam, Ahmad E., Maruyama, Benji, Dayeh, Shadi, Li, Lain-Jong, Yang, Kesong, Lo, Yu-Hwa, and Xu, Sheng

Published
2020
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30. Engineering Heteromaterials to Control Lithium Ion Transport Pathways.

Author

Liu, Yang, Vishniakou, Siarhei, Yoo, Jinkyoung, and Dayeh, Shadi A

Abstract

Safe and efficient operation of lithium ion batteries requires precisely directed flow of lithium ions and electrons to control the first directional volume changes in anode and cathode materials. Understanding and controlling the lithium ion transport in battery electrodes becomes crucial to the design of high performance and durable batteries. Recent work revealed that the chemical potential barriers encountered at the surfaces of heteromaterials play an important role in directing lithium ion transport at nanoscale. Here, we utilize in situ transmission electron microscopy to demonstrate that we can switch lithiation pathways from radial to axial to grain-by-grain lithiation through the systematic creation of heteromaterial combinations in the Si-Ge nanowire system. Our systematic studies show that engineered materials at nanoscale can overcome the intrinsic orientation-dependent lithiation, and open new pathways to aid in the development of compact, safe, and efficient batteries.

Published
2015

31. Strong Geometrical Effects in Submillimeter Selective Area Growth and Light Extraction of GaN Light Emitting Diodes on Sapphire.

Author

Tanaka, Atsunori, Chen, Renjie, Jungjohann, Katherine L, and Dayeh, Shadi A

Subjects
Biochemistry and Cell Biology, Other Physical Sciences
Abstract

Advanced semiconductor devices often utilize structural and geometrical effects to tailor their characteristics and improve their performance. We report here detailed understanding of such geometrical effects in the epitaxial selective area growth of GaN on sapphire substrates and utilize them to enhance light extraction from GaN light emitting diodes. Systematic size and spacing effects were performed side-by-side on a single 2" sapphire substrate to minimize experimental sampling errors for a set of 144 pattern arrays with circular mask opening windows in SiO2. We show that the mask opening diameter leads to as much as 4 times increase in the thickness of the grown layers for 20 μm spacings and that spacing effects can lead to as much as 3 times increase in thickness for a 350 μm dot diameter. We observed that the facet evolution in comparison with extracted Ga adatom diffusion lengths directly influences the vertical and lateral overgrowth rates and can be controlled with pattern geometry. Such control over the facet development led to 2.5 times stronger electroluminescence characteristics from well-faceted GaN/InGaN multiple quantum well LEDs compared to non-faceted structures.

Published
2015

32. Atomic scale analysis of the enhanced electro- and photo-catalytic activity in high-index faceted porous NiO nanowires.

Author

Shen, Meng, Han, Ali, Wang, Xijun, Ro, Yun Goo, Kargar, Alireza, Lin, Yue, Guo, Hua, Du, Pingwu, Jiang, Jun, Zhang, Jingyu, Dayeh, Shadi A, and Xiang, Bin

Subjects
Biochemistry and Cell Biology, Other Physical Sciences
Abstract

Catalysts play a significant role in clean renewable hydrogen fuel generation through water splitting reaction as the surface of most semiconductors proper for water splitting has poor performance for hydrogen gas evolution. The catalytic performance strongly depends on the atomic arrangement at the surface, which necessitates the correlation of the surface structure to the catalytic activity in well-controlled catalyst surfaces. Herein, we report a novel catalytic performance of simple-synthesized porous NiO nanowires (NWs) as catalyst/co-catalyst for the hydrogen evolution reaction (HER). The correlation of catalytic activity and atomic/surface structure is investigated by detailed high resolution transmission electron microscopy (HRTEM) exhibiting a strong dependence of NiO NW photo- and electrocatalytic HER performance on the density of exposed high-index-facet (HIF) atoms, which corroborates with theoretical calculations. Significantly, the optimized porous NiO NWs offer long-term electrocatalytic stability of over one day and 45 times higher photocatalytic hydrogen production compared to commercial NiO nanoparticles. Our results open new perspectives in the search for the development of structurally stable and chemically active semiconductor-based catalysts for cost-effective and efficient hydrogen fuel production at large scale.

Published
2015

33. A 0.00179 mm2/Ch Chopper-Stabilized TDMA Neural Recording System With Dynamic EOV Cancellation and Predictive Mixed-Signal Impedance Boosting

Author

Fathy, Nader Sherif Kassem, Vatsyayan, Ritwik, Bourhis, Andrew M., Dayeh, Shadi A., and Mercier, Patrick P.

Abstract

This article presents a digitally-assisted multi-channel neural recording system. The system uses a 16-channel chopper-stabilized Time Division Multiple Access (TDMA) scheme to record multiplexed neural signals into a single shared analog front end (AFE). The choppers reduce the total integrated noise across the modulated spectrum by 2.4$ \times $ and 4.3$ \times $ in Local Field Potential (LFP) and Action Potential (AP) bands, respectively. In addition, a novel impedance booster based on Sign-Sign least mean squares (LMS) adaptive filter (AF) predicts the input signal and pre-charges the AC-coupling capacitors. The impedance booster module increases the AFE input impedance by a factor of 39$ \times $ with a 7.1% increase in area. The proposed system obviates the need for on-chip digital demodulation, filtering, and remodulation normally required to extract Electrode Offset Voltages (EOV) from multiplexed neural signals, thereby achieving 3.6$ \times $ and 2.8$ \times $ savings in both area and power, respectively, in the EOV filter module. The Sign-Sign LMS AF is reused to determine the system loop gain, which relaxes the feedback DAC accuracy requirements and saves 10.1$ \times $ in power compared to conventional oversampled DAC truncation-error ΔΣ-modulator. The proposed SoC is designed and fabricated in 65 nm CMOS, and each channel occupies 0.00179 mm2 of active area. Each channel consumes 5.11 μW of power while achieving 2.19 μVrms and 2.4 μVrms of input referred noise (IRN) over AP and LFP bands. The resulting AP band noise efficiency factor (NEF) is 1.8. The proposed system is verified with acute in-vivo recordings in a Sprague-Dawley rat using parylene C based thin-film platinum nanorod microelectrodes.

Published
2024
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34. Lattice strain effects on the optical properties of MoS2 nanosheets.

Author

Yang, Lei, Cui, Xudong, Zhang, Jingyu, Wang, Kan, Shen, Meng, Zeng, Shuangshuang, Dayeh, Shadi A, Feng, Liang, and Xiang, Bin

Subjects
ELECTRICAL AND ELECTRONIC ENGINEERING, TWO-DIMENSIONAL MATERIALS
Abstract

"Strain engineering" in functional materials has been widely explored to tailor the physical properties of electronic materials and improve their electrical and/or optical properties. Here, we exploit both in plane and out of plane uniaxial tensile strains in MoS2 to modulate its band gap and engineer its optical properties. We utilize X-ray diffraction and cross-sectional transmission electron microscopy to quantify the strains in the as-synthesized MoS2 nanosheets and apply measured shifts of Raman-active modes to confirm lattice strain modification of both the out-of-plane and in-plane phonon vibrations of the MoS2 nanosheets. The induced band gap evolution due to in-plane and out-of-plane tensile stresses is validated by photoluminescence (PL) measurements, promising a potential route for unprecedented manipulation of the physical, electrical and optical properties of MoS2.

Published
2014

35. An electroencephalogram microdisplay to visualize neuronal activity on the brain surface.

Author

Tchoe, Youngbin, Wu, Tianhai, U, Hoi Sang, Roth, David M., Kim, Dongwoo, Lee, Jihwan, Cleary, Daniel R., Pizarro, Patricia, Tonsfeldt, Karen J., Lee, Keundong, Chen, Po Chun, Bourhis, Andrew M., Galton, Ian, Coughlin, Brian, Yang, Jimmy C., Paulk, Angelique C., Halgren, Eric, Cash, Sydney S., and Dayeh, Shadi A.

Abstract

Functional mapping during brain surgery is applied to define brain areas that control critical functions and cannot be removed. Currently, these procedures rely on verbal interactions between the neurosurgeon and electrophysiologist, which can be time-consuming. In addition, the electrode grids that are used to measure brain activity and to identify the boundaries of pathological versus functional brain regions have low resolution and limited conformity to the brain surface. Here, we present the development of an intracranial electroencephalogram (iEEG)–microdisplay that consists of freestanding arrays of 2048 GaN light-emitting diodes laminated on the back of micro-electrocorticography electrode grids. With a series of proof-of-concept experiments in rats and pigs, we demonstrate that these iEEG-microdisplays allowed us to perform real-time iEEG recordings and display cortical activities by spatially corresponding light patterns on the surface of the brain in the surgical field. Furthermore, iEEG-microdisplays allowed us to identify and display cortical landmarks and pathological activities from rat and pig models. Using a dual-color iEEG-microdisplay, we demonstrated coregistration of the functional cortical boundaries with one color and displayed the evolution of electrical potentials associated with epileptiform activity with another color. The iEEG-microdisplay holds promise to facilitate monitoring of pathological brain activity in clinical settings. Editor's summary: The visualization of recorded cortical activity in real time on the brain surface could facilitate electrophysiological studies and neurosurgical procedures. Here, Tchoe et al. combined micro-electrocorticography electrode grids with light-emitting diodes to create intracranial electroencephalography microdisplays. The authors show in a series of proof-of-concept experiments in pigs and rats that these microdisplays allow the visualization of spontaneous or elicited cortical activity and functional cortical boundaries on the surface of the brain. Future iterations of this system could also be useful in clinical settings. —Daniela Neuhofer [ABSTRACT FROM AUTHOR]

Published
2024
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41. The Brain Electroencephalogram Microdisplay for Precision Neurosurgery

Author

Tchoe, Youngbin, primary, Wu, Tianhai, additional, U, Hoi Sang, additional, Roth, David M, additional, Kim, Dongwoo, additional, Lee, Jihwan, additional, Cleary, Daniel R, additional, Pizarro, Patricia, additional, Tonsfeldt, Karen J, additional, Lee, Keundong, additional, Chen, Po Chun, additional, Bourhis, Andrew M, additional, Galton, Ian, additional, Coughlin, Brian, additional, Yang, Jimmy C, additional, Paulk, Angelique C, additional, Halgren, Eric, additional, Cash, Sydney S, additional, and Dayeh, Shadi A, additional

Published
2023
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44. Electrochemical and electrophysiological considerations for clinical high channel count neural interfaces.

Author

Lee, Jihwan, Lee, Jihwan, Bourhis, Andrew, Tchoe, Youngbin, Cleary, Daniel, Tonsfeldt, Karen, Lee, Keundong, Montgomery-Walsh, Rhea, Paulk, Angelique, U, Hoi, Cash, Sydney, Dayeh, Shadi, Vatsyayan, Ritwik, Lee, Jihwan, Lee, Jihwan, Bourhis, Andrew, Tchoe, Youngbin, Cleary, Daniel, Tonsfeldt, Karen, Lee, Keundong, Montgomery-Walsh, Rhea, Paulk, Angelique, U, Hoi, Cash, Sydney, Dayeh, Shadi, and Vatsyayan, Ritwik

Abstract

Electrophysiological recording and stimulation are the gold standard for functional mapping during surgical and therapeutic interventions as well as capturing cellular activity in the intact human brain. A critical component probing human brain activity is the interface material at the electrode contact that electrochemically transduces brain signals to and from free charge carriers in the measurement system. Here, we summarize state-of-the-art electrode array systems in the context of translation for use in recording and stimulating human brain activity. We leverage parametric studies with multiple electrode materials to shed light on the varied levels of suitability to enable high signal-to-noise electrophysiological recordings as well as safe electrophysiological stimulation delivery. We discuss the effects of electrode scaling for recording and stimulation in pursuit of high spatial resolution, channel count electrode interfaces, delineating the electrode-tissue circuit components that dictate the electrode performance. Finally, we summarize recent efforts in the connectorization and packaging for high channel count electrode arrays and provide a brief account of efforts toward wireless neuronal monitoring systems.

Published
2023

47. Flexible, Scalable, High Channel Count Stereo-Electrode for Recording in the Human Brain

Author

Lee, Keundong, primary, Paulk, Angelique C., additional, Ro, Yun Goo, additional, Cleary, Daniel R., additional, Tonsfeldt, Karen J., additional, Kfir, Yoav, additional, Pezaris, John, additional, Tchoe, Youngbin, additional, Lee, Jihwan, additional, Bourhis, Andrew M., additional, Vatsyayan, Ritwik, additional, Martin, Joel R., additional, Russman, Samantha M., additional, Yang, Jimmy C., additional, Baohan, Amy, additional, Richardson, R. Mark, additional, Williams, Ziv M., additional, Fried, Shelley I., additional, Sang U, Hoi, additional, Raslan, Ahmed M., additional, Ben-Haim, Sharona, additional, Halgren, Eric, additional, Cash, Sydney S., additional, and Dayeh, Shadi. A., additional

Published
2022
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49. O020 / #940 DEVELOPMENT AND CLINICAL TRANSLATION OF A 4096 CHANNEL MICROELECTRODE ARRAY

Author

Tchoe, Youngbin, primary, Bourhis, Andrew, additional, Cleary, Daniel, additional, Stedelin, Brittany, additional, Lee, Jihwan, additional, Tonsfeldt, Karen, additional, Brown, Erik, additional, Siler, Dominic, additional, Paulk, Angelique, additional, Yang, Jimmy, additional, Oh, Hongseok, additional, Ro, Yun Goo, additional, Russman, Samantha, additional, Ganji, Mehran, additional, Galton, Ian, additional, Ben-Haim, Sharona, additional, Raslan, Ahmed, additional, and Dayeh, Shadi, additional

Published
2022
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50. O047 / #778 FIRST-IN-HUMAN ACUTE USE OF NOVEL PLATINUM-NANOROD (PTNR) MULTI-THOUSAND CHANNELS NEURAL SURFACE BIOINTERFACE REVEALS SUPERIOR SPATIOTEMPORAL DYNAMICS OF CORTICAL PHYSIOLOGY

Author

Raslan, Ahmed, primary, Tchoe, Youngbin, additional, Bourhis, Andrew, additional, Stedelin, Brittany, additional, Brown, Erik, additional, Nerison, Caleb, additional, Paulk, Angelique, additional, Cleary, Daniel, additional, Lee, Jihwan, additional, Lee, Keundong, additional, Galton, Ian, additional, Russman, Samantha, additional, Ben-Haim, Sharona, additional, and Dayeh, Shadi, additional

Published
2022
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