A new high-density (25 electrodes/mm2) penetrating microelectrode array for recording and stimulating sub-millimeter neuroanatomical structures

OBJECTIVE Among the currently available neural interface devices, there has been a need for a penetrating electrode array with a high electrode-count and high electrode-density (the number of electrodes/mm(2)) that can be used for electrophysiological studies of sub-millimeter neuroanatomical structures. We have developed such a penetrating microelectrode array with both a high electrode-density (25 electrodes/mm(2)) and high electrode-count (up to 96 electrodes) for small nervous system structures, based on the existing Utah Slanted Electrode Array (USEA). Such high electrode-density arrays are expected to provide greater access to nerve fibers than the conventionally spaced USEA especially in small diameter nerves. APPROACH One concern for such high density microelectrode arrays is that they may cause a nerve crush-type injury upon implantation. We evaluated this possibility during acute (<10 h) in vivo experiments with electrode arrays implanted into small diameter peripheral nerves of anesthetized rats (sciatic nerve) and cats (pudendal nerve). MAIN RESULTS Successful intrafascicular implantation and viable nerve function was demonstrated via microstimulation, single-unit recordings and histological analysis. Measurements of the electrode impedances and quantified electrode dimensions demonstrated fabrication quality. The results of these experiments show that such high density neural interfaces can be implanted acutely into neural tissue without causing a complete nerve crush injury, while mediating intrafascicular access to fibers in small diameter peripheral nerves. SIGNIFICANCE This new penetrating microelectrode array has characteristics un-matched by other neural interface devices currently available for peripheral nervous system neurophysiological research.

[1]  J. Pine Recording action potentials from cultured neurons with extracellular microcircuit electrodes , 1980, Journal of Neuroscience Methods.

[2]  R A Normann,et al.  A 100 electrode intracortical array: structural variability. , 1990, Biomedical sciences instrumentation.

[3]  D. Durand,et al.  A slowly penetrating interfascicular nerve electrode for selective activation of peripheral nerves. , 1997, IEEE transactions on rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society.

[4]  S. Wolfe,et al.  Peripheral Nerve Injury and Repair , 2000, The Journal of the American Academy of Orthopaedic Surgeons.

[5]  Qing Bai,et al.  A high-yield microassembly structure for three-dimensional microelectrode arrays , 2000, IEEE Transactions on Biomedical Engineering.

[6]  A. Branner,et al.  A multielectrode array for intrafascicular recording and stimulation in sciatic nerve of cats , 2000, Brain Research Bulletin.

[7]  D. Durand,et al.  Functionally selective peripheral nerve stimulation with a flat interface nerve electrode , 2002, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[8]  R. Normann,et al.  A technique for implantation of a 3-dimensional penetrating electrode array in the modiolar nerve of cats and humans. , 2002, Archives of otolaryngology--head & neck surgery.

[9]  J. Csicsvari,et al.  Massively parallel recording of unit and local field potentials with silicon-based electrodes. , 2003, Journal of neurophysiology.

[10]  K. Horch,et al.  Fabrication and characteristics of an implantable, polymer-based, intrafascicular electrode , 2003, Journal of Neuroscience Methods.

[11]  R A Normann,et al.  High-resolution analysis of the spatio-temporal activity patterns in rat olfactory bulb evoked by enantiomer odors. , 2003, Chemical senses.

[12]  K. Horch,et al.  Acute peripheral nerve recording Characteristics of polymer-based longitudinal intrafascicular electrodes , 2004, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[13]  P. Melo-Pinto,et al.  Functional and morphological assessment of a standardized rat sciatic nerve crush injury with a non-serrated clamp. , 2004, Journal of neurotrauma.

[14]  D. Weber,et al.  Coding of position by simultaneously recorded sensory neurones in the cat dorsal root ganglion , 2004, The Journal of physiology.

[15]  Eduardo Fernández,et al.  Long-term stimulation and recording with a penetrating microelectrode array in cat sciatic nerve , 2004, IEEE Transactions on Biomedical Engineering.

[16]  Development of a Novel Intrafascicular Nerve Electrode , 2005, ASAIO journal.

[17]  R. Normann,et al.  A method for pneumatically inserting an array of penetrating electrodes into cortical tissue , 2006, Annals of Biomedical Engineering.

[18]  K. E. Jones,et al.  A glass/silicon composite intracortical electrode array , 2006, Annals of Biomedical Engineering.

[19]  Shy Shoham,et al.  Discrete stimulus estimation from neural responses in the turtle retina , 2006, Vision Research.

[20]  K. Horch,et al.  An intrafascicular electrode for recording of action potentials in peripheral nerves , 2006, Annals of Biomedical Engineering.

[21]  M. Keith,et al.  Human Nerve Stimulation Thresholds and Selectivity Using a Multi-contact Nerve Cuff Electrode , 2007, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[22]  A. Varejão,et al.  Long-term functional and morphological assessment of a standardized rat sciatic nerve crush injury with a non-serrated clamp , 2007, Journal of Neuroscience Methods.

[23]  J. Anthony Movshon,et al.  Comparison of Recordings from Microelectrode Arrays and Single Electrodes in the Visual Cortex , 2007, The Journal of Neuroscience.

[24]  S. Cogan Neural stimulation and recording electrodes. , 2008, Annual review of biomedical engineering.

[25]  K J Gustafson,et al.  The Feline Dorsal Nerve of the Penis Arises from the Deep Perineal Nerve and Not the Sensory Afferent Branch , 2008, Anatomia, histologia, embryologia.

[26]  Stuart F. Cogan,et al.  Penetrating microelectrode arrays with low-impedance sputtered iridium oxide electrode coatings , 2009, 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[27]  Florian Solzbacher,et al.  Encapsulation of an Integrated Neural Interface Device With Parylene C , 2009, IEEE Transactions on Biomedical Engineering.

[28]  G.A. Clark,et al.  Automated Stimulus-Response Mapping of High-Electrode-Count Neural Implants , 2009, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[29]  David J. Warren,et al.  An automated system for measuring tip impedance and among-electrode shunting in high-electrode count microelectrode arrays , 2009, Journal of Neuroscience Methods.

[30]  Xavier Navarro,et al.  Topographical distribution of motor fascicles in the sciatic‐tibial nerve of the rat , 2010, Muscle & nerve.

[31]  Richard A Normann,et al.  Muscle‐selective block using intrafascicular high‐frequency alternating current , 2010, Muscle & nerve.

[32]  F Solzbacher,et al.  A Wafer-Scale Etching Technique for High Aspect Ratio Implantable MEMS Structures. , 2010, Sensors and actuators. A, Physical.

[33]  Sandeep Negi,et al.  Wafer-scale fabrication of penetrating neural microelectrode arrays , 2010, Biomedical microdevices.

[34]  T. Stieglitz,et al.  A transverse intrafascicular multichannel electrode (TIME) to interface with the peripheral nerve. , 2010, Biosensors & bioelectronics.

[35]  Bradley Greger,et al.  The functional consequences of chronic, physiologically effective intracortical microstimulation. , 2011, Progress in brain research.

[36]  Jiangang Du,et al.  Multiplexed, High Density Electrophysiology with Nanofabricated Neural Probes , 2011, PloS one.

[37]  O. Paul,et al.  CMOS-Based High-Density Silicon Microprobe Arrays for Electronic Depth Control in Intracortical Neural Recording , 2011, Journal of Microelectromechanical Systems.

[38]  T S Davis,et al.  Multiple factors may influence the performance of a visual prosthesis based on intracortical microstimulation: nonhuman primate behavioural experimentation , 2011, Journal of neural engineering.

[39]  K. Kilgore,et al.  Design, fabrication and evaluation of a conforming circumpolar peripheral nerve cuff electrode for acute experimental use , 2011, Journal of Neuroscience Methods.

[40]  Michael J. Black,et al.  Neural control of cursor trajectory and click by a human with tetraplegia 1000 days after implant of an intracortical microelectrode array , 2011 .

[41]  R A Normann,et al.  Multiple-Input Single-Output Closed-Loop Isometric Force Control Using Asynchronous Intrafascicular Multi-Electrode Stimulation , 2011, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[42]  Richard A. Normann,et al.  Selective Activation of the Muscles of Micturition Using Intrafascicular Stimulation of the Pudendal Nerve , 2011, IEEE Journal on Emerging and Selected Topics in Circuits and Systems.

[43]  Nicolas Y. Masse,et al.  Reach and grasp by people with tetraplegia using a neurally controlled robotic arm , 2012, Nature.

[44]  Dominique M. Durand,et al.  A high aspect ratio microelectrode array for mapping neural activity in vitro , 2012, Journal of Neuroscience Methods.

[45]  Excimer-laser deinsulation of Parylene-C coated Utah electrode array tips , 2012 .

[46]  G A Clark,et al.  Coordinated, multi-joint, fatigue-resistant feline stance produced with intrafascicular hind limb nerve stimulation , 2012, Journal of neural engineering.

[47]  N. Ratcliffe,et al.  The importance of methane breath testing: a review , 2013, Journal of breath research.

[48]  Sue Francis,et al.  Physiological measurements using ultra-high field fMRI: a review , 2014, Physiological measurement.