scholarly article | Q13442814 |
P2093 | author name string | Gene Y Fridman | |
Felix P Aplin | |||
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Stimulus induced pH changes in cochlear implants: an in vitro and in vivo study | Q43765464 | ||
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Charge injection limits of activated iridium oxide electrodes with 0.2 ms pulses in bicarbonate buffered saline (neurological stimulation application) | Q68450732 | ||
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Direct current influence on bone formation in titanium implants | Q70232672 | ||
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Do direct current electric fields enhance micturition in the spinal cat? | Q73545644 | ||
Generation of natural pH gradients in microfluidic channels for use in isoelectric focusing | Q74226856 | ||
Threshold suprachoroidal-transretinal stimulation current resulting in retinal damage in rabbits | Q79838111 | ||
Outcomes of electrical stimulation of the neurogenic bladder: results of a two-year follow-up study | Q87115479 | ||
Modeling trans-spinal direct current stimulation for the modulation of the lumbar spinal motor pathways | Q88347199 | ||
Ionic Direct Current Modulation for Combined Inhibition/Excitation of the Vestibular System | Q90235908 | ||
Normally closed plunger-membrane microvalve self-actuated electrically using a shape memory alloy wire | Q90569792 | ||
Carbon nanotubes: present and future commercial applications | Q28284699 | ||
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Cutaneous wound healing | Q29618894 | ||
Plasticity within excitatory and inhibitory pathways of the vestibulo-spinal circuitry guides changes in motor performance. | Q30356388 | ||
Safe direct current stimulation to expand capabilities of neural prostheses | Q30436953 | ||
Cochlear implants: a remarkable past and a brilliant future | Q30452445 | ||
Localization and targeting of voltage-dependent ion channels in mammalian central neurons. | Q30492681 | ||
THE ACTION POTENTIAL IN THE MYELINATED NERVE FIBER OF XENOPUS LAEVIS AS COMPUTED ON THE BASIS OF VOLTAGE CLAMP DATA. | Q30868780 | ||
International lower urinary tract function basic spinal cord injury data set. | Q33307247 | ||
The electric resistivity of human tissues (100 Hz-10 MHz): a meta-analysis of review studies | Q33791888 | ||
The basic mechanism for the electrical stimulation of the nervous system. | Q33855021 | ||
Origin of the osseous bioelectric potentials: a review | Q34052653 | ||
Strength-duration relationship for extracellular neural stimulation: numerical and analytical models | Q34212961 | ||
Charge density and charge per phase as cofactors in neural injury induced by electrical stimulation | Q34267956 | ||
Brain temperature and its fundamental properties: a review for clinical neuroscientists | Q34304941 | ||
Tissue impedance: a historical overview | Q34367778 | ||
New horizons in neuromodulation | Q34402634 | ||
An organic electronic biomimetic neuron enables auto-regulated neuromodulation | Q34474621 | ||
Tissue damage thresholds during therapeutic electrical stimulation | Q34510131 | ||
Electrical stimulation with non-implanted electrodes for overactive bladder in adults. | Q34546973 | ||
The effects of extracellular acidosis on neurons and glia in vitro | Q34596302 | ||
Wound healing in rat cornea: the role of electric currents | Q34599774 | ||
Design for a simplified cochlear implant system | Q34635374 | ||
Controlling cell behavior electrically: current views and future potential | Q34650760 | ||
Electrical signals control wound healing through phosphatidylinositol-3-OH kinase-gamma and PTEN. | Q34652580 | ||
Better speech recognition with cochlear implants | Q34788470 | ||
A brief history of cardiac pacing | Q35597807 | ||
Specific Intensity Direct Current (DC) Electric Field Improves Neural Stem Cell Migration and Enhances Differentiation towards βIII-Tubulin+ Neurons | Q35661910 | ||
Contribution of axonal orientation to pathway-dependent modulation of excitatory transmission by direct current stimulation in isolated rat hippocampus | Q35902599 | ||
Electrical stimulation of excitable tissue: design of efficacious and safe protocols | Q36015323 | ||
Acid-Base Homeostasis | Q36349470 | ||
The specific resistance of biological material—A compendium of data for the biomedical engineer and physiologist | Q36585712 | ||
Characterization of high capacitance electrodes for the application of direct current electrical nerve block. | Q36655763 | ||
Plasticity within non-cerebellar pathways rapidly shapes motor performance in vivo | Q36897669 | ||
Stimulus induced pH changes in retinal implants. | Q50706697 | ||
Health status, community integration, and economic risk factors for mortality after spinal cord injury. | Q50751339 | ||
An integrative model of auditory phantom perception: tinnitus as a unified percept of interacting separable subnetworks. | Q50904381 | ||
Transcranial direct current stimulation in tinnitus patients: a systemic review and meta-analysis. | Q51541627 | ||
Single- and multifrequency models for bioelectrical impedance analysis of body water compartments. | Q52204873 | ||
The use of tDCS as a therapeutic option for tinnitus: a systematic review. | Q52343394 | ||
Music enjoyment with cochlear implantation. | Q52362426 | ||
Combining electrical stimulation and tissue engineering to treat large bone defects in a rat model. | Q52573369 | ||
Differential expression of voltage-gated sodium channels in afferent neurons renders selective neural block by ionic direct current. | Q52590652 | ||
Calculations of the pH changes produced in body tissue by a spherical stimulation electrode. | Q52679224 | ||
Theory and design of capacitor electrodes for chronic stimulation. | Q52895774 | ||
Mechanisms of electrical vasoconstriction. | Q55007076 | ||
Direct current stimulation of endothelial monolayers induces a transient and reversible increase in transport due to the electroosmotic effect. | Q55359681 | ||
Percutaneous direct current stimulation - a new electroceutical solution for severe neurological pain and soft tissue injuries. | Q55444881 | ||
Electrical fields in the vicinity of epithelial wounds in the isolated bovine eye | Q56568074 | ||
Analysis of a Model for Excitation of Myelinated Nerve | Q56784355 | ||
Analysis of Models for External Stimulation of Axons | Q56784361 | ||
Development and Characterization of PEDOT:PSS/Alginate Soft Microelectrodes for Application in Neuroprosthetics | Q57072883 | ||
Recent Advances in Materials, Devices, and Systems for Neural Interfaces | Q57177507 | ||
Organic electronics for precise delivery of neurotransmitters to modulate mammalian sensory function | Q57713752 | ||
Tinnitus: presence and future | Q36980045 | ||
The role of neural plasticity in tinnitus | Q36980051 | ||
Efferent-mediated responses in vestibular nerve afferents of the alert macaque | Q37131860 | ||
The "mirror" estimate: an intuitive predictor of membrane polarization during extracellular stimulation | Q37263520 | ||
Classification of methods in transcranial electrical stimulation (tES) and evolving strategy from historical approaches to contemporary innovations | Q37322603 | ||
Electrical fields, nerve growth and nerve regeneration | Q37358084 | ||
Electrical fields in wound healing-An overriding signal that directs cell migration | Q37369299 | ||
A multichannel semicircular canal neural prosthesis using electrical stimulation to restore 3-d vestibular sensation. | Q37399412 | ||
The science of electrical stimulation therapy for fracture healing | Q37617041 | ||
Organic bioelectronics in nanomedicine | Q37798999 | ||
Electrical stimulation in bone healing: critical analysis by evaluating levels of evidence | Q37918817 | ||
Modeling extracellular electrical neural stimulation: from basic understanding to MEA-based applications | Q37950737 | ||
Neurological perspectives on voltage-gated sodium channels. | Q38042001 | ||
Organic bioelectronics for electronic-to-chemical translation in modulation of neuronal signaling and machine-to-brain interfacing | Q38065692 | ||
Physiological challenges for intracortical electrodes | Q38128649 | ||
Transcranial Direct Current Stimulation in Epilepsy | Q38362054 | ||
Auditory-nerve response from cats raised in a low-noise chamber | Q38581367 | ||
Dielectric properties of tissues and biological materials: a critical review | Q38618441 | ||
Current status and future perspectives of spinal cord stimulation in treatment of chronic pain | Q38768083 | ||
The Role of Direct Current Electric Field-Guided Stem Cell Migration in Neural Regeneration | Q38815843 | ||
Continuous Direct Current Nerve Block Using Multi Contact High Capacitance Electrodes | Q38842450 | ||
Safety of Transcranial Direct Current Stimulation: Evidence Based Update 2016. | Q38884450 | ||
Animal models of transcranial direct current stimulation: Methods and mechanisms | Q38970032 | ||
Vestibular implants studied in animal models: clinical and scientific implications | Q38985557 | ||
Spinal cord stimulation for complex regional pain syndrome type I: a prospective cohort study with long-term follow-up | Q39233366 | ||
Epileptic neuronal networks: methods of identification and clinical relevance | Q39259879 | ||
Dielectric properties of body tissues | Q39770460 | ||
Safe direct current stimulator 2: concept and design | Q39956036 | ||
Continuous low-voltage dc electroporation on a microfluidic chip with polyelectrolytic salt bridges | Q40079680 | ||
Electronic control of Ca2+ signalling in neuronal cells using an organic electronic ion pump | Q40104319 | ||
Criteria for selecting electrodes for electrical stimulation: theoretical and practical considerations | Q40228346 | ||
A CMOS Neural Interface for a Multichannel Vestibular Prosthesis | Q40280626 | ||
Cathodic oxygen consumption and electrically induced osteogenesis | Q40320422 | ||
Development of a multichannel vestibular prosthesis prototype by modification of a commercially available cochlear implant. | Q40466599 | ||
Neuromodulation of Axon Terminals. | Q40481740 | ||
Vestibular compensation: a review of the oculomotor, neural, and clinical consequences of unilateral vestibular loss. | Q40521108 | ||
Treatment of the Neurogenic Bladder with Direct Current on the Spinal Cord (Myelotron) | Q40658600 | ||
Electrical effects at the bone surface | Q40829573 | ||
Electrical Guidance of Human Stem Cells in the Rat Brain | Q41019243 | ||
Electrophoresis along cell membranes | Q41052841 | ||
Effects of Biphasic Current Pulse Frequency, Amplitude, Duration, and Interphase Gap on Eye Movement Responses to Prosthetic Electrical Stimulation of the Vestibular Nerve | Q41834787 | ||
P275 | copyright license | Creative Commons Attribution 4.0 International | Q20007257 |
P6216 | copyright status | copyrighted | Q50423863 |
P407 | language of work or name | English | Q1860 |
P921 | main subject | direct current | Q159241 |
P304 | page(s) | 379 | |
P577 | publication date | 2019-01-01 | |
P1433 | published in | Frontiers in Neuroscience | Q2177807 |
P1476 | title | Implantable Direct Current Neural Modulation: Theory, Feasibility, and Efficacy | |
P478 | volume | 13 |
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