Nerve conduction block utilising high-frequency alternating current

Kilgore, Kevin L.; Bhadra, Niloy

doi:10.1007/bf02344716

Cited by 246 publications

(319 citation statements)

References 46 publications

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“…11). However, previous studies using animals (Bhadra et al, 2006;Bhadra and Kilgore, 2005;Bowman and McNeal, 1986;Kilgore and Bhadra, 2004;Rehoul and Rosenblueth, 1939;Rosenblueth and Rehoul, 1939;Tai et al, 2004;2005c;Tanner, 1962;Williamson and Andrews, 2005) showed that the minimal blocking frequency varied between 1 kHz and 10 kHz in different nerves of various species using different electrode geometries. Therefore, the temperature might be one of the factors that could influence the minimal blocking frequency.…”

Section: Discussionmentioning

confidence: 96%

“…The block of spontaneous neuronal activity was always coincident with a stimulus-induced rise in extracelluar potassium concentration, suggesting that a constant potassium outflow from the neurons was induced by the stimulation. The stimulation frequency to block the hippocampal neuron is relatively low (<500 Hz) compared to the minimal stimulation frequency required to block the axonal conduction (1-10 kHz) (Bhadra et al, 2006;Bhadra and Kilgore, 2005;Bowman and McNeal, 1986;Kilgore and Bhadra, 2004;Rehoul and Rosenblueth, 1939;Rosenblueth and Rehoul, 1939;Tai et al, 2004;2005c;Tanner, 1962;Williamson and Andrews, 2005). However, this frequency discrepancy might be caused by the slow membrane dynamics of the neuron and the longer duration action potential.…”

Section: Discussionmentioning

confidence: 99%

“…A reversible nerve conduction block method will find many applications in both clinical medicine and basic neuroscience (Kilgore and Bhadra, 2004;Nashold et al, 1982;Tai et al, 2004). Understanding the biophysics and mechanisms underlying the nerve conduction block induced by high-frequency biphasic electrical current could promote its clinical application and possibly the design of new stimulation waveforms of a lower frequency to block nerve conduction.…”

Section: Discussionmentioning

confidence: 99%

“…For example, blocking peripheral nerves could help alleviate chronic pain of peripheral origin (Nashold et al, 1982) or stop unwanted motor effects such as muscle spasms and spasticity (Kilgore and Bhadra, 2004). Blocking pudendal nerve conduction in spinal cord injured people during micturition could reduce urethral sphincter contraction and urethral outlet resistance, and improve voiding efficiency (Tai et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

“…Previous studies indicated that temperature might play a role in this difference in minimal blocking frequency. For example, a study using isolated frog sciatic nerve (Kilgore and Bhadra, 2004) reported that nerve block could be observed at a stimulation frequency as low as 1 kHz at room temperature. Studies using rat sciatic nerves (Bhadra and Kilgore, 2005;Williamson and Andrews, 2005) showed that consistent nerve block could be achieved at stimulation frequencies greater than 10 kHz which was presumably at body temperature near 37 °C.…”

Section: Introductionmentioning

confidence: 99%

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Influence of frequency and temperature on the mechanisms of nerve conduction block induced by high-frequency biphasic electrical current

et al. 2007

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The influences of stimulation frequency and temperature on mechanisms of nerve conduction block induced by high-frequency biphasic electrical current were investigated using a lumped circuit model of the myelinated axon based on Schwarz and Eikhof (SE) equations. The simulation analysis showed that a temperature-frequency relationship was determined by the axonal membrane dynamics (i.e. how fast the ion channels can open or close.). At a certain temperature, the axonal conduction block always occurred when the period of biphasic stimulation was smaller than the action potential duration (APD). When the temperature decreased from 37°C to 15°C, the membrane dynamics slowed down resulting in an APD increase from 0.4 ms to 2.4 ms accompanied by a decrease in the minimal blocking frequency from 4 kHz to 0.5 kHz. The simulation results also indicated that as the stimulation frequency increased the mechanism of conduction block changed from a cathodal/anodal block to a block dependent upon continuous activation of potassium channels. Understanding the interaction between the minimal blocking frequency and temperature could promote a better understanding of the mechanisms of high frequency induced axonal conduction block and the clinical application of this method for blocking the nerve conduction.

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Section: Discussionmentioning

confidence: 96%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Influence of frequency and temperature on the mechanisms of nerve conduction block induced by high-frequency biphasic electrical current

et al. 2007

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Motor Neuroprostheses

Procházka¹

2018

Comprehensive Physiology

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Neuroprostheses (NPs) are electrical stimulators that activate nerves, either to provide sensory input to the central nervous system (sensory NPs), or to activate muscles (motor NPs: MNPs). The first MNPs were belts with inbuilt batteries and electrodes developed in the 1850s to exercise the abdominal muscles. They became enormously popular among the general public, but as a result of exaggerated therapeutic claims they were soon discredited by the medical community. In the 1950s, MNPs reemerged for the serious purpose of activating paralyzed muscles. Neuromuscular electrical stimulation (NMES), when applied in a preset sequence, is called therapeutic electrical stimulation (TES). NMES timed so that it enhances muscle contraction in intended voluntary movements is called functional electrical stimulation (FES) or functional neuromuscular stimulation (FNS). It has been 50 years since the first FES device, a foot‐drop stimulator, was described and 40 years since the first implantable version was tested in humans. A commercial foot‐drop stimulator became available in the 1970s, but for various reasons, it failed to achieve widespread use. With advances in technology, such devices are now more convenient and reliable. Enhancing upper limb function is a more difficult task, but grasp‐release stimulators have been shown to provide significant benefits. This chapter deals with the technical aspects of NMES, the therapeutic and functional benefits of TES and FES, delayed‐onset and carryover effects attributable to “neuromodulation” and the barriers and opportunities in this rapidly developing field. © 2019 American Physiological Society. Compr Physiol 9:127‐148, 2019.

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Identifying the Role of Block Length in Neural Heat Block to Reduce Temperatures During Infrared Neural Inhibition

et al. 2019

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Background and Objectives The objective of this study is to assess the hypothesis that the length of axon heated, defined here as block length (BL), affects the temperature required for thermal inhibition of action potential propagation applied using laser heating. The presence of such a phenomenon has implications for how this technique, called infrared neural inhibition (INI), may be applied in a clinically safe manner since it suggests that temperatures required for therapy may be reduced through the proper spatial application of light. Here, we validate the presence of this phenomenon by assessing how the peak temperatures during INI are reduced when two different BLs are applied using irradiation from either one or two adjacent optical fibers. Study Design/Materials and Methods Assessment of the role of BL was carried out over two phases. First, a computational proof of concept was performed in the neural conduction simulation environment, NEURON, simulating the response of action potentials to increased temperatures applied at different full‐width at half‐maxima (FWHM) along axons. Second, ex vivo validation of these predictions was performed by measuring the radiant exposure, peak temperature rise, and FWHM of heat distributions associated with INI from one or two adjacent optical fibers. Electrophysiological assessment of radiant exposures at inhibition threshold were carried out in ex vivo Aplysia californica (sea slug) pleural abdominal nerves ( n = 6), an invertebrate with unmyelinated axons. Measurement of the maximum temperature rise required for induced heat block was performed in a water bath using a fine wire thermocouple. Finally, magnetic resonance thermometry (MRT) was performed on a nerve immersed in saline to assess the elevated temperature distribution at these radiant exposures. Results Computational modeling in NEURON provided a theoretical proof of concept that the BL is an important factor contributing to the peak temperature required during neural heat block, predicting a 11.7% reduction in temperature rise when the FWHM along an axon is increased by 42.9%. Experimental validation showed that, when using two adjacent fibers instead of one, a 38.5 ± 2.2% (mean ± standard error of the mean) reduction in radiant exposure per pulse per fiber threshold at the fiber output (P = 7.3E−6) is measured, resulting in a reduction in peak temperature rise under each fiber of 23.5 ± 2.1% ( P = 9.3E−5) and 15.0 ± 2.4% ( P = 1.4E−3) and an increase in the FWHM of heating by 37.7 ± 6.4% ( P = 1E−3), 68.4 ± 5.2% ( P = 2.4E−5), and 51.9 ± 9.9% ( P = 1.7E−3) in three MRT slices. Conclusions This study provides the first experimental evidence for a phenomenon during the heat block in which the temperature for inhibition is dependent on the BL. While more work is needed to further reduce the temperature during INI, the results highlight that spatial application of the temperature rise during INI must be considered. Optimized implementation of INI may leverage this cellular response to provide optical modul...

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Nerve conduction block utilising high-frequency alternating current

Cited by 246 publications

References 46 publications

Influence of frequency and temperature on the mechanisms of nerve conduction block induced by high-frequency biphasic electrical current

Influence of frequency and temperature on the mechanisms of nerve conduction block induced by high-frequency biphasic electrical current

Motor Neuroprostheses

Identifying the Role of Block Length in Neural Heat Block to Reduce Temperatures During Infrared Neural Inhibition

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