2022
DOI: 10.1186/s42234-022-00093-z
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Effects of waveform shape and electrode material on KiloHertz frequency alternating current block of mammalian peripheral nerve

Abstract: Objectives KiloHertz frequency alternating current waveforms produce conduction block in peripheral nerves. It is not clearly known how the waveform shape affects block outcomes, and if waveform effects are frequency dependent. We determined the effects of waveform shape using two types of electrodes. Materials and methods Acute in-vivo experiments were performed on 12 rats. Bipolar electrodes were used to electrically block motor nerve impulses in… Show more

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Cited by 4 publications
(7 citation statements)
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“…We supported this theory by demonstrating that thresholds of non-sinusoidal waveforms were explained by the rms of the signal after lowpass filtering, and that this rms depended largely on the amplitude of the fundamental frequency component resulting from Fourier analysis. This theory explains the observation that square waveforms—with first harmonic amplitude of ~ 1.3 (4/π)—have lower block thresholds than sinusoids [ 4 , 6 ], as well as the observation that triangular waveforms—with first harmonic amplitude of ~ 0.8 (8/π 2 )—have higher block thresholds compared to sinusoids [ 6 ]. However, this theory assumed that lowpass filtering of waveforms was the sole determinant of block threshold, despite the known nonlinear axonal membrane dynamics.…”
Section: Discussionmentioning
confidence: 98%
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“…We supported this theory by demonstrating that thresholds of non-sinusoidal waveforms were explained by the rms of the signal after lowpass filtering, and that this rms depended largely on the amplitude of the fundamental frequency component resulting from Fourier analysis. This theory explains the observation that square waveforms—with first harmonic amplitude of ~ 1.3 (4/π)—have lower block thresholds than sinusoids [ 4 , 6 ], as well as the observation that triangular waveforms—with first harmonic amplitude of ~ 0.8 (8/π 2 )—have higher block thresholds compared to sinusoids [ 6 ]. However, this theory assumed that lowpass filtering of waveforms was the sole determinant of block threshold, despite the known nonlinear axonal membrane dynamics.…”
Section: Discussionmentioning
confidence: 98%
“…Importantly, these findings were dependent on the electrode geometry: most of the monopolar and tripolar tests with composite signals showed an effect of waveform shape on block threshold and onset response, while most bipolar tests did not. This may explain why previous studies investigating waveform effects—which used only bipolar cuffs—observed waveform effects only on block threshold but not on onset response [ 4 , 6 ].…”
Section: Discussionmentioning
confidence: 99%
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“…These materials have been tested to evaluate the block threshold (BT) and the onset response (BR); the two main parameters involved in KHFAC. Both of them should be minimized: the block threshold can be defined as the amplitude value completely blocking the nerve conduction, while the onset response as the initial nerve activity starting after the block is imposed (Green et al, 2022). Patel et al (2018) evaluated different electrode materials among the most commonly used, without identifying any significant difference in BT and OR.…”
Section: Introductionmentioning
confidence: 99%