![]() ![]() There is however scant neurophysiological investigation into the mechanism of any of these waveforms to date. Over the past decade, alternative stimulus waveforms have been proposed, ranging from square pulses delivered at higher frequencies (1–10 kHz), or a series of short bursts of pulses delivered at a given frequency, both delivering pain relief without necessarily eliciting a paraesthesia sensation ( De Ridder et al., 2010 Kapural et al., 2015). In its original form, SCS used stimulus pulses of a few 100 μs repeated at a frequency of 50 Hz to activate the dorsal columns, eliciting a tingling sensation (paraesthesia), and inducing pain relief. Although the exact mechanisms of action of spinal cord stimulation (SCS) are still debated, the efficacy in treating chronic neuropathic pain has been demonstrated in a plethora of studies and SCS has become a widely-used therapy across the globe ( Kapural et al., 2015 North et al., 2016 Deer et al., 2018 Thomson et al., 2018 Mekhail et al., 2019 Russo et al., 2020). This concept, developed from the seminal paper by Melzack and Wall (1965) has since been refined and expanded upon. It is commonly accepted that electrical stimulation of afferent cutaneous sensory fibres in the dorsal columns provides pain relief in neuropathic pain conditions. The inverse relationship between ECAP amplitude and sensation for increasing frequencies at fixed stimulus amplitude questions common assumptions of monotonic relationships between ECAP amplitude and sensation strength. Both relationships followed logarithmic trends against stimulus frequency meaning that the effects on ECAP amplitude and sensation are larger for smaller frequencies.Ĭonclusion: This work supports the hypothesis that SCS-induced paraesthesia is conveyed through both frequency coding and population coding, fitting known psychophysics of tactile sensory information processing. Results: Frequency response curves showed an inverse relationship between stimulation sensation strength and ECAP amplitude, with higher frequencies generating smaller ECAPs but stronger stimulation-induced paraesthesia (at constant stimulation amplitude). During the experiments subjects were asked to rate the stimulation-induced sensation (paraesthesia) on a scale from 0 to 10. Stimulation was performed at various vertebral levels, varying the frequency (ranging from 2 to 455 Hz) while all other stimulating variables were kept constant. Neurophysiological recordings were taken during the patient’s trial phase at two routine follow-ups using a custom external stimulator capable of recording ECAPs in real-time from all non-stimulating contacts. Both lead together thus spanning about three vertebral levels. Patients were implanted according to standard practice, having two 8-contact leads (8 mm inter-electrode spacing) which overlapped 2–4 contacts around the T9/T10 interspace. Methods: Patients suffering with chronic neuropathic lower-back and/or lower-limb pain undergoing an epidural SCS trial were recruited. This study investigates the effect of stimulus frequency on both the ECAP amplitude as well as the perceived stimulus sensation in patients undergoing SCS therapy for chronic back and/or leg pain. ![]() ![]() ECAP amplitude grows linearly with stimulus current after a threshold, and a larger ECAP results in a stronger stimulus sensation for patients. Thomas’ NHS Foundation Trust, London, United Kingdomīackground: The effect of spinal cord stimulation (SCS) amplitude on the activation of dorsal column fibres has been widely studied through the recording of Evoked Compound Action Potentials (ECAPs), the sum of all action potentials elicited by an electrical stimulus applied to the fibres. 1Saluda Medical Pty Ltd., Artarmon, NSW, Australia.Parker 1 Dave Mugan 1 Adnan Al-Kaisy 2 Stefano Palmisani 2* Gerrit Eduard Gmel 1 Rosana Santos Escapa 1 John L. ![]()
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