Krishnan Chakravarthy1, Hira Richter2, Paul J Christo2, Kayode Williams2, Yun Guan2. 1. Department of Anesthesiology and Pain Medicine, University of California San Diego Health System, San Diego, CA, USA. 2. Department of Anesthesiology and Critical Care Medicine, Division of Pain Medicine, Johns Hopkins School of Medicine, Baltimore, MD, USA.
Abstract
BACKGROUND: Traditional spinal cord stimulation (SCS) requires that paresthesia overlaps chronic painful areas. However, the new paradigm high-frequency SCS (HF-SCS) does not rely on paresthesia. STUDY DESIGN: A review of preclinical and clinical studies regarding the use of paresthesia-free HF-SCS for various chronic pain states. METHODS: We reviewed available literatures on HF-SCS, including Nevro's paresthesia-free ultra high-frequency 10 kHz therapy (HF10-SCS). Data sources included relevant literature identified through searches of PubMed, MEDLINE/OVID, and SCOPUS, and manual searches of the bibliographies of known primary and review articles. OUTCOME MEASURES: The primary goal is to describe the present developing conceptions of preclinical mechanisms of HF-SCS and to review clinical efficacy on paresthesia-free HF10-SCS for various chronic pain states. RESULTS: HF10-SCS offers a novel pain reduction tool without paresthesia for failed back surgery syndrome and chronic axial back pain. Preclinical findings indicate that potential mechanisms of action for paresthesia-free HF-SCS differ from those of traditional SCS. CONCLUSIONS: To fully understand and utilize paresthesia-free HF-SCS, mechanistic study and translational research will be very important, with increasing collaboration between basic science and clinical communities to design better trials and optimize the therapy based on mechanistic findings from effective preclinical models and approaches. Future research in these vital areas may include preclinical and clinical components conducted in parallel to optimize the potential of this technology.
BACKGROUND: Traditional spinal cord stimulation (SCS) requires that paresthesia overlaps chronic painful areas. However, the new paradigm high-frequency SCS (HF-SCS) does not rely on paresthesia. STUDY DESIGN: A review of preclinical and clinical studies regarding the use of paresthesia-free HF-SCS for various chronic pain states. METHODS: We reviewed available literatures on HF-SCS, including Nevro's paresthesia-free ultra high-frequency 10 kHz therapy (HF10-SCS). Data sources included relevant literature identified through searches of PubMed, MEDLINE/OVID, and SCOPUS, and manual searches of the bibliographies of known primary and review articles. OUTCOME MEASURES: The primary goal is to describe the present developing conceptions of preclinical mechanisms of HF-SCS and to review clinical efficacy on paresthesia-free HF10-SCS for various chronic pain states. RESULTS: HF10-SCS offers a novel pain reduction tool without paresthesia for failed back surgery syndrome and chronic axial back pain. Preclinical findings indicate that potential mechanisms of action for paresthesia-free HF-SCS differ from those of traditional SCS. CONCLUSIONS: To fully understand and utilize paresthesia-free HF-SCS, mechanistic study and translational research will be very important, with increasing collaboration between basic science and clinical communities to design better trials and optimize the therapy based on mechanistic findings from effective preclinical models and approaches. Future research in these vital areas may include preclinical and clinical components conducted in parallel to optimize the potential of this technology.
Authors: Jacob Caylor; Rajiv Reddy; Sopyda Yin; Christina Cui; Mingxiong Huang; Charles Huang; Rao Ramesh; Dewleen G Baker; Alan Simmons; Dmitri Souza; Samer Narouze; Ricardo Vallejo; Imanuel Lerman Journal: Bioelectron Med Date: 2019-06-28
Authors: Adantchede L Zannou; Niranjan Khadka; Mohamad FallahRad; Dennis Q Truong; Brian H Kopell; Marom Bikson Journal: Neuromodulation Date: 2019-06-21