Computational Study of the Effect of Electrode Polarity on Neural Activation Related to Paresthesia Coverage in Spinal Cord Stimulation Therapy

Jose L Durá; Carmen Solanes; Jose De Andrés; Javier Saiz

doi:10.1111/ner.12909

Computational Study of the Effect of Electrode Polarity on Neural Activation Related to Paresthesia Coverage in Spinal Cord Stimulation Therapy

Neuromodulation. 2019 Apr;22(3):269-279. doi: 10.1111/ner.12909. Epub 2018 Dec 26.

Authors

Jose L Durá¹, Carmen Solanes¹, Jose De Andrés^{2

3}, Javier Saiz¹

Affiliations

¹ Center of Research and Innovation in Bioengineering, Universitat Politècnica de València, Valencia, Spain.
² Anesthesia, Critical Care, and Multidisciplinary Pain Management Department, General University Hospital, Valencia, Spain.
³ Anesthesia Unit- Surgical Specialties Department, Valencia University Medical School, Valencia, Spain.

PMID: 30586207
DOI: 10.1111/ner.12909

Abstract

Objective: Using computer simulation, we investigated the effect of electrode polarity on neural activation in spinal cord stimulation and propose a new strategy to maximize the activating area in the dorsal column (DC) and, thus, paresthesia coverage in clinical practice.

Materials and methods: A new three-dimensional spinal cord model at the T10 vertebral level was developed to simulate neural activation induced by the electric field distribution produced by different typical four-contact electrode polarities in single- and dual-lead stimulation. Our approach consisted of the combination of a finite element model of the spinal cord developed in COMSOL Multiphysics and a nerve fiber model implemented in MATLAB. Five evaluation parameters were evaluated, namely, the recruitment ratio, the perception and discomfort thresholds, and the activating area and depth. The results were compared quantitatively.

Results: The dual-guarded cathode presents the maximum activating area and depth in single- and dual-lead stimulation. However, the lowest value of the ratio between the perception threshold in DC and the perception threshold in the dorsal root (DR) is achieved when the guarded cathode is programmed. Although the two versions of bipolar polarity (namely bipolar 1 and bipolar 2) produce higher activating area and depth than the guarded cathode, they are suitable for producing DR stimulation. Similarly, dual-lead stimulation is likely to activate DR fibers because the electrodes are closer to these fibers.

Conclusions: The results suggest that the activating area in the DC is maximized by using the dual-guarded cathode both in single- and dual-lead stimulation modes. However, DC nerve fibers are preferentially stimulated when the guarded cathode is used. According to these results, the new electrode programming strategy that we propose for clinical practice first uses the dual-guarded cathode, but, if the DR nerve fibers are activated, it then uses guarded cathode polarity.

Keywords: Computational model; dorsal column stimulation; dorsal root stimulation; electrode polarity; spinal cord stimulation.

MeSH terms

Adult
Computer Simulation*
Electrodes, Implanted*
Humans
Imaging, Three-Dimensional / methods*
Nerve Fibers, Myelinated / physiology*
Paresthesia / diagnostic imaging
Paresthesia / physiopathology
Paresthesia / therapy*
Spinal Cord Stimulation / instrumentation
Spinal Cord Stimulation / methods*
Thoracic Vertebrae / diagnostic imaging
Young Adult