Comparison of spinal cord stimulation profiles from intra- and extradural electrode arrangements by finite element modelling

Huang, Qiujun; Oya, Hiroyuki; Flouty, Oliver; Reddy, Chandan G.; Howard, Matthew A.; Gillies, G. T.; Utz, Marcel

doi:10.1007/s11517-014-1157-7

Cited by 35 publications

(30 citation statements)

References 46 publications

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“…The therapeutic window for stimulation parameters thus widens, whereas it is now relatively narrow for epidural stimulation [11]. With the ability to selectively activate a larger number of Aβ fibers, the net "dose" of current density delivered in a more focused way within the desired target zone in the dorsal columns will be higher, with greater potential for improved pain relief [14].…”

Section: Results Of Preliminary Testingmentioning

confidence: 99%

“…Brought to you by | New York University Bobst Library Technical Services Authenticated Download Date | 6/28/15 2:32 AM Careful computational investigations have now confirmed that intradural SCS should indeed permit more selective activation of dorsal column axons without unwanted fiber activation, compared with epidural SCS [14]. We have also carried out studies of the biophysics underlying this concept, of the testing protocols, and fixation techniques used in in vivo experimentation, and of the histological evidence of safety with direct electrical stimulation of the spinal cord [5,6,9,12,13,21,23,24,29,33].…”

Section: New Device Conceptmentioning

confidence: 99%

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Revisiting intradural spinal cord stimulation: an introduction to a novel intradural spinal cord stimulation device

Dalm

Viljoen²,

Dahdaleh³

et al. 2014

Innovative Neurosurgery

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Background: Spinal cord stimulation has been in use for decades and is growing as a therapeutic treatment option. A significant problem arising from the epidural location of the lead is electrical shunting through the cerebrospinal fluid, providing sub-optimal delivery of the electrical current specifically to the Aβ fibers of the dorsal column. Objective: Our goal is to design a safe and effective intradural spinal cord stimulator (SCS) that places the stimulating electrodes directly against the pia similar to what is currently employed with the auditory brainstem implant. Methods: We have reviewed the literature on the early original intradural SCSs and designed, built, and tested an improved device that seeks to overcome the limitations the existing epidural stimulators. Results: In particular, we have shown that the present design of our device allows for motion of the spinal cord without the device being displaced itself, exerts a surface pressure on the spinal cord surface that is below what would cause ischemia or vessel injury, activates somatosensory evoked potentials at a lower threshold than epidural stimulation, and (iv) does not cause deleterious neurological deficits in a chronic ovine model of intradural stimulator implantation.

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Section: Results Of Preliminary Testingmentioning

confidence: 99%

Section: New Device Conceptmentioning

confidence: 99%

Revisiting intradural spinal cord stimulation: an introduction to a novel intradural spinal cord stimulation device

Dalm

Viljoen²,

Dahdaleh³

et al. 2014

Innovative Neurosurgery

Self Cite

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“…In parallel with that, we are conducting finite element analyses of the current distributions that can be produced within the target tissues by intradural stimulation and comparing them with the existing epidural models. 34 Most recently, we have also undertaken a series of studies involving reciprocating translational movement of our spinal cord surrogate with the HSCMS mounted on it, to determine the ranges of motion available relative to the lead-loop's upper attachment point, before the rostral and caudal tips of the device begin to lift off the surrogate's surface.…”

Section: Discussionmentioning

confidence: 99%

Soft-coupling suspension system for an intradural spinal cord stimulator: Biophysical performance characteristics

Oya

Safayi

Jeffery

et al. 2013

Journal of Applied Physics

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We have characterized the mechanical compliance of an improved version of the suspension system used to position the electrode-bearing membrane of an intradural neuromodulator on the dorsal pial surface of the spinal cord. Over the compression span of 5 mm, it exhibited a restoring force of 2.4 μN μm−1 and a mean pressure of 0.5 mm Hg (=66 Pa) on the surface below it, well within the range of normal intrathecal pressures. We have implanted prototype devices employing this suspension and a novel device fixation technique in a chronic ovine model of spinal cord stimulation and found that it maintains stable contact at the electrode-pia interface without lead fracture, as determined by measurement of the inter-contact impedances.

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“…Models of SCS have been continuously refined and applied from the early 80's through recent efforts 1,2,5,10,[13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30][31] (see Table 1). Development of models of increasing complexity offered mirrored general enhancements in numerical modeling techniques (finite element analysis), with proprietary efforts by numerous groups, each subject to multiple version iterations.…”

Section: Broad Impact Of An Open-source High-resolution Computationalmentioning

confidence: 99%

Realistic Anatomically Detailed Open-Source Spinal Cord Stimulation (RADO-SCS) Model

Khadka

Liu

Zander

et al. 2019

Preprint

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Objective: Computational current flow models of spinal cord stimulation (SCS) are widely used in device development, clinical trial design, and patient programming. Proprietary models of varied sophistication have been developed. An open-source model with state-of-the-art precision would serve as a standard for SCS simulation. Approach:We developed a sophisticated SCS modeling platform, named Realistic Anatomically Detailed Open-Source Spinal Cord Stimulation (RADO-SCS) model. This platform consists of realistic and detailed spinal cord and ancillary tissues anatomy derived based on prior imaging and cadaveric studies. Represented tissues within the T9-T11 spine levels include vertebrae, intravertebral discs, epidural space, dura, CSF, white-matter, gray-matter, dorsal and ventral roots and rootlets, dorsal root ganglion, sympathetic chain, thoracic aorta, epidural space vasculature, white-matter vasculature, and thorax. As an exemplary, a bipolar SCS montage was simulated to illustrate the model workflow from the electric field calculated from a finite element model (FEM) to activation thresholds predicted for individual axons populating the spinal cord.Main Results: Compared to prior models, RADO-SCS meets or exceeds detail for every tissue compartment. The resulting electric fields in white and gray-matter, and axon model activation thresholds are broadly consistent with prior stimulations. Significance:The RADO-SCS can be used to simulate any SCS approach with both unprecedented resolution (precision) and transparency (reproducibility). Freely available online, the RADO-SCS will be updated continuously with version control.

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Comparison of spinal cord stimulation profiles from intra- and extradural electrode arrangements by finite element modelling

Cited by 35 publications

References 46 publications

Revisiting intradural spinal cord stimulation: an introduction to a novel intradural spinal cord stimulation device

Revisiting intradural spinal cord stimulation: an introduction to a novel intradural spinal cord stimulation device

Soft-coupling suspension system for an intradural spinal cord stimulator: Biophysical performance characteristics

Realistic Anatomically Detailed Open-Source Spinal Cord Stimulation (RADO-SCS) Model

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