Human distal sciatic nerve fascicular anatomy: Implications for ankle control using nerve-cuff electrodes

Gustafson, Kenneth J.; Grinberg, Yanina; Joseph, Sheeba M.; Triolo, Ronald J.

doi:10.1682/jrrd.2010.10.0201

Cited by 52 publications

(46 citation statements)

References 26 publications

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“…Although Sunderland [63] suggested that nerves were typically plexiform in nature, with axons traversing from fascicle to fascicle, there is sufficient evidence to suggest that, at least at the target locations along these nerves, the axons and fascicles within the nerve are more organized. While histological studies of the tibial and common peroneal nerve did not resolve to the axon level, they do not support the plexiform model within these nerves [47]. They do, however, suggest that there can be a large amount of variation in the location and number of fascicles between nerves.…”

Section: Discussionmentioning

confidence: 99%

“…While control of some ankle function has been noted in humans with stimulation via nerve cuff electrodes located as proximal as the spinal nerve roots, the selectivity of such systems was insufficient for control of standing balance and walking [46]. The fascicular anatomy of the human distal sciatic nerve and its main branches have been mapped to aid in the design of nerve cuff electrodes [47]. Computer models suggests that a FINE on the sciatic nerve will require many contacts for selective restoration of active ankle plantarflexion or dorsiflexion with balanced inversion and eversion [48].…”

Section: Introductionmentioning

confidence: 99%

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Selective activation of the human tibial and common peroneal nerves with a flat interface nerve electrode

Schiefer¹,

Freeberg²,

Pinault³

et al. 2013

J. Neural Eng.

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Problem Addressed Electrical stimulation has been shown effective in restoring basic lower extremity motor function in individuals with paralysis. We tested the hypothesis that a Flat Interface Nerve Electrode (FINE) placed around the human tibial or common peroneal nerve above the knee can selectively activate each of the most important muscles these nerves innervate for use in a neuroprosthesis to control ankle motion. Methodology During intraoperative trials involving three subjects, an 8-contact FINE was placed around the tibial and/or common peroneal nerve, proximal to the popliteal fossa. The FINE’s ability to selectively recruit muscles innervated by these nerves was assessed. Data were used to estimate the potential to restore active plantarflexion or dorsiflexion while balancing inversion and eversion using a biomechanical simulation. Results, Significance, and Potential Impact With minimal spillover to non-targets, at least three of the four targets in the tibial nerve, including two of the three muscles constituting the triceps surae were independently and selectively recruited in all subjects. As acceptable levels of spillover increased, recruitment of the target muscles increased. Selective activation of muscles innervated by the peroneal nerve was more challenging. Estimated joint moments suggests that plantarflexion sufficient for propulsion during stance phase of gait and dorsiflexion sufficient to prevent foot drop during swing can be achieved, accompanied by a small but tolerable inversion or eversion moment.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Selective activation of the human tibial and common peroneal nerves with a flat interface nerve electrode

Schiefer¹,

Freeberg²,

Pinault³

et al. 2013

J. Neural Eng.

View full text Add to dashboard Cite

show abstract

“…41 The anatomy of the sciatic nerve has been well described in the literature. 1,13,14,20,33 The sciatic nerve originates from the anterior divisions of L-4 through S-3 and the posterior divisions of L-4 through S-2, thus forming the tibial and peroneal branches, respectively. 20 The sciatic nerve begins as these fibers coalesce entering the gluteal region through the greater sciatic foramen below the piriformis muscle 33 and then courses inferiorly at the midway point between the ischial tuberosity and greater trochanter of the femur.…”

Section: Discussionmentioning

confidence: 99%

Challenges in sciatic nerve repair: anatomical considerations

Burks¹,

Levi²,

Hayes³

et al. 2014

JNS

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“…The internal topography of the common peroneal nerve has been described. 2,21 The fascicles of the articular branch run with the fascicles of the deep peroneal nerve in the anterolateral portion of the common peroneal nerve at the level of the fibular head. This is the place to look on MRI.…”

Section: Clues To the Presence Of An Intraneural Cystmentioning

confidence: 99%

The nearly invisible intraneural cyst: a new and emerging part of the spectrum

Wilson¹,

Hébert-Blouin

Murthy

et al. 2017

FOC

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OBJECTIVE The authors have observed that a subset of patients referred for evaluation of peroneal neuropathy with “negative” findings on MRI of the knee have subtle evidence of a peroneal intraneural ganglion cyst on subsequent closer inspection. The objective of this study was to introduce the nearly invisible peroneal intraneural ganglion cyst and provide illustrative cases. The authors further wanted to identify clues to the presence of a nearly invisible cyst. METHODS Illustrative cases demonstrating nearly invisible peroneal intraneural ganglion cysts were retrospectively reviewed and are presented. Case history and physical examination, imaging, and intraoperative findings were reviewed for each case. The outcomes of interest were the size and configuration of peroneal intraneural ganglion cysts over time, relative to various interventions that were performed, and in relation to physical examination and electrodiagnostic findings. RESULTS The authors present a series of cases that highlight the dynamic nature of peroneal intraneural ganglion cysts and introduce the nearly invisible cyst as a new and emerging part of the spectrum. The cases demonstrate changes in size and morphology over time of both the intraneural and extraneural compartments of these cysts. Despite “negative” MR imaging findings, nearly invisible cysts can be identified in a subset of patients. CONCLUSIONS The authors demonstrate here that peroneal intraneural ganglion cysts ride a roller coaster of change in both size and morphology over time, and they describe the nearly invisible cyst as one end of the spectrum. They identified clues to the presence of a nearly invisible cyst, including deep peroneal predominant symptoms, fluctuating symptoms, denervation changes in the tibialis anterior muscle, and abnormalities of the superior tibiofibular joint, and they correlate the subtle imaging findings to the internal fascicular topography of the common peroneal nerve. The description of the nearly invisible cyst may allow for increased recognition of this pathological entity that occurs with a spectrum of findings.

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Human distal sciatic nerve fascicular anatomy: Implications for ankle control using nerve-cuff electrodes

Cited by 52 publications

References 26 publications

Selective activation of the human tibial and common peroneal nerves with a flat interface nerve electrode

Selective activation of the human tibial and common peroneal nerves with a flat interface nerve electrode

Challenges in sciatic nerve repair: anatomical considerations

The nearly invisible intraneural cyst: a new and emerging part of the spectrum

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