Mechanical fatigue resistance of an implantable branched lead system for a distributed set of longitudinal intrafascicular electrodes

Pena, A.; Kuntaegowdanahalli, Sathyakumar S.; Abbas, James J.; Patrick, J.; Horch, K.W.; Jung, Ranu

doi:10.1088/1741-2552/aa814d

Cited by 17 publications

(21 citation statements)

References 48 publications

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“…A major problem with chronic neurostimulation of peripheral nerve for purposes of neural interfacing is that of lead wires tugging on microelectrodes penetrating into the body of a nerve. This becomes a more severe problem when large numbers of wires are used for advanced multichannel neural interface systems needed for both sensory and motor control of prosthetics [ 5 ]. Such systems require more channels than can be provided by most nerve cuff systems and need to contact or stimulate nerves lying deeper at the fascicular and subfasicular level.…”

Section: Introductionmentioning

confidence: 99%

Remote Stimulation of Sciatic Nerve Using Cuff Electrodes and Implanted Diodes

Sridharan¹,

Chirania²,

Towe³

et al. 2018

Micromachines

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We demonstrate a method of neurostimulation using implanted, free-floating, inter-neural diodes. They are activated by volume-conducted, high frequency, alternating current (AC) fields and address the issue of instability caused by interconnect wires in chronic nerve stimulation. The aim of this study is to optimize the set of AC electrical parameters and the diode features to achieve wireless neurostimulation. Three different packaged Schottky diodes (1.5 mm, 500 µm and 220 µm feature sizes) were tested in vivo (n = 17 rats). A careful assessment of sciatic nerve activation as a function of diode–dipole lengths and relative position of the diode was conducted. Subsequently, free-floating Schottky microdiodes were implanted in the nerve (n = 3 rats) and stimulated wirelessly. Thresholds for muscle twitch responses increased non-linearly with frequency. Currents through implanted diodes within the nerve suffer large attenuations (~100 fold) requiring 1–2 mA drive currents for thresholds at 17 µA. The muscle recruitment response using electromyograms (EMGs) is intrinsically steep for subepineurial implants and becomes steeper as diode is implanted at increasing depths away from external AC stimulating electrodes. The study demonstrates the feasibility of activating remote, untethered, implanted microscale diodes using external AC fields and achieving neurostimulation.

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Section: Introductionmentioning

confidence: 99%

Remote Stimulation of Sciatic Nerve Using Cuff Electrodes and Implanted Diodes

Sridharan¹,

Chirania²,

Towe³

et al. 2018

Micromachines

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“…Each group of LIFEs can be implanted Fig. 6 Several forms of intrafascicular electrodes a The intrafascicular drawing of LIFE [84] b Schematic of the TIME [8] c Illustration of the SELINE [85] d USEA [86] in different nerves, and each LIFE can be implanted in different fascicles or in the separate areas of the same fascicle [94]. A 6-month rat study showed electrode breakage in a small percent of the electrodes leading to failure [95].…”

Section: Intra-fascicular Electrodesmentioning

confidence: 99%

Interfaces with the peripheral nervous system for the control of a neuroprosthetic limb: a review

Yildiz

Shin

Kaufman

2020

J NeuroEngineering Rehabil

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The field of prosthetics has been evolving and advancing over the past decade, as patients with missing extremities are expecting to control their prostheses in as normal a way as possible. Scientists have attempted to satisfy this expectation by designing a connection between the nervous system of the patient and the prosthetic limb, creating the field of neuroprosthetics. In this paper, we broadly review the techniques used to bridge the patient's peripheral nervous system to a prosthetic limb. First, we describe the electrical methods including myoelectric systems, surgical innovations and the role of nerve electrodes. We then describe non-electrical methods used alone or in combination with electrical methods. Design concerns from an engineering point of view are explored, and novel improvements to obtain a more stable interface are described. Finally, a critique of the methods with respect to their long-term impacts is provided. In this review, nerve electrodes are found to be one of the most promising interfaces in the future for intuitive user control. Clinical trials with larger patient populations, and for longer periods of time for certain interfaces, will help to evaluate the clinical application of nerve electrodes.

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“…for cardiac pacemakers (123) and cochlear implants: (124, 125)), and these studies are typically performed under accelerated conditions to achieve high cycle numbers (i.e. long equivalent implant years) over months of testing (122) or are run to cable failure (121).…”

Section: In Vitro Evaluation Of Device Safety and Reliabilitymentioning

confidence: 99%

The development of neural stimulators: a review of preclinical safety and efficacy studies

et al. 2018

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The pipeline from concept to commercialisation of these devices is long and expensive; careful attention to both device design and its preclinical evaluation will have significant impact on the duration and cost associated with taking a device through to commercialisation. Carefully controlled in vitro and in vivo studies together with ex vivo and human cadaver trials are key components of a thorough preclinical evaluation of any new neural stimulator.

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Mechanical fatigue resistance of an implantable branched lead system for a distributed set of longitudinal intrafascicular electrodes

Cited by 17 publications

References 48 publications

Remote Stimulation of Sciatic Nerve Using Cuff Electrodes and Implanted Diodes

Remote Stimulation of Sciatic Nerve Using Cuff Electrodes and Implanted Diodes

Interfaces with the peripheral nervous system for the control of a neuroprosthetic limb: a review

The development of neural stimulators: a review of preclinical safety and efficacy studies

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