Toward Bioelectronic Medicine—Neuromodulation of Small Peripheral Nerves Using Flexible Neural Clip

Lee, Sanghoon; Peh, Wendy Yen Xian; Wang, Jiahui; Yang, Fengyuan; Ho, John S.; Thakor, Nitish V.; Yen, Shih Cheng; Lee, Chengkuo

doi:10.1002/advs.201700149

Cited by 79 publications

(63 citation statements)

References 67 publications

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“…Cuff electrodes are broadly researched as peripheral nerve interfaces. They are fabricated with various designs and are still continuing to be developed in advanced forms [58][59][60][61][62][63][64][65][66]. These designs are named and classified according to their morphological properties [10].…”

Section: Extraneural 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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Section: Extraneural 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 cord was then cut by using a fine micro spring scissors to produce a complete transaction. After the SCI, skin incisions were made at the abdominal and head area to allow the head-plug, with connecting wires (DFT™ wire, Fort Wayne Metals) to the flexible neural clip electrodes coated with iridium oxide for the pelvic nerve 16 and the ground electrode (Cooner Wire AS632), to be tunnelled subcutaneously from the abdominal skin incision towards the skull for implantation. Metal screws and dental cement were used for anchoring the head-plug on the rat's skull.…”

Section: Surgery For Pelvic Nerve Stimulation In Sci Ratsmentioning

confidence: 99%

“…The pelvic nerve branches off from the L6-S1 nerve trunk, and contains axons of preganglionic parasympathetic neurons that synapse onto the postganglionic parasympathetic neurons in the major pelvic ganglion in the rodents, which then release acetylcholine to excite the smooth detrusor muscles in the bladder wall 1 . In order to perform nerve stimulation in awake SCI rats, we implanted a bipolar flexible neural clip 16,17 on the pelvic nerve, and used a prototype of a wireless nerve stimulator to deliver biphasic constant current pulses. Bladder size, capacity, and preservation of nonvoiding spontaneous contractions 18 were monitored and quantified.…”

Section: Introductionmentioning

confidence: 99%

Neuromodulation of pelvic nerve during early phase of spinal cord injury in rats using implantable prototype devices - a preliminary study

Peh

Alam

Ahmed

et al. 2019

Preprint

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ObjectivesThe bladder becomes retentive during the early phase of spinal cord injury, and requires proper bladder management to prevent damage to the lower urinary tract and kidney. We investigated the effects of on-demand pelvic nerve stimulation on the areflexive bladder during the earliest phase of complete spinal cord injury in rats and the use of pelvic nerve signals as a proxy to estimate intravesical pressure for closed-loop applications. Materials and MethodsIn order to stimulate the pelvic nerves in female Sprague-Dawley rats with complete spinal cord transection (T7 level), a flexible electrode was implanted unilaterally on pelvic nerve, and electrical stimulation was provided by a custom-built nerve stimulator. Stimulationevoked voiding was monitored in the awake state while size, capacity and spontaneous contractions of the bladder were analysed under anaesthesia. Separately, recordings of the pelvic nerve signals, external urethral sphincter activity and intravesical pressure were performed in animals with intact and transected spinal cord under anaesthesia. ResultsSuccessful pelvic nerve stimulation enabled more frequent voiding, reduced overdistension of bladder, and preserved non-voiding spontaneous bladder contractions.Typical bladder management protocol for SCI rats (manual expression every 8 -12 hours) resulted in more severe bladder overdistention. Signal processing of the recorded extraneural pelvic nerve signals successfully reconstructed changes in intravesical pressure, demonstrating their use in estimating the fullness and contractions of the bladder. ConclusionsThe preliminary results suggest that pelvic nerve stimulators can serve as an alternative method for frequent emptying of the areflexive bladder. Simultaneous recording of the same pelvic nerve will be useful for development of a closed-loop neuroprosthesis.

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“…Examples include optoelectronic devices for neuromodulation, [7] soft mechanical actuators to assist organ functions, [8,9] and microfluidic devices for drug delivery. To interface with the delicate biological tissues, flexible electrodes made of polyimide, [12][13][14] SU-8, [15,16] poly(lactic-co-glycolic acid) (PLGA), [17] and hydrogel [18] are developed to minimize the mechanical mismatch with the brain and peripheral nerves. To interface with the delicate biological tissues, flexible electrodes made of polyimide, [12][13][14] SU-8, [15,16] poly(lactic-co-glycolic acid) (PLGA), [17] and hydrogel [18] are developed to minimize the mechanical mismatch with the brain and peripheral nerves.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Low‐Current Direct Stimulation for Rehabilitation Treatment Related to Muscle Function Loss Using Self‐Powered TENG System

et al. 2019

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Muscle function loss is characterized as abnormal or completely lost muscle capabilities, and it can result from neurological disorders or nerve injuries. The currently available clinical treatment is to electrically stimulate the diseased muscles. Here, a self‐powered system of a stacked‐layer triboelectric nanogenerator (TENG) and a multiple‐channel epimysial electrode to directly stimulate muscles is demonstrated. Then, the two challenges regarding direct TENG muscle stimulation are further investigated. For the first challenge of improving low‐current TENG stimulation efficiency, it is found that the optimum stimulation efficiency can be achieved by conducting a systematic mapping with a multiple‐channel epimysial electrode. The second challenge is TENG stimulation stability. It is found that the force output generated by TENGs is more stable than using the conventional square wave stimulation and enveloped high frequency stimulation. With modelling and in vivo measurements, it is confirmed that the two factors that account for the stable stimulation using TENGs are the long pulse duration and low current amplitude. The current waveform of TENGs can effectively avoid synchronous motoneuron recruitment at the two stimulation electrodes to reduce force fluctuation. Here, after investigating these two challenges, it is believed that TENG direct muscle stimulation could be used for rehabilitative and therapeutic purpose of muscle function loss treatment.

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Toward Bioelectronic Medicine—Neuromodulation of Small Peripheral Nerves Using Flexible Neural Clip

Cited by 79 publications

References 67 publications

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

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

Neuromodulation of pelvic nerve during early phase of spinal cord injury in rats using implantable prototype devices - a preliminary study

Investigation of Low‐Current Direct Stimulation for Rehabilitation Treatment Related to Muscle Function Loss Using Self‐Powered TENG System

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