Thin Film Multi-Electrode Softening Cuffs for Selective Neuromodulation

González-González, María Alejandra; Kanneganti, Aswini; Joshi‐Imre, Alexandra; Hernández-Reynoso, Ana G.; Bendale, Geetanjali; Modi, Romil; Ecker, Melanie; Khurram, Syed Ali; Cogan, Stuart F.; Voit, Walter; Romero-Ortega, Mario I.

doi:10.1038/s41598-018-34566-6

Cited by 74 publications

(86 citation statements)

References 57 publications

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“…Similarly, the Charles Lieber group has demonstrated that a ultraflexible open mesh electrode array can be injected into the rodent brain via syringe and minimize the chronic immune response, enabling high‐quality chronic recordings for periods of at least 12 weeks . More recently, the Romero‐Ortega group has demonstrated that SMP cuffs can be surgically implanted directly on the rat sciatic and pelvic nerves and both record and intermittently stimulate for periods of at least 30 d, while minimizing the immune response compared to stiffer control devices . In comparison to the Injectrode, these promising technologies have the clear advantage of higher channel counts, as well as predictable electrode geometries and spacing.…”

Section: Resultsmentioning

confidence: 99%

An Injectable Neural Stimulation Electrode Made from an In‐Body Curing Polymer/Metal Composite

Trevathan

Baumgart

Nicolai

et al. 2019

Adv Healthcare Materials

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Implanted neural stimulation and recording devices hold vast potential to treat a variety of neurological conditions, but the invasiveness, complexity, and cost of the implantation procedure greatly reduce access to an otherwise promising therapeutic approach. To address this need, a novel electrode that begins as an uncured, flowable prepolymer that can be injected around a neuroanatomical target to minimize surgical manipulation is developed. Referred to as the Injectrode, the electrode conforms to target structures forming an electrically conductive interface which is orders of magnitude less stiff than conventional neuromodulation electrodes. To validate the Injectrode, detailed electrochemical and microscopy characterization of its material properties is performed and the feasibility of using it to stimulate the nervous system electrically in rats and swine is validated. The silicone-metal-particle composite performs very similarly to pure wire of the same metal (silver) in all measures, including exhibiting a favorable cathodic charge storage capacity (CSC C ) and charge injection limits compared to the clinical LivaNova stimulation electrode and silver wire electrodes. By virtue of its simplicity, the Injectrode has the potential to be less invasive, more robust, and more cost-effective than traditional electrode designs, which could increase the adoption of neuromodulation therapies for existing and new indications.

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Section: Resultsmentioning

confidence: 99%

An Injectable Neural Stimulation Electrode Made from an In‐Body Curing Polymer/Metal Composite

Trevathan

Baumgart

Nicolai

et al. 2019

Adv Healthcare Materials

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show abstract

“…Although electrical stimulation-evoked responses can be useful in determining the type of activated fibers, these responses do not represent physiological neural signaling. A few research groups have obtained physiological neural recordings from autonomic nerves using extraneural cuff electrodes [31][32][33][34][35] . However, extraneural electrodes lack spatial selectivity, as these electrodes record the compound activity of hundreds to thousands of axons from outside the nerve.…”

Section: Introductionmentioning

confidence: 99%

Multi-channel intraneural vagus nerve recordings with a novel high-density carbon fiber microelectrode array

Jiman

Ratze

Welle

et al. 2020

Preprint

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25Autonomic nerves convey essential neural signals that regulate vital body functions. Recording 26 clearly distinctive physiological neural signals from autonomic nerves will help develop new 27 treatments for restoring regulatory functions. However, this is very challenging due to the small 28 nature of autonomic nerves and the low-amplitude signals from their small axons. We developed 29 a multi-channel, high-density, intraneural carbon fiber microelectrode array (CFMA) with ultra-30 small electrodes (8-9 µm in diameter, 150-250 µm in length) for recording physiological action 31 potentials from small autonomic nerves. In this study, we inserted CFMA with up to 16 32 recording carbon fibers in the cervical vagus nerve of 22 isoflurane-anesthetized rats. We 33 recorded action potentials with peak-to-peak amplitudes of 15.1-91.7 µV and signal-to-noise 34 ratios of 2.0-8.3 on multiple carbon fibers per experiment, determined conduction velocities of 35 some vagal signals in the afferent (0.7-1.0 m/sec) and efferent (0.7-8.8 m/sec) directions, and 36 monitored firing rate changes in breathing and blood glucose modulated conditions. Overall, 37 these experiments demonstrated that CFMAs are a novel interface for in-vivo intraneural action 38 potential recordings from autonomic nerves. This work is a milestone towards the 39 comprehensive understanding of physiological neural signaling and the development of 40 innovative treatment modalities for restoring vital functions controlled by autonomic nerves. 41 42

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“…Traditional extraneural electrodes such as the 3D cuff electrode ( Figure a), helical electrode (Figure b), and the 2D PI‐based electrode (Figure c) have been widely used in clinical practice. In addition, more recently developed electrodes based on shape memory polymers (Figure d,e) have moved forward on the flexible neural interface. However, the drawbacks are still obvious: large mechanical and geometrical mismatches and complicated surgical implantation and fixation procedures often induce irreversible neural damage, such as inflammation and axonal degradation.…”

Section: Biomedical Applicationsmentioning

confidence: 99%

Section: Biomedical Applicationsmentioning

confidence: 99%

Flexible Hybrid Electronics for Digital Healthcare

et al. 2019

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Recent advances in material innovation and structural design provide routes to flexible hybrid electronics that can combine the high‐performance electrical properties of conventional wafer‐based electronics with the ability to be stretched, bent, and twisted to arbitrary shapes, revolutionizing the transformation of traditional healthcare to digital healthcare. Here, material innovation and structural design for the preparation of flexible hybrid electronics are reviewed, a brief chronology of these advances is given, and biomedical applications in bioelectrical monitoring and stimulation, optical monitoring and treatment, acoustic imitation and monitoring, bionic touch, and body‐fluid testing are described. In conclusion, some remarks on the challenges for future research of flexible hybrid electronics are presented.

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Thin Film Multi-Electrode Softening Cuffs for Selective Neuromodulation

Cited by 74 publications

References 57 publications

An Injectable Neural Stimulation Electrode Made from an In‐Body Curing Polymer/Metal Composite

An Injectable Neural Stimulation Electrode Made from an In‐Body Curing Polymer/Metal Composite

Multi-channel intraneural vagus nerve recordings with a novel high-density carbon fiber microelectrode array

Flexible Hybrid Electronics for Digital Healthcare

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