A soft, scalable and adaptable multi-contact cuff electrode for targeted peripheral nerve modulation

Paggi, Valentina; Fallegger, Florian; Serex, Ludovic; Rizzo, Olivier; Galan, Katia; Giannotti, Alice; Furfaro, Ivan; Zinno, Ciro; Bernini, Fabio; Micera, Silvestro; Lacour, Stéphanie P.

doi:10.1186/s42234-023-00137-y

Bioelectron Med

2024

DOI: 10.1186/s42234-023-00137-y

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A soft, scalable and adaptable multi-contact cuff electrode for targeted peripheral nerve modulation

Valentina Paggi,

Florian Fallegger,

Ludovic Serex

et al.

Abstract: Background Cuff electrodes target various nerves throughout the body, providing neuromodulation therapies for motor, sensory, or autonomic disorders. However, when using standard, thick silicone cuffs, fabricated in discrete circular sizes, complications may arise, namely cuff displacement or nerve compression, due to a poor adaptability to variable nerve shapes and sizes encountered in vivo. Improvements in cuff design, materials, closing mechanism and surgical approach are necessary to overco… Show more

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Cited by 6 publications

References 39 publications

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Organ Neuroprosthetics: Connecting Transplanted and Artificial Organs with the Nervous System

Micera,

Menciassi,

Cianferotti

et al. 2024

Adv Healthcare Materials

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Implantable neural interfaces with the central and peripheral nervous systems are currently used to restore sensory, motor, and cognitive functions in disabled people with very promising results. They have also been used to modulate autonomic activities to treat diseases such as diabetes or hypertension. Here, this study proposes to extend the use of these technologies to (re‐)establish the connection between new (transplanted or artificial) organs and the nervous system in order to increase the long‐term efficacy and the effective biointegration of these solutions. In this perspective paper, some clinically relevant applications of this approach are briefly described. Then, the choices that neural engineers must implement about the type, implantation location, and closed‐loop control algorithms to successfully realize this approach are highlighted. It is believed that these new “organ neuroprostheses” are going to become more and more valuable and very effective solutions in the years to come.

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Organ Neuroprosthetics: Connecting Transplanted and Artificial Organs with the Nervous System

Micera,

Menciassi,

Cianferotti

et al. 2024

Adv Healthcare Materials

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Soft‐Actuated Cuff Electrodes with Minimal Contact for Bidirectional Peripheral Interfaces

Moon,

Park,

Chou

et al. 2024

Advanced Materials

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Neural interfaces with embedded electrical functions, such as cuff electrodes, are essential for monitoring and stimulating peripheral nerves. Still, several challenges remain with cuff electrodes because sutured devices can damage the nerve by high pressure and the secured contact of electrodes with the nerve is hard to accomplish, which however is essential in maintaining electrical performance. Here, a sutureless soft‐actuated cuff electrodes (SACE) that can envelop the nerve conveniently by creating a bent shape controlled upon fluid injection, is introduced. Moreover, fluid injection protrudes part of the device where electrodes are formed, thereby achieving minimized, soft but secure contact between the electrodes and the nerve. In vivo results demonstrate the successful recording and stimulation of peripheral nerves over time up to 6 weeks. While securing contact with the nerve, the implanted electrodes can preserve the nerve intact with no reduction in blood flow, thereby indicating only minimal compressive force applied to the nerve. The SACE is expected to be a promising tool for recording and stimulation of peripheral nerves toward bidirectional neuroprostheses.

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Thin-film implants for bioelectronic medicine

Oldroyd,

Hadwe,

Barone

et al. 2024

MRS Bulletin

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This article is based on the MRS Mid-Career Researcher Award “for outstanding contributions to the fundamentals and development of organic electronic materials and their application in biology and medicine” presentation given by George G. Malliaras, University of Cambridge, at the 2023 MRS Spring Meeting in San Francisco, Calif. Bioelectronic medicine offers a revolutionary approach to treating disease by stimulating the body with electricity. While current devices show safety and efficacy, limitations, including bulkiness, invasiveness, and scalability, hinder their wider application. Thin-film implants promise to overcome these limitations. Made using microfabrication technologies, these implants conform better to neural tissues, reduce tissue damage and foreign body response, and provide high-density, multimodal interfaces with the body. This article explores how thin-film implants using organic materials and novel designs may contribute to disease management, intraoperative monitoring, and brain mapping applications. Additionally, the technical challenges to be addressed for this technology to succeed are discussed. Graphical abstract

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A soft, scalable and adaptable multi-contact cuff electrode for targeted peripheral nerve modulation

Cited by 6 publications

References 39 publications

Organ Neuroprosthetics: Connecting Transplanted and Artificial Organs with the Nervous System

Organ Neuroprosthetics: Connecting Transplanted and Artificial Organs with the Nervous System

Soft‐Actuated Cuff Electrodes with Minimal Contact for Bidirectional Peripheral Interfaces

Thin-film implants for bioelectronic medicine

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