A guide towards long-term functional electrodes interfacing neuronal tissue

Renz, Aline F.; Reichmuth, Andreas M.; Stauffer, Flurin; Thompson-Steckel, Greta; Vörös, János

doi:10.1088/1741-2552/aae0c2

Cited by 47 publications

(48 citation statements)

References 165 publications

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“…For soft bioelectronics, biocompatibility and histology tests are also required to confirm the superior biointegration properties triggering lower immune response compared to state‐of‐the‐art implants. [ 31,32 ] In the case of epidural electrodes, there is no penetration by foreign material within the neural tissue. We only expected encapsulation of the implant by fibrotic tissue build‐up.…”

Section: Figurementioning

confidence: 99%

Soft, Implantable Bioelectronic Interfaces for Translational Research

et al. 2020

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The convergence of materials science, electronics, and biology, namely bioelectronic interfaces, leads novel and precise communication with biological tissue, particularly with the nervous system. However, the translation of lab‐based innovation toward clinical use calls for further advances in materials, manufacturing and characterization paradigms, and design rules. Herein, a translational framework engineered to accelerate the deployment of microfabricated interfaces for translational research is proposed and applied to the soft neurotechnology called electronic dura mater, e‐dura. Anatomy, implant function, and surgical procedure guide the system design. A high‐yield, silicone‐on‐silicon wafer process is developed to ensure reproducible characteristics of the electrodes. A biomimetic multimodal platform that replicates surgical insertion in an anatomy‐based model applies physiological movement, emulates therapeutic use of the electrodes, and enables advanced validation and rapid optimization in vitro of the implants. Functionality of scaled e‐dura is confirmed in nonhuman primates, where epidural neuromodulation of the spinal cord activates selective groups of muscles in the upper limbs with unmet precision. Performance stability is controlled over 6 weeks in vivo. The synergistic steps of design, fabrication, and biomimetic in vitro validation and in vivo evaluation in translational animal models are of general applicability and answer needs in multiple bioelectronic designs and medical technologies.

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Section: Figurementioning

confidence: 99%

Soft, Implantable Bioelectronic Interfaces for Translational Research

et al. 2020

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“…In contrast to traditional rigid devices, they integrate well with biological tissues as a result of low mechanical mismatch and high conformability to curved biological structures. [ 1–3 ] Recently, soft and stretchable devices have been developed to interface with the central nervous system. Minev et al.…”

Section: Introductionmentioning

confidence: 99%

Opto‐E‐Dura: A Soft, Stretchable ECoG Array for Multimodal, Multiscale Neuroscience

Renz

Lee

Tybrandt

et al. 2020

Adv Healthcare Materials

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Soft, stretchable materials hold great promise for the fabrication of biomedical devices due to their capacity to integrate gracefully with and conform to biological tissues. Conformal devices are of particular interest in the development of brain interfaces where rigid structures can lead to tissue damage and loss of signal quality over the lifetime of the implant. Interfaces to study brain function and dysfunction increasingly require multimodal access in order to facilitate measurement of diverse physiological signals that span the disparate temporal and spatial scales of brain dynamics. Here the Opto‐e‐Dura, a soft, stretchable, 16‐channel electrocorticography array that is optically transparent is presented. Its compatibility with diverse optical and electrical readouts is demonstrated enabling multimodal studies that bridge spatial and temporal scales. The device is chronically stable for weeks, compatible with wide‐field and 2‐photon calcium imaging and permits the repeated insertion of penetrating multielectrode arrays. As the variety of sensors and effectors realizable on soft, stretchable substrates expands, similar devices that provide large‐scale, multimodal access to the brain will continue to improve fundamental understanding of brain function.

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“…This is the main factor that limits the correct operation of a long-term implant that should be desirably active for the entire lifetime of the patient. To minimize this mechanism, four strategies can be adopted: the usage of soft materials, the implementation of surface coating to prevent biofouling, the integration of drug delivery system to control the inflammatory mechanism and the engineering of autologous cell layer to suppress the tissue response [14]. On the implant side, other issues arise in term of durability and reliability.…”

Section: Brain Challengesmentioning

confidence: 99%

“…Numerous review papers reported new findings in the part that is usually in contact with the brain, such as the electrode grid [10][11][12][13] and described physiological mechanisms underlying the implantation of these devices in the brain [14], but very few present all the fabrication methodologies that involve new materials and electronic design to allow the manufacturing of the whole system.…”

Section: Introductionmentioning

confidence: 99%

The rise of flexible electronics in neuroscience, from materials selection to in vitro and in vivo applications

Maiolo

Polese

Convertino

2019

Advances in Physics: X

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Neuroscience deals with one of the most complicate system we can study: the brain. The huge amount of connections among the cells and the different phenomena occurring at different scale give rise to a continuous flow of data that have to be collected, analyzed and interpreted. Neuroscientists try to interrogate this complexity to find basic principles underlying brain electrochemical signalling and human/animal behaviour to disclose the mechanisms that trigger neurodegenerative diseases and to understand how restoring damaged brain circuits. The main tool to perform these tasks is a neural interface, a system able to interact with brain tissue at different levels to provide a uni/bidirectional communication path. Recently, breakthroughs coming from various disciplines have been combined to enforce features and potentialities of neural interfaces. Among the different findings, flexible electronics is playing a pivotal role in revolutionizing neural interfaces. In this work, we review the most recent advances in the fabrication of neural interfaces based on flexible electronics. We define challenges and issues to be solved for the application of such platforms and we discuss the different parts of the system regarding improvements in materials selection and breakthrough in applications both for in vitro and in vivo tests.

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A guide towards long-term functional electrodes interfacing neuronal tissue

Cited by 47 publications

References 165 publications

Soft, Implantable Bioelectronic Interfaces for Translational Research

Soft, Implantable Bioelectronic Interfaces for Translational Research

Opto‐E‐Dura: A Soft, Stretchable ECoG Array for Multimodal, Multiscale Neuroscience

The rise of flexible electronics in neuroscience, from materials selection to in vitro and in vivo applications

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