A Removable Insertion Shuttle for Ultraflexible Neural Probe Implantation with Stable Chronic Brain Electrophysiological Recording

Zhang, Shun; Wang, Chengjun; Gao, Huan; Yu, Chaonan; Yan, Qinghao; Lu, Yung-Hsiu; Tao, Zhehao; Linghu, Changhong; Chen, Zhou; Xu, Kedi; Song, Jizhou

doi:10.1002/admi.201901775

Cited by 32 publications

(26 citation statements)

References 33 publications

(47 reference statements)

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“…A second method to temporarily attach shuttles to stiff carriers is by using a so called needle-and-thread approach [ 74 , 82 , 195 ] ( Figure 6 e,f). In this approach the probe functions as the needle and a stiff microwire [ 74 ] or even an actual needle [ 195 ] can function as the thread. For this method to work, the implantable probes have to incorporate a small hole at the probe tip.…”

Section: Implantation Methods For Soft/flexible Neural Implantsmentioning

confidence: 99%

Technological Challenges in the Development of Optogenetic Closed-Loop Therapy Approaches in Epilepsy and Related Network Disorders of the Brain

et al. 2020

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Epilepsy is a chronic, neurological disorder affecting millions of people every year. The current available pharmacological and surgical treatments are lacking in overall efficacy and cause side-effects like cognitive impairment, depression, tremor, abnormal liver and kidney function. In recent years, the application of optogenetic implants have shown promise to target aberrant neuronal circuits in epilepsy with the advantage of both high spatial and temporal resolution and high cell-specificity, a feature that could tackle both the efficacy and side-effect problems in epilepsy treatment. Optrodes consist of electrodes to record local field potentials and an optical component to modulate neurons via activation of opsin expressed by these neurons. The goal of optogenetics in epilepsy is to interrupt seizure activity in its earliest state, providing a so-called closed-loop therapeutic intervention. The chronic implantation in vivo poses specific demands for the engineering of therapeutic optrodes. Enzymatic degradation and glial encapsulation of implants may compromise long-term recording and sufficient illumination of the opsin-expressing neural tissue. Engineering efforts for optimal optrode design have to be directed towards limitation of the foreign body reaction by reducing the implant’s elastic modulus and overall size, while still providing stable long-term recording and large-area illumination, and guaranteeing successful intracerebral implantation. This paper presents an overview of the challenges and recent advances in the field of electrode design, neural-tissue illumination, and neural-probe implantation, with the goal of identifying a suitable candidate to be incorporated in a therapeutic approach for long-term treatment of epilepsy patients.

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Section: Implantation Methods For Soft/flexible Neural Implantsmentioning

confidence: 99%

Technological Challenges in the Development of Optogenetic Closed-Loop Therapy Approaches in Epilepsy and Related Network Disorders of the Brain

et al. 2020

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“…Due to the recent advances in techniques for designing such materials and devices, the electronic devices now feature unprecedented soft mechanical properties that are similar to those of human tissues. [ 1–7 ] This has led to the developments in implantable biosensors and wearable bioelectronics, thereby enabling their monolithic biointegration with target tissues.…”

Section: Introductionmentioning

confidence: 99%

Unconventional Device and Material Approaches for Monolithic Biointegration of Implantable Sensors and Wearable Electronics

Koo

Song

Yoo

et al. 2020

Adv Materials Technologies

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and unwanted side effects and to maximize signal quality and device fidelity in vivo. [37-42] As most tissues and organs are soft, the system modulus of biomedical devices should ideally be matched to that of the specific tissues they interact with. This section reviews unconventional device design approaches based on mechanics for an intimate and conformal contact with the target tissues. 2.1. Ultrathin Brain Implants for Electrocorticography Measurements www.advancedsciencenews.com www.advmattechnol.de

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“…[ 39 ] Several interfaces utilized the biodegradable materials such as polyvinyl alcohol, polyethylene glycol, or silk to harden ultrathin devices instantly for implantation. [ 21,41,42 ]…”

Section: Introductionmentioning

confidence: 99%

“…In other words, the substrates made up of polyimide or parylene‐C, relatively rigid materials, can overcome their natural rigidity by reducing the thickness, but the ultrathin substrate of neural interfaces necessitates an extra guiding or supporting structure. [ 21,41,42 ] In case of neural interfaces based on bioresorbable materials, the devices are limited only to short‐term implantation. In addition, insufficient in vivo data to demonstrate the biocompatibility [ 43 ] and uncontrollable demise hinder the bioelectronic devices made up of these innovative materials.…”

Section: Introductionmentioning

confidence: 99%

Development of a Polydimethylsiloxane‐Based Electrode Array for Electrocorticography

Lee

Moon

Kim

et al. 2020

Adv Materials Inter

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patients with tetraplegia [7-11] as well as to reveal the underlying neuroscience. [12-15] As the domain of bioelectronics has grown ever larger, the neural interfacing devices are required to have distinct prop erties and functions for specific uses. For a chronically implantable interface, the electrodes that are implanted in the brain continuously generate micromotions, and the mechanical mismatch between the rigid electrodes and the soft brain tissue causes foreign body responses. [16-20] Such immune responses degrade the signal quality and obstruct the usage of the device in a long term. Besides, for the electrodes monitoring brain activities on the surface of the brain, a proper contact between the electrodes and the folded brain surface is required to guarantee the signal quality, [21-23] which however is chal lenging to assure. Rigid materials, durable with conven tional silicon microfabrication technolo gies, were used in the earlier inventions of neural electrodes, [2,24,25] but the bio logical and mechanical mismatch between the rigid/stiff electrodes and soft tissues triggered the emer gence of soft interfaces. Soft materials, which are mechanically more compatible with tissues and conformable with curved sur faces, emerged as promising alternatives. Polymers including silicones with a low Young's modulus can reduce the imbalance in flexibility between the electrodes and the tissue. Polyimide, paryleneC, polydimethylsiloxane (PDMS), and SU8, with Young's moduli in MPa or GPa range, [26] are the representa tive polymeric substrates of soft neural electrodes. [27-34] As the cube of the substrate thickness is proportional to the bending stiffness, which is associated with the flexibility, ultrathin sheets of substrate can achieve even softer devices. [21,34-37] Bio degradable or bioresorbable materials have also been used as the substrate materials for shortterm implantation. [38-40] They have been proven to effectively reduce injury, which not only dissolves in the body over time but also eliminate the necessity for further surgery to remove the device when it is no longer in use. [39] Several interfaces utilized the biodegradable materials such as poly vinyl alcohol, polyethylene glycol, or silk to harden ultrathin devices instantly for implantation. [21,41,42] The Young's modulus of PDMS (1.32 MPa) is extremely low compared to that of polyimide, paryleneC, or SU8. [26] Neural interfaces play an essential role to disclose neural networks and to assist paralyzed patients in past decades. As the conformability and longevity become vital issues for neural interfaces, flexible materials are increasingly engaged in the development of such devices. However, the development of devices comprised of polydimethylsiloxane (PDMS) is bothered because of its incompatibility with silicon microfabrication technology, mainly caused by different thermal expansion coefficients between metals and PDMS. Here, a PDMS-based electrode array is developed through a single-wafer processing by employing an intermediate parylene-C...

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A Removable Insertion Shuttle for Ultraflexible Neural Probe Implantation with Stable Chronic Brain Electrophysiological Recording

Cited by 32 publications

References 33 publications

Technological Challenges in the Development of Optogenetic Closed-Loop Therapy Approaches in Epilepsy and Related Network Disorders of the Brain

Technological Challenges in the Development of Optogenetic Closed-Loop Therapy Approaches in Epilepsy and Related Network Disorders of the Brain

Unconventional Device and Material Approaches for Monolithic Biointegration of Implantable Sensors and Wearable Electronics

Development of a Polydimethylsiloxane‐Based Electrode Array for Electrocorticography

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