Free‐Standing Nanofilm Electrode Arrays for Long‐Term Stable Neural Interfacings

Gao, Lei; Wang, Jinfen; Zhao, Yan; Li, Hongbian; Liu, Mengcheng; Ding, Jianfei; Guan, Shouliang; Fang, Ying

doi:10.1002/adma.202107343

Cited by 16 publications

(18 citation statements)

References 55 publications

(78 reference statements)

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“…Although some achievements have been realized by scientists, materials used to make the implantable probes suffer from several challenges such as a mismatch in chemo-mechanical properties and a tradeoff between electron conduction and optical transparency. [21,22] Due to their inherently high electronic conductivity and electrochemical stability, traditional implantable probes are primarily fabricated using inorganic materials. However, the inorganic electrodes show an extremely high elasticity modulus, for instance, >100 MPa for platinum, which is much higher than that of human tissues (10-100 kPa).…”

Section: Introductionmentioning

confidence: 99%

Electron Conductive and Transparent Hydrogels for Recording Brain Neural Signals and Neuromodulation

et al. 2023

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Recording brain neural signals and optogenetic neuromodulations open frontiers in decoding brain neural information and neurodegenerative disease therapeutics. Conventional implantable probes suffer from modulus mismatch with biological tissues and an irreconcilable tradeoff between transparency and electron conductivity. Herein, a strategy is proposed to address these tradeoffs, which generates conductive and transparent hydrogels with polypyrrole‐decorated microgels as cross‐linkers. The optical transparency of the electrodes can be attributed to the special structures that allow light waves to bypass the microgel particles and minimize their interaction. Demonstrated by probing the hippocampus of rat brains, the biomimetic electrode shows a prolonged capacity for simultaneous optogenetic neuromodulation and recording of brain neural signals. More importantly, an intriguing brain–machine interaction is realized, which involves signal input to the brain, brain neural signal generation, and controlling limb behaviors. This breakthrough work represents a significant scientific advancement toward decoding brain neural information and developing neurodegenerative disease therapies.

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Section: Introductionmentioning

confidence: 99%

Electron Conductive and Transparent Hydrogels for Recording Brain Neural Signals and Neuromodulation

et al. 2023

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“…Notably, functional nanomaterials such as graphene can be utilized as the free-standing candidate to enable wide-band brain activity recordings and also promote the scaling elastic adhesion radius of neural electrodes to a subcellular scale, therefore facilitating neuroscience and biomedical applications. [69,70] Shi et al [62] developed a clinically-friendly 49-channel silk fMEA (Figure 3F), applying ≈30 μm silk as the substrate and 2 μm thick PI as the supporting/isolating layers. When the silk layer is solved completely, the fMEA is biocompatible with the cortical surface and spontaneously conformal coupling to achieve in situ real-time and spatiotemporal ECoG detection/monitoring, neural stimulation/decoding the neural and/or brain activities of rats in a series of statues.…”

Section: Typical Fmeas For Neural Recordingmentioning

confidence: 99%

“…Notably, functional nanomaterials such as graphene can be utilized as the free‐standing candidate to enable wide‐band brain activity recordings and also promote the scaling elastic adhesion radius of neural electrodes to a subcellular scale, therefore facilitating neuroscience and biomedical applications. [ 69,70 ] Shi et al. [ 62 ] developed a clinically‐friendly 49‐channel silk fMEA (Figure 3F), applying ≈30 µm silk as the substrate and 2 µm thick PI as the supporting/isolating layers.…”

Section: Electrode Optimization Technologies For Improving Neural Int...mentioning

confidence: 99%

“…A thin chromium (Cr) and gold (Au) layer were deposited by e‐beam evaporation to prepare the electrode sites, interconnects, and bonding pads, while a thick PI layer of 0.75 µm was employed as the insulating layer. Their group [ 69 ] further developed free‐standing Au nanofilm electrode arrays (NEAs) that consist of 120 channels and are encapsulated into a biodissolvable polymer carrier through elastocapillary self‐assembly. Such neural electrodes based on free‐standing nanoscale materials offer opportunities to a variety of implantable and high‐density fMEAs.…”

Section: Electrode Optimization Technologies For Improving Neural Int...mentioning

confidence: 99%

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Challenges and Opportunities of Implantable Neural Interfaces: From Material, Electrochemical and Biological Perspectives

Zeng

Huang

2023

Adv Funct Materials

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The desirable implantable neural interfaces can accurately record bioelectrical signals from neurons and regulate neural activities with high spatial/time resolution, facilitating the understanding of neuronal functions and dynamics. However, the electrochemical performance (impedance, charge storage/injection capacity) is limited with the miniaturization and integration of neural electrodes. The “crosstalk” caused by the uneven distribution of elctric field leads to lower electrical stimulation/recording efficiency. The mismatch between stiff electrodes and soft tissues exacerbates the inflammatory responses, thus weakening the transmission of signals. Though remarkable breakthroughs have been made through the incorporation of optimizing electrode design and functionalized nanomaterials, the chronic stability, and long‐term activity in vivo of the neural electrodes still need further development. In this review, the neural interface challenges mainly on electrochemistry and biology are discussed, followed by summarizing typical electrode optimization technologies and exploring recent advances in the application of nanomaterials, based on traditional metallic materials, emerging 2D materials, conducting polymer hydrogels, etc., for enhancing neural interfaces. The strategies for improving the durability including enhanced adhesion and minimized inflammatory response, are also summarized. The promising directions are finally presented to provide enlightenment for high‐performance neural interfaces in future, which will promote profound progress in neuroscience research.

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“…[21] A variety of nanostructured architectures with strategically designed layout of integrated electrodes or FETs have been developed to offer conformal and stable interfaces with diversely shaped cells/organoids, and to provide long-term, continuous recording of biophysiological signals with high sensitivity and high fidelity. [39][40][41][42][43][44][45][46][47][48][49][50][51][52][53][54][55][56] For example, many different forms of needle type architectures were developed for cell interfacing, ranging from nanoprobes, [57][58][59][60][61] nanopillars, [42,[62][63][64][65] nanotubes, [66] nanocrowns, [24] to nanovolcanos. [67] Aside from these 1D nanostructured configurations, 2D planar type, [68][69][70][71] as well as diverse 3D architectures have been devised to allow monitoring with higher spatial resolutions.…”

Section: Introductionmentioning

confidence: 99%

Bioelectric Interface Technologies in Cells and Organoids

Xue,

Zhao

2023

Adv Materials Inter

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The past two decades have witnessed breakthroughs in cellular‐scale bioelectronics and their widespread applications in life sciences, creating many powerful platforms for studying organisms directly and efficiently. These advanced devices can integrate seamlessly and intimately onto/into target cells and organoids, providing unprecedented functions and revolutionary capabilities. Bioelectronics with nanostructured designs are developed to allow for long‐term, stable monitoring of electrophysiological activities. This review summarizes nanostructured bioelectronics for cell electrophysiology recording, emphasizing the crucial roles of structural designs on functions and capabilities, e.g., intracellular access, high‐density multiplexed recording, multifunctional interfaces and the conformability to curvy biological shapes. Finally, the remaining challenges and opportunities in nanostructured bioelectronics are identified, and perspectives on the future developments toward their practical applications are provided.

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Free‐Standing Nanofilm Electrode Arrays for Long‐Term Stable Neural Interfacings

Cited by 16 publications

References 55 publications

Electron Conductive and Transparent Hydrogels for Recording Brain Neural Signals and Neuromodulation

Electron Conductive and Transparent Hydrogels for Recording Brain Neural Signals and Neuromodulation

Challenges and Opportunities of Implantable Neural Interfaces: From Material, Electrochemical and Biological Perspectives

Bioelectric Interface Technologies in Cells and Organoids

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