Iridium Oxide Nanoparticle–Protein Corona Neural Interfaces with Enhanced Electroactivity and Bioactivity Enable Electrically Manipulatable Physical and Chemical Neuronal Activation

Chan, Fu Erh; Syu, Huei Min; Wang, Te Yi; Tang, Zheng Ting; Huang, Chih Ning; Lee, Jyh Fu; Burnouf, Thierry; Hu, Shang Hsiu; Chen, Po Chun; Huang, Wei

doi:10.1002/admi.202100694

Cited by 6 publications

(3 citation statements)

References 43 publications

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“…Another approach involves the electrochemical or layer‐by‐layer deposition of Au, Ag, or IrOx to create nanoparticles (Bao et al, 2019; Chan et al, 2021; D. Lee et al, 2018; H. Zhang et al, 2012) or nanograins (R. Kim et al, 2013) on the electrode surface. Zhang et al used a layer‐by‐layer technique to deposit CNTs or Au NPs in poly(diallyl dimethylammonium chloride) (PDDA) on the electrode (H. Zhang et al, 2012).…”

Section: Inorganic Nanomaterials and Their Compositesmentioning

confidence: 99%

Conducting polymer‐based nanostructured materials for brain–machine interfaces

Ziai

Zargarian

Rinoldi

et al. 2023

WIREs Nanomed Nanobiotechnol

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As scientists discovered that raw neurological signals could translate into bioelectric information, brain–machine interfaces (BMI) for experimental and clinical studies have experienced massive growth. Developing suitable materials for bioelectronic devices to be used for real‐time recording and data digitalizing has three important necessitates which should be covered. Biocompatibility, electrical conductivity, and having mechanical properties similar to soft brain tissue to decrease mechanical mismatch should be adopted for all materials. In this review, inorganic nanoparticles and intrinsically conducting polymers are discussed to impart electrical conductivity to systems, where soft materials such as hydrogels can offer reliable mechanical properties and a biocompatible substrate. Interpenetrating hydrogel networks offer more mechanical stability and provide a path for incorporating polymers with desired properties into one strong network. Promising fabrication methods, like electrospinning and additive manufacturing, allow scientists to customize designs for each application and reach the maximum potential for the system. In the near future, it is desired to fabricate biohybrid conducting polymer‐based interfaces loaded with cells, giving the opportunity for simultaneous stimulation and regeneration. Developing multi‐modal BMIs, Using artificial intelligence and machine learning to design advanced materials are among the future goals for this field.This article is categorized under: Therapeutic Approaches and Drug Discovery > Nanomedicine for Neurological Disease

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Section: Inorganic Nanomaterials and Their Compositesmentioning

confidence: 99%

Conducting polymer‐based nanostructured materials for brain–machine interfaces

Ziai

Zargarian

Rinoldi

et al. 2023

WIREs Nanomed Nanobiotechnol

View full text Add to dashboard Cite

show abstract

“…13,14 To achieve a high performance nerve-electrode interface, attention should be paid to the following aspects: (i) the charge transfer mechanism of diverse electrode materials needs to be clarified, since the electrical deviations of neural interfaces bring about obstacles to signal transmission and detection. 15–17 (ii) An excellent electrochemical performance of the neural electrode is highly desired, 18,19 including electrochemical impedance, 20,21 charge storage capacity (CSC), 22,23 charge injection limit (CIL, it is defined as the maximum charge density that can be injected into the tissue under the safe potential window measured by cyclic voltammetry) 24–26 and so on. Among them, a low impedance favors monitoring the electrophysiological signal with more details.…”

Section: Introductionmentioning

confidence: 99%

Strategies for interface issues and challenges of neural electrodes

Liang

Yan

et al. 2022

Nanoscale

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“…Nanostructured hydrogels are a combination of nanotechnology and biomaterial science that can improve electrical properties. Hydrogel matrices have been loaded with conductive materials such as metallic fillers ( e.g ., nanowires, nanoflakes, or micro- or nanoparticles), and carbon-based conductive materials ( e.g ., nanotubes or graphene) to form a percolation network within a hydrogel matrix. − The advantages of this approach include signal transmission by the transfer of ions and small molecules, similarly to human biological tissues . Thus, tissues have a much higher electrical conductivity than when electrons and holes are used as the charge carriers in metal electronic devices.…”

Section: Introductionmentioning

confidence: 99%

In Vivo Chronic Brain Cortex Signal Recording Based on a Soft Conductive Hydrogel Biointerface

Rinoldi

Ziai

Zargarian

et al. 2022

ACS Appl. Mater. Interfaces

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In neuroscience, the acquisition of neural signals from the brain cortex is crucial to analyze brain processes, detect neurological disorders, and offer therapeutic brain−computer interfaces. The design of neural interfaces conformable to the brain tissue is one of today's major challenges since the insufficient biocompatibility of those systems provokes a fibrotic encapsulation response, leading to an inaccurate signal recording and tissue damage precluding long-term/permanent implants. The design and production of a novel soft neural biointerface made of polyacrylamide hydrogels loaded with plasmonic silver nanocubes are reported herein. Hydrogels are surrounded by a silicon-based template as a supporting element for guaranteeing an intimate neural-hydrogel contact while making possible stable recordings from specific sites in the brain cortex. The nanostructured hydrogels show superior electroconductivity while mimicking the mechanical characteristics of the brain tissue. Furthermore, in vitro biological tests performed by culturing neural progenitor cells demonstrate the biocompatibility of hydrogels along with neuronal differentiation. In vivo chronic neuroinflammation tests on a mouse model show no adverse immune response toward the nanostructured hydrogel-based neural interface. Additionally, electrocorticography acquisitions indicate that the proposed platform permits long-term efficient recordings of neural signals, revealing the suitability of the system as a chronic neural biointerface.

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Iridium Oxide Nanoparticle–Protein Corona Neural Interfaces with Enhanced Electroactivity and Bioactivity Enable Electrically Manipulatable Physical and Chemical Neuronal Activation

Cited by 6 publications

References 43 publications

Conducting polymer‐based nanostructured materials for brain–machine interfaces

Conducting polymer‐based nanostructured materials for brain–machine interfaces

Strategies for interface issues and challenges of neural electrodes

In Vivo Chronic Brain Cortex Signal Recording Based on a Soft Conductive Hydrogel Biointerface

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