Dopamine-integrated all-hydrogel multi-electrode arrays for neural activity recording.

IF 12.2 2区 材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Mingze Zeng, Jie Ding, Yuan Tian, Yusheng Zhang, Xiaoyin Liu, Zhihong Chen, Jing Sun, Chengheng Wu, Huabing Yin, Dan Wei, Hongsong Fan
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Abstract

Investigation of brain neural circuits is essential for deciphering the diagnostics and therapeutics of neurodegenerative diseases. The main concerns with traditional rigid metal electrodes include intrinsic mechanical mismatch between sensing electrodes and tissues, unavoidable foreign body responses, and inadequate spatiotemporal resolution, resulting in a deficiency of sensing performance. All-hydrogel neural electrodes with multi-electrode arrays (MEAs) suggest a viable way to modulate the trade-off between tissue-mechanical compliance and excellent spatiotemporal recording capacity, but still face the issues of insufficient conductivity and unstable interlayer bonding. Herein, we constructed a four-layer all-hydrogel neural electrode, by sandwiching a conductive hydrogel layer within two encapsulation hydrogel layers, with a shielding hydrogel layer located on top. We introduce a dual-strategy treatment to induce controllable phase separation in poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) hydrogel, which achieved ultra-high conductivity (up to 4176 S cm-1) comparable to that of metals and precise spatial resolution (∼15 μm) suitable for single neuron recording. In addition, the utilization of polyphenol chemistry mediated adaptive adhesion endowed this neural electrode with flexible and stable interlayer bonding among conductive-encapsulation-shielding layers and the tissue-electrode interface. Consequently, the all-hydrogel neural electrode exhibited a tenfold higher signal-to-noise ratio than a commercial silver electrode, realized the recording of weak neural activity signals within single and multiple neurons in epileptic rats, and applied man-made stimulation to the cerebral cortex of rats during seizures. This work provides a useful tool to understand the development, function and treatment of neurodegenerative diseases.

用于神经活动记录的多巴胺集成全水凝胶多电极阵列。
脑神经回路的研究对于破译神经退行性疾病的诊断和治疗方法至关重要。传统刚性金属电极的主要问题包括传感电极与组织之间固有的机械不匹配、不可避免的异物反应以及时空分辨率不足,从而导致传感性能不足。带有多电极阵列(MEAs)的全水凝胶神经电极为调节组织机械顺应性和出色的时空记录能力之间的权衡提供了一种可行的方法,但仍面临导电性不足和层间结合不稳定的问题。在此,我们构建了一种四层全水凝胶神经电极,将导电水凝胶层夹在两层封装水凝胶层中,并在其上设置屏蔽水凝胶层。我们采用双重策略处理聚(3,4-亚乙二氧基噻吩):聚(苯乙烯磺酸)(PEDOT:PSS)水凝胶,诱导可控相分离,实现了与金属相当的超高导电率(高达 4176 S cm-1)和适合单神经元记录的精确空间分辨率(∼15 μm)。此外,利用多酚化学介导的适应性粘附赋予了这种神经电极在导电-封装-屏蔽层和组织-电极界面之间灵活而稳定的层间结合。因此,全水凝胶神经电极的信噪比是商用银电极的十倍,实现了对癫痫大鼠单个和多个神经元内微弱神经活动信号的记录,并在癫痫发作时对大鼠大脑皮层进行人工刺激。这项工作为了解神经退行性疾病的发展、功能和治疗提供了有用的工具。
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来源期刊
Materials Horizons
Materials Horizons CHEMISTRY, MULTIDISCIPLINARY-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
18.90
自引率
2.30%
发文量
306
审稿时长
1.3 months
期刊介绍: Materials Horizons is a leading journal in materials science that focuses on publishing exceptionally high-quality and innovative research. The journal prioritizes original research that introduces new concepts or ways of thinking, rather than solely reporting technological advancements. However, groundbreaking articles featuring record-breaking material performance may also be published. To be considered for publication, the work must be of significant interest to our community-spanning readership. Starting from 2021, all articles published in Materials Horizons will be indexed in MEDLINE©. The journal publishes various types of articles, including Communications, Reviews, Opinion pieces, Focus articles, and Comments. It serves as a core journal for researchers from academia, government, and industry across all areas of materials research. Materials Horizons is a Transformative Journal and compliant with Plan S. It has an impact factor of 13.3 and is indexed in MEDLINE.
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