A Zwitterionic Conductive Hydrogel Interface for Enhanced Electrocorticography Signal Fidelity via High Conductivity, Antifouling, and Brain-Matched Mechanics.

IF 5.4 2区化学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Biomacromolecules Pub Date : 2025-10-07 DOI:10.1021/acs.biomac.5c01412

Ying Xiang, Xuan He, Tingting Cheng, Weihao Zhu, Ji Pang, Yijia Cao, Meng Wu, Renjun Pei, Yi Cao

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Abstract

Electrocorticography (ECoG) holds considerable promise for neural signal monitoring with high spatiotemporal resolution. However, conventional rigid ECoG electrodes are often hampered by poor mechanical compliance and insufficient resistance to biofouling, leading to high interfacial impedance and compromised signal quality. While integrating conductive hydrogels into ECoG interface offers a potential solution, concurrently achieving high conductivity, mechanical compatibility with brain tissue, biosafety, and robust antifouling remains a significant challenge. This study introduces SPP@NaCl, a novel zwitterionic conductive hydrogel synthesized by doping a poly(sulfobetaine methacrylate) (pSB) hydrogel matrix with poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) and employing NaCl as a Lewis acid to induce phase separation, thereby promoting an interconnected PEDOT network. The resultant SPP@NaCl hydrogel exhibits a compelling combination of properties: high electrical conductivity (∼9 S·m^-¹), a low Young's modulus (1.74 kPa) that closely matches brain tissue, excellent conformability, and markedly reduced protein adsorption attributable to its zwitterionic structure. When integrated with commercial ECoG electrodes, the optimized SPP@NaCl-8 hydrogel dramatically lowers interfacial impedance. The resulting Au-SPP@NaCl electrodes enabled high-fidelity, real-time monitoring of cortical epileptiform discharges in a rat seizure model and demonstrated stable, long-term neural signal acquisition in anesthetized healthy rats. This work presents a new strategy for constructing ECoG interfaces that simultaneously deliver high conductivity, mechanical compliance, biosafety, and antifouling capabilities, highlighting the significant potential of these hydrogel-integrated ECoG electrodes for advanced brain-computer interface applications.

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两性离子导电水凝胶界面通过高电导率、防污和脑匹配力学增强皮质电成像信号保真度。

脑皮质电图（ECoG）在高时空分辨率的神经信号监测方面具有相当大的前景。然而，传统的刚性ECoG电极往往受到机械顺应性差和抗生物污染能力不足的阻碍，导致高界面阻抗和信号质量受损。虽然将导电水凝胶集成到ECoG界面中提供了一种潜在的解决方案，但同时实现高导电性、与脑组织的机械相容性、生物安全性和强大的防污性仍然是一个重大挑战。本文介绍了以聚（3,4-乙烯二氧噻吩）和聚苯乙烯磺酸盐（PEDOT:PSS）为基料，以NaCl为Lewis酸诱导相分离，形成相互连接的PEDOT网络，合成了新型两性离子导电水凝胶SPP@NaCl。所得SPP@NaCl水凝胶具有令人信服的特性组合：高电导率（~ 9 S·m-1），低杨氏模量（1.74 kPa），与脑组织紧密匹配，良好的相容性，以及由于其两性离子结构而显著减少的蛋白质吸附。当与商用ECoG电极集成时，优化的SPP@NaCl-8水凝胶显着降低了界面阻抗。由此产生的Au-SPP@NaCl电极能够在大鼠癫痫模型中实现高保真、实时监测皮质癫痫样放电，并在麻醉的健康大鼠中证明了稳定、长期的神经信号获取。这项工作提出了一种构建ECoG接口的新策略，同时提供高导电性、机械顺应性、生物安全性和防污能力，突出了这些水凝胶集成ECoG电极在高级脑机接口应用中的巨大潜力。

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来源期刊

Biomacromolecules 化学-高分子科学

CiteScore

10.60

自引率

4.80%

发文量

417

审稿时长

1.6 months

期刊介绍： Biomacromolecules is a leading forum for the dissemination of cutting-edge research at the interface of polymer science and biology. Submissions to Biomacromolecules should contain strong elements of innovation in terms of macromolecular design, synthesis and characterization, or in the application of polymer materials to biology and medicine. Topics covered by Biomacromolecules include, but are not exclusively limited to: sustainable polymers, polymers based on natural and renewable resources, degradable polymers, polymer conjugates, polymeric drugs, polymers in biocatalysis, biomacromolecular assembly, biomimetic polymers, polymer-biomineral hybrids, biomimetic-polymer processing, polymer recycling, bioactive polymer surfaces, original polymer design for biomedical applications such as immunotherapy, drug delivery, gene delivery, antimicrobial applications, diagnostic imaging and biosensing, polymers in tissue engineering and regenerative medicine, polymeric scaffolds and hydrogels for cell culture and delivery.