湿法打印的可拉伸和应变不敏感导电聚合物电极:促进体内胃慢波图谱绘制

Peikai Zhang, Omkar N. Athavale, Bicheng Zhu, Jadranka Travas‐Sejdic, Peng Du
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摘要

可穿戴和植入式设备在临床诊断、疾病治疗以及人体电生理学和生物化学过程的基础研究中发挥着至关重要的作用。导电聚合物是一种新兴的有前途的解决方案,它超越了传统金属电极的局限性,具有更强的保形性和拉伸性。然而,目前 CP 电极的微细加工技术有许多局限性。本研究开发了一种新型湿印刷技术,用于制造高度可拉伸的聚(3,4-亚乙二氧基噻吩):聚苯乙烯磺酸盐(PEDOT:PSS)微电极。在液态凝固浴中进行的湿法印刷具有非接触、操作简单快捷、可印刷低粘度油墨等优点。演示了宽度≈20 µm 的 PEDOT:PSS 线的湿印刷。通过添加 D-山梨醇作为增塑剂,PEDOT:PSS 电极实现了超过 720% 的超高拉伸性,同时电极在高应变下仍保持导电性和应变敏感性。实验证明,PEDOT:PSS 湿印刷电极阵列可用于胃电生理记录。在猪和啮齿动物模型中,可拉伸电极膨胀后与组织贴合,记录到的电生理信号与镀金电极相当。使用低粘度导电油墨制造柔性可拉伸电极阵列的湿印刷方法有望应用于保形电子学。
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Wet‐Printed Stretchable and Strain‐Insensitive Conducting Polymer Electrodes: Facilitating In Vivo Gastric Slow Wave Mapping
Wearable and implantable devices play a crucial role in clinical diagnosis, disease treatment, and fundamental research on the body's electrophysiology and biochemical processes. Conducting polymers are emerging as promising solutions to surpass the limitations of traditional metal‐based electrodes, offering enhanced conformability, and stretchability. However, current microfabrication techniques of CP electrodes have a number of limitations. In this study, a novel wet‐printing technique is developed for the fabrication of highly stretchable poly(3,4‐ethylenedioxythiophene): polystyrene sulfonate (PEDOT:PSS) microelectrodes. The wet‐printing, conducted in a liquid coagulation bath, has the advantages of being non‐contact, easy and fast to perform, and capable of printing low‐viscosity inks. Wet‐printing of PEDOT:PSS lines with a width of ≈20 µm is demonstrated. By adding D‐sorbitol as a plasticizer, an ultra‐high stretchability of PEDOT:PSS electrodes, of more than 720% is achieved while the electrodes remained conductive and strain‐insensitive up to high strains. The use of PEDOT:PSS wet‐printed electrode arrays for the electrophysiological recording from the stomach is demonstrated. The stretchable electrodes conformed swell to the tissue and recorded comparable electrophysiological signals to Au‐plated electrodes in porcine and rodent animal models. The wet‐printing approach to fabricating flexible and stretchable electrode arrays using low‐viscosity, conducting inks holds promise for applications in conformable electronics.
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