Organic Mixed Conductors in Electrochemical Transistors for Bioelectronic Applications

IF 14 Q1 CHEMISTRY, MULTIDISCIPLINARY
Jiajun Song, Li Li*, Wai-Yeung Wong* and Feng Yan*, 
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引用次数: 0

Abstract

Organic semiconductors have emerged as promising materials for facilitating communication between electronic systems and biological entities due to their distinctive advantages, such as structural similarity to biological substances, biocompatibility, tailorability, and mechanical flexibility. Organic bioelectronics mainly focuses on developing devices capable of sensing biological substances and signals, as well as stimulating or regulating biological processes. This interdisciplinary field encompasses various applications, ranging from healthcare monitoring and diagnostics to neuroprosthetics and human–machine interfaces.

Among various organic devices, organic electrochemical transistors (OECTs) have gained significant attention in bioelectronics due to their effective coupling of electronic and ionic transports. OECTs utilize organic mixed ionic–electronic conductors (OMIECs) as ion-permeable channel materials, enabling ion doping throughout the entire channel. This unique volumetric doping gives OECTs ultrahigh transconductance at low working voltages, making them advantageous for highly sensitive biosensing and reliable recording of electrophysiological signals with enhanced signal-to-noise ratios. The properties of OMIECs play a crucial role in determining the device performance and the application scenarios, leading to considerable interest in recent decades.

Understanding the relationship between material figures of merit and specific applications is crucial for guiding material design and selection. This account focuses on the recent advances in OMIECs development for OECTs and highlights their impact on bioelectronic applications. First, we introduce the operation of OECTs, emphasizing the coupling of electronic and ionic circuits and the unique bulk doping mechanism that sets them apart from conventional field-effect transistors. Potential factors influencing transconductance and transient behavior are discussed. Then, we delve into the historical perspective on OMIECs development in OECTs, underscoring material design strategies that enable mixed conduction, including the introduction of glycolated side chains and the utilization of emerging 2D nanoporous structures. Subsequently, we explore the beneficial traits of OMIECs for bioelectronic applications. We discuss the strategies to harness the high transconductance originating from OMIECs for achieving high-performance biosensors and recording electrophysiological signals with superior signal-to-noise ratios. Additionally, we critically examine the latest strategies employed in the realization of stretchable, self-healing, and bioadhesive OMIECs. These innovative features have made significant contributions to wearable and implantable applications. The integration of stretchability ensures compatibility with the dynamic nature of biological entities, enabling robust and reliable performance. The self-healing capabilities of OMIECs exhibit a remarkable ability to autonomously repair damage or degradation, thereby prolonging the lifespan and functionality of bioelectronic devices. Moreover, the bioadhesive properties of OMIECs enable secure attachment to biological surfaces, establishing intimate contact for improved signal acquisition and stability. Finally, we discuss the challenges and opportunities in the further development of OMIECs in OECTs. This article provides an overview of recent advancements in OMIECs and their potential to revolutionize bioelectronic applications. With continuous innovation, OMIECs hold great promise for shaping the future of bioelectronics.

Abstract Image

生物电子应用电化学晶体管中的有机混合导体
有机半导体因其与生物物质结构相似、生物相容性、可定制性和机械灵活性等独特优势,已成为促进电子系统与生物实体之间通信的有前途的材料。有机生物电子学主要侧重于开发能够感知生物物质和信号以及刺激或调节生物过程的设备。在各种有机器件中,有机电化学晶体管(OECTs)因其电子和离子传输的有效耦合而在生物电子学领域备受关注。有机电化学晶体管利用有机混合离子电子导体(OMIEC)作为离子渗透通道材料,使离子掺杂贯穿整个通道。这种独特的体积掺杂使 OECTs 在低工作电压下具有超高的转导能力,从而使其在高灵敏度生物传感和可靠记录电生理信号方面具有优势,并提高了信噪比。OMIEC 的特性在决定器件性能和应用场景方面起着至关重要的作用,近几十年来引起了人们的极大兴趣。本文重点介绍了用于 OECTs 的 OMIECs 开发的最新进展,并强调了它们对生物电子应用的影响。首先,我们介绍了 OECT 的工作原理,强调了电子和离子电路的耦合以及使其有别于传统场效应晶体管的独特体掺杂机制。我们还讨论了影响跨导和瞬态行为的潜在因素。然后,我们从历史角度深入探讨了 OMIEC 在 OECT 中的发展,强调了实现混合传导的材料设计策略,包括引入乙二醇侧链和利用新兴的二维纳米多孔结构。随后,我们探讨了 OMIECs 在生物电子应用中的有益特性。我们讨论了利用 OMIEC 产生的高跨导实现高性能生物传感器和记录具有卓越信噪比的电生理信号的策略。此外,我们还对实现可拉伸、自愈合和生物粘性 OMIEC 所采用的最新策略进行了认真研究。这些创新功能为可穿戴和植入式应用做出了重大贡献。可拉伸性的集成确保了与生物实体动态特性的兼容性,从而实现了稳健可靠的性能。OMIEC 的自愈能力表现出了自主修复损伤或退化的非凡能力,从而延长了生物电子设备的寿命和功能。此外,OMIEC 的生物粘附特性还能安全地附着在生物表面,建立亲密接触,从而提高信号采集和稳定性。最后,我们讨论了进一步开发 OMIEC 在 OECT 中的应用所面临的挑战和机遇。本文概述了 OMIEC 的最新进展及其彻底改变生物电子应用的潜力。随着不断创新,OMIEC 将大有希望塑造生物电子学的未来。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
17.70
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