Novel conductive PEDOT:DBSA hydrogels with tuneable properties for bioelectronics

Materials Advances, Journal Year: 2025, Volume and Issue: unknown

Published: Jan. 1, 2025

PEDOT:DBSA hydrogel shows excellent biocompatibility, tunable mechanical properties, and electrical properties for cell-targeted bioelectronics. This could enhance bioelectronic devices' efficiency applicability in cell stimulation.

Language: Английский

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Microfabricated Conductive PEDOT:PSS Hydrogels for Soft Electronics

Korean Journal of Chemical Engineering, Journal Year: 2025, Volume and Issue: unknown

Published: March 10, 2025

Language: Английский

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Hydrogel-Based Biointerfaces: Recent Advances, Challenges, and Future Directions in Human–Machine Integration

Gels, Journal Year: 2025, Volume and Issue: 11(4), P. 232 - 232

Published: March 23, 2025

Human–machine interfacing (HMI) has emerged as a critical technology in healthcare, robotics, and wearable electronics, with hydrogels offering unique advantages multifunctional materials that seamlessly connect biological systems electronic devices. This review provides detailed examination of recent advancements hydrogel design, focusing on their properties potential applications HMI. We explore the key characteristics such biocompatibility, mechanical flexibility, responsiveness, which are essential for effective long-term integration tissues. Additionally, we highlight innovations conductive hydrogels, hybrid composite materials, fabrication techniques 3D/4D printing, allow customization to meet demands specific HMI applications. Further, discuss diverse classes polymers contribute conductivity, including conducting, natural, synthetic, polymers, emphasizing role enhancing electrical performance adaptability. In addition material examine regulatory landscape governing hydrogel-based biointerfaces applications, addressing considerations clinical translation commercialization. An analysis patent insights into emerging trends shaping future technologies human–machine interactions. The also covers range neural interfaces, soft haptic systems, where play transformative Thereafter, addresses challenges face issues related stability, scalability, while perspectives continued evolution technologies.

Language: Английский

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Design Strategies of PEDOT:PSS-Based Conductive Hydrogels and Their Applications in Health Monitoring

Polymers, Journal Year: 2025, Volume and Issue: 17(9), P. 1192 - 1192

Published: April 27, 2025

Conductive hydrogels, particularly those incorporating poly(3,4-ethylenedioxythiophene):polystyrene sulfonate (PEDOT:PSS), have revolutionized wearable health monitoring by merging tissue-like softness with robust electronic functionality. This review systematically explores design strategies for PEDOT:PSS-based focusing on advanced gelation methods, including polymer crosslinking, ionic interactions, and light-induced polymerization, to engineer hierarchical networks that balance conductivity mechanical adaptability. Cutting-edge fabrication techniques such as electrochemical patterning, additive manufacturing, laser-assisted processing further enable precise microstructural control, enhancing interfacial compatibility biological systems. The applications of these hydrogels in sensors are highlighted through their capabilities real-time deformation tracking, dynamic tissue microenvironment analysis, high-resolution electrophysiological signal acquisition. Environmental stability long-term durability critical ensuring reliable operation under physiological conditions mitigating performance degradation caused fatigue, oxidation, or biofouling. By addressing challenges environmental durability, PEDOT:PSS demonstrate transformative potential personalized healthcare, where unique combination softness, biocompatibility, tunable electro-mechanical properties enables seamless integration human tissues continuous, patient-specific monitoring. These systems offer scalable solutions multi-modal diagnostics, empowering tailored therapeutic interventions chronic disease management. concludes insights into future directions, emphasizing the intelligent responsiveness energy autonomy advance next-generation bioelectronic interfaces.

Language: Английский

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The novel nanozyme-based electrochemical-driven electrochromic visual biosensor based on PEDOT:PSS/RGO conductive film for rapid detection of nitrite in food samples

Food Chemistry, Journal Year: 2025, Volume and Issue: unknown, P. 143971 - 143971

Published: March 1, 2025

Language: Английский

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A photonic crystal-hydrogel sensor for the monitoring of potassium ions in sweat

Analytical Methods, Journal Year: 2025, Volume and Issue: unknown

Published: Jan. 1, 2025

Monitoring sweat electrolyte levels using a photonic crystal biosensor membrane stimulated with onion extract.

Language: Английский

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Block copolymer micelles stabilized Pickering emulsions in templating ultralight conducting PEDOT:PSS elastomeric aerogels

Colloids and Surfaces A Physicochemical and Engineering Aspects, Journal Year: 2024, Volume and Issue: 705, P. 135548 - 135548

Published: Oct. 11, 2024

Language: Английский

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Mechanoadaptive Bioelectronics for Deep Tissue Sensing

Chinese Journal of Chemistry, Journal Year: 2024, Volume and Issue: unknown

Published: Dec. 20, 2024

Comprehensive Summary Deep‐tissue physiological signals are critical for accurate disease diagnosis. Current clinical equipment, however, often falls short of enabling continuous, long‐term monitoring. Wearable and implantable flexible electronics offer a promising avenue addressing this limitation, allowing in vivo signal collection paving the way early diagnosis personalized treatment. A major challenge lies ensuring that these devices seamlessly integrate with diverse microenvironments throughout human body. Mechanoadaptive bioelectronics is emerging as key solution to optimize acquisition device robustness. This review provides comprehensive overview characteristics various organs types they generate. Furthermore, it explores recent advancements mechanoadaptive bioelectronics, systematically categorizes their strategies, underscores potential revolutionize healthcare. Finally, we delve into ongoing challenges field highlight directions advance adaptability further. Key Scientists In 2017, researchers developed an ionic skin enhanced mechanical compatibility through strain‐hardening properties. [1] Three years later, neural interface platform called adaptive self‐healing electronic epineurium (A‐SEE) was reported. [2] minimized stress on tissue by dynamically relaxing stress. 2021, hydrogel hybrid probe tracking isolated neuroelectric activity, optogenetics, behavioral studies circuits. also utilized hydration‐induced softening minimize foreign body response. [3] same year, shape‐adaptive imager Kirigami design proposed. [4] following morphing (MorphE) reported, which exhibited attractive viscoelasticity minimal growing nerve during implantation. [5] 2023, standardized tissue‐electronic developed, can be implanted minimally invasive cardiac procedures rapidly beating heart. [6] Recently, needle‐like microfiber based biphasic liquid metal created. reach target site simply puncturing enable multifunctional sensing. [7] At about time, amalgamated living synthetic components studying treating inflammatory disease. [8] enables real‐time digital updates potentially treatment non‐resolving inflammation, enlightening new generation bioelectronics.

Language: Английский

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Development of novel poly(o-anisidine) nanocomposite flexible membrane electrodes and characterization of their supercapacitor applications

Ionics, Journal Year: 2024, Volume and Issue: unknown

Published: Dec. 11, 2024

Language: Английский

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