Electronically Conductive Hydrogels by in Situ Polymerization of a Water‐Soluble EDOT‐Derived Monomer

Nguyen, Dan My; Wu, Yuhang; Nolin, Abigail; Lo, Chen‐Tsyr; Guo, Tianzheng; Dhong, Charles; Martin, David C.; Kayser, Laure V.

doi:10.1002/adem.202200280

Cited by 11 publications

(10 citation statements)

References 46 publications

(78 reference statements)

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“…Notably, at an identical gel volume, the hydrogel with a 100:13 ratio of SS to EDOT displayed the lowest impedance magnitude. The Nyquist plot of the hydrogels (Figure b) were analyzed and fitted to the equivalent circuit model commonly used for PEDOT-based conductive hydrogels (Figure c). ,, The tabulated values extracted from this model are presented in Table and show small χ 2 values, indicating a good fit for the model. The values of R c , R e , and R i are, respectively, the resistive contributions from the assembled cell used for the test and the electronic and ionic resistance from the conductive hydrogel.…”

Section: Resultsmentioning

confidence: 99%

“…However, bioelectronic devices made from conductive hydrogels are currently limited by their fabrication methods and our ability to control the shape and position of the hydrogel. Conventional methods such as molding ,, have been frequently used to fabricate conductive hydrogels but can only provide simple structures with low resolution (>100 μm) . This large size may not be compatible with bioelectronic applications requiring small electrodes.…”

Section: Introductionmentioning

confidence: 99%

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One Pot Photomediated Formation of Electrically Conductive Hydrogels

Nguyen,

Lo,

Guo

et al. 2023

ACS Polym. Au

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Electrically conductive hydrogels represent an innovative platform for the development of bioelectronic devices. While photolithography technologies have enabled the fabrication of complex architectures with high resolution, photoprinting conductive hydrogels is still a challenging task because the conductive polymer absorbs light which can outcompete photopolymerization of the insulating scaffold. In this study, we introduce an approach to synthesizing conductive hydrogels in one step. Our approach combines the simultaneous photo-crosslinking of a polymeric scaffold and the polymerization of 3,4ethylene dioxythiophene (EDOT), without additional photocatalysts. This process involves the copolymerization of photocross-linkable coumarin-containing monomers with sodium styrenesulfonate to produce a water-soluble poly(styrenesulfonate-co-coumarin acrylate) (P(SS-co-CoumAc)) copolymer. Our findings reveal that optimizing the [SS]:[CoumAc] ratio at 100:5 results in hydrogels with the strain at break up to 16%. This mechanical resilience is coupled with an electronic conductivity of 9.2 S m −1 suitable for wearable electronics. Furthermore, the conductive hydrogels can be photopatterned to achieve micrometer-sized structures with high resolution. The photo-cross-linked hydrogels are used as electrodes to record stable and reliable surface electromyography (sEMG) signals. These novel photo-cross-linkable polymers combined with one-pot PEDOT (poly-EDOT) polymerization open possibilities for rapidly prototyping complex bioelectronic devices and creating custom-designed interfaces between electronics and biological systems.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

One Pot Photomediated Formation of Electrically Conductive Hydrogels

Nguyen,

Lo,

Guo

et al. 2023

ACS Polym. Au

Self Cite

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“…In another work, a parallel approach was demonstrated by mold casting hydrogels composed of water‐soluble EDOT‐diethylene glycol that are electronically conductive upon in situ polymerization and can maintain the mechanical properties of the gel. [ 107 ] In the future, a better understanding of polymer chain entanglements and formation of nanofibril networks in PEDOT‐based or PEDOT:PSS solutions will advance the development of these 3D printable polymer systems. Moreover, the flexibility and reproducibility of 3D printing of conductive PEDOT: PSS allows the fabrication of bioelectronic signal recording probe with PDMS (Figure 8d,e ).…”

Section: Strategies For Implementing Molecular 2d and 3d Organization...mentioning

confidence: 99%

Engineering Multi‐Scale Organization for Biotic and Organic Abiotic Electroactive Systems

et al. 2023

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Multi-scale organization of molecular and living components is one of the most critical parameters that regulate charge transport in electroactive systems-whether abiotic, biotic, or hybrid interfaces. In this article, an overview of the current state-of-the-art for controlling molecular order, nanoscale assembly, microstructure domains, and macroscale architectures of electroactive organic interfaces used for biomedical applications is provided. Discussed herein are the leading strategies and challenges to date for engineering the multi-scale organization of electroactive organic materials, including biomolecule-based materials, synthetic conjugated molecules, polymers, and their biohybrid analogs. Importantly, this review provides a unique discussion on how the dependence of conduction phenomena on structural organization is observed for electroactive organic materials, as well as for their living counterparts in electrogenic tissues and biotic-abiotic interfaces. Expansion of fabrication capabilities that enable higher resolution and throughput for the engineering of ordered, patterned, and architecture electroactive systems will significantly impact the future of bioelectronic technologies for medical devices, bioinspired harvesting platforms, and in vitro models of electroactive tissues. In summary, this article presents how ordering at multiple scales is important for modulating transport in both the electroactive organic, abiotic, and living components of bioelectronic systems.

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“…32 Another method begins with a polymer precursor, 3,4ethylenedioxythiophene diethylene glycol, to create a hydrogel. 33 In a recent study, PBLG, a biocompatible polypeptide, was used to enhance the assembly of poly(3-hexylthiophene) (P3HT) into a network structure. 34 Here, the interactions between PBLG and P3HT led to an ordered structure of P3HT growing between bundled PBLG helices.…”

Section: ■ Introductionmentioning

confidence: 99%

“…The process involves mixing DMSO into aqueous PEDOT: PSS solutions to develop interconnected networks of PEDOT: PSS nanofibrils . Another method begins with a polymer precursor, 3,4-ethylenedioxythiophene diethylene glycol, to create a hydrogel . In a recent study, PBLG, a biocompatible polypeptide, was used to enhance the assembly of poly(3-hexylthiophene) (P3HT) into a network structure .…”

Section: Introductionmentioning

confidence: 99%

Gels of Semiconducting Polymers in Benign Solvents

Lakdusinghe,

Mooney,

Ahmad

et al. 2023

Langmuir

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Gels of semiconducting polymers have many potential applications, including biomedical devices and sensors.Here, we report a self-assembled gel system consisting of isoindigobased semiconducting polymers with galactose side chains in benign, alcohol-based solvents. Because of the carbohydrate side chains, the modified isoindigo polymers are soluble in alcohols. We obtained thermoreversible gels in 1-propanol using these polymers and di-Fmoc-L-lysine, a molecular gelator. The polymers and molecular gelators have been selected in such a way that they do not have significant physical interactions. The molecular gelator self-assembled to form a fibrous structure that confines the polymer chains in the interstitial spaces of the fibers. The polymer chains formed local aggregations and increased the shear moduli of the gels significantly. Bulky galactose side chains and the less planar nature of the polymer backbone hindered the formation of longrange assembled structures of the polymers. However, the dispersion of polymers throughout the gel samples resulted in a percolated structure in the dried gel films. The bulk electrical conductivity of dried gels confirmed the presence of such percolated structures. Our results demonstrated that carbohydrate-containing conjugated polymers can be combined with molecular gelators to obtain gels in eco-friendly solvents.

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Electronically Conductive Hydrogels by in Situ Polymerization of a Water‐Soluble EDOT‐Derived Monomer

Cited by 11 publications

References 46 publications

One Pot Photomediated Formation of Electrically Conductive Hydrogels

One Pot Photomediated Formation of Electrically Conductive Hydrogels

Engineering Multi‐Scale Organization for Biotic and Organic Abiotic Electroactive Systems

Gels of Semiconducting Polymers in Benign Solvents

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