Roll-to-roll electrochemical fabrication of non-polarizable silver/silver chloride-coated nylon yarn for biological signal monitoring

Haddad, Peter A.; Servati, Amir; Soltanian, Saeid; Servati, Peyman; Ko, Frank

doi:10.1177/0040517518817060

Cited by 3 publications

(6 citation statements)

References 31 publications

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“…The method used to fabricate Ag/AgCl yarns is a modified setup from previous work 12 . The setup allows for a higher throughput of Ag/AgCl yarn, as well as modifiable process parameters, which allow for accurate control of coating thicknesses and yarn conductance to meet material performance requirements.…”

Section: Methodsmentioning

confidence: 99%

“…Efforts have been devoted to developing dry electrodes for biosignal monitoring, such as printed Ag/AgCl-based inks on flexible substrates or textiles 4 , 10 . Work by Xu et al 11 and Haddad et al 12 have demonstrated the fabrication of Ag/AgCl based e-textiles comparable with Ag/AgCl solid gel electrodes for biosignal monitoring.…”

Section: Introductionmentioning

confidence: 99%

“…This work reports a continuous roll-to-roll electrochemical system for the lab scale fabrication of Ag/AgCl-coated multi-filament nylon yarn that has been developed by the authors 12 , electrochemical characterization of the coating process of AgCl on Ag-nylon yarns, design, and performance of embroidered electrodes for ECG measurement, which provide insights into the stability and performance as an electrode material.…”

Section: Introductionmentioning

confidence: 99%

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Roll-to-roll fabrication of silver/silver chloride coated yarns for dry electrodes and applications in biosignal monitoring

Le,

Soltanian,

Narayana

et al. 2023

Sci Rep

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This work presents a continuous roll-to-roll electrochemical coating system for producing silver/silver chloride (Ag/AgCl)-coated yarns, and their application in e-textile electrodes for biosignal monitoring. Ag/AgCl is one of the most preferred electrode materials as an interface between the conductive backbone of an electrode and skin. E-textile Ag/AgCl-coated multi-filament nylon yarns offer stable, flexible, and breathable alternatives to standard rigid or flexible film-based Ag/AgCl electrodes. The developed system allows for highly controlled process parameters to achieve stable and uniform AgCl film deposition on Ag-coated nylon yarns. The electrical, electrochemical properties, and morphology of the coated yarns were characterized. Dry electrodes were fabricated and could measure electrocardiogram (ECG) signals with comparable performance to standard gel electrodes. Ag/AgCl e-textile electrodes demonstrated high stability, with low average polarization potential (1.22 mV/min) compared with Ag-coated electrodes (3.79 mV/min), low impedance (below 2 MΩ, 0.1–150 Hz), and are excellent candidates for heart rate detection and monitoring.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Roll-to-roll fabrication of silver/silver chloride coated yarns for dry electrodes and applications in biosignal monitoring

Le,

Soltanian,

Narayana

et al. 2023

Sci Rep

Self Cite

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“…Plating, dip-coating, physical vapor deposition, polymerization of conducting polymers, knitting, weaving and embroidery, inkjet, screen, and stencil printing are used [168]- [171]. Roll-to-roll electrochemical fabrication of Ag/AgCl coated nylon yearns has been demonstrated [172], and screen and stencil printing and blade coating have been combined for wearable EIT electrode arrays on polyester fabrics [173]. Along with silver, PEDOT:PSS (with additional crosslinkers for improved properties) is playing a prominent role with textile electrodes as well [171], [174].…”

Section: Recent Advancements In Bioimpedance Sensor Realizationmentioning

confidence: 99%

Bioimpedance Sensors: A Tutorial

Kassanos

2021

IEEE Sensors J.

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Electrical bioimpedance entails the measurement of the electrical properties of tissues as a function of frequency. It is thus a spectroscopic technique. It has been applied in a plethora of biomedical applications for diagnostic and monitoring purposes. In this tutorial, the basics of electrical bioimpedance sensor design will be discussed. The electrode/electrolyte interface is thoroughly described, as well as methods for its modelling with equivalent circuits and computational tools. The design optimization and modelling of bipolar and tetrapolar bioimpedance sensors is presented in detail, based on the sensitivity theorem. Analytical and numerical modelling approaches for electric field simulations based on conformal mapping, point electrode approximations and the finite element method (FEM) are also elaborated. Finally, current trends on bioimpedance sensors are discussed followed by an overview of instrumentation methods for bioimpedance measurements, covering aspects of voltage signal excitations, current sources, voltage measurement front-end topologies and methods for computing the electrical impedance.

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“…In particular, metal coated nylon fibers have been broadly applied in wearable sensors, such as strain sensors, 40 conductive resistive sensors, 41 pressure sensors, 42 and biological sensors. 43 In addition, noble metal coated nylon fibers with a rough surface provide the possibility to be used as wearable high-sensitive SERS substrates due to the facilitation of building dense plasmonic hotspots. In this work, coarse silver (Ag) layer coated nylon fibers (NFs) with twisted spiral structure are used to load gold (Au) nanoparticles (NPs) to fabricate ultrasensitive SERS substrate (denoted as Au NP@Ag/NF) in a relatively simple and low-cost technique.…”

mentioning

confidence: 99%

Construction of dense plasmonic hotspots on coarse Ag layer coated nylon fibers for ultrasensitive SERS sensing

Liu

et al. 2022

Textile Research Journal

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Surface-enhanced Raman scattering is a powerful sensing tool effectively and rapidly to detect chemicals in environmental monitoring and food safety. Textile fiber-based surface-enhanced Raman scattering substrates have been fabricated to contribute to the practical applications of surface-enhanced Raman scattering sensing. Inspired by the metallic nanostructures with dense plasmonic hotspots which have excellent surface-enhanced Raman scattering activity, coarse silver layer coated nylon fibers are used in this study to combine with gold nanoparticles by a simple immersion method forming enriched plasmonic hotspots on textile fibers for ultrasensitive surface-enhanced Raman scattering detection. The fiber-based surface-enhanced Raman scattering substrate denoted as gold nanoparticle@silver layer coated nylon fiber shows a high sensitivity to rhodamine 6G with an excellent enhancement factor of 2.41 × 1010 and a detection limit of 10−14 M. The finite-difference time-domain simulations indicate that ultra-high sensitivity arises from the enhanced electric fields densely formed in the inter-particle and particle-film gap in the twisted gold nanoparticle@silver layer coated nylon fiber structure. In addition, the gold nanoparticle@silver layer coated nylon fiber substrate demonstrates outstanding surface-enhanced Raman scattering signal reproducibility (relative standard deviation 6.14%) as well as application flexibility. Through a simple swab procedure, gold nanoparticle@silver layer coated nylon fibers absorb rhodamine 6G molecules on apple and the detection limit can reach 10−13 M. Our results allowed us to foresee the use of synthetic fibers enriched with plasmonic hotspots in ultrasensitive wearable sensors.

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Roll-to-roll electrochemical fabrication of non-polarizable silver/silver chloride-coated nylon yarn for biological signal monitoring

Cited by 3 publications

References 31 publications

Roll-to-roll fabrication of silver/silver chloride coated yarns for dry electrodes and applications in biosignal monitoring

Roll-to-roll fabrication of silver/silver chloride coated yarns for dry electrodes and applications in biosignal monitoring

Bioimpedance Sensors: A Tutorial

Construction of dense plasmonic hotspots on coarse Ag layer coated nylon fibers for ultrasensitive SERS sensing

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