Journal of Textile Research ›› 2026, Vol. 47 ›› Issue (02): 135-143.doi: 10.13475/j.fzxb.20250304401

• Textile Engineering • Previous Articles     Next Articles

Comparison of electrocardiogram sensing performance of embroidery electrodes based on different conductive yarn materials

SHEN Yuxi1, TANG Hong1(), ZHAO Min1,2   

  1. 1 School of Textile and Clothing, Nantong University, Nantong, Jiangsu 226019, China
    2 Xinglin College, Nantong University, Nantong, Jiangsu 226236, China
  • Received:2025-03-20 Revised:2025-11-20 Online:2026-02-15 Published:2026-04-24
  • Contact: TANG Hong E-mail:tang.h@ntu.edu.cn

RichHTML

1

PDF (PC)

6

Abstract:

Objective This study aimed to develop high-performance textile-based embroidery electrocardiogram (ECG) electrodes by investigating the influence of conductive yarn materials on their sensing properties. Conventional Ag/AgCl gel electrodes often cause skin irritation and performance degradation over prolonged use, necessitating the development of durable and comfortable alternatives. Four types of conductive yarns—nylon/silver, polyester/copper fiber, polyester/stainless steel fiber, and polyester/carbon fiber—were selected to fabricate embroidery electrodes. The research evaluated their structural characteristics, electrical properties, and ECG signal acquisition performance to identify the most suitable material for long-term monitoring.

Method Embroidery electrodes were fabricated using an elastic knitted fabric as the substrate and a bionic pattern inspired by tree frog toe pads to enhance the stability of skin-electrode contact. Four conductive yarns with identical linear density and metal content (15%-18%) were employed. Electrode thickness, flatness, surface resistance, skin-electrode interface impedance, and ECG signals were systematically measured. A standard limb lead system was used for ECG acquisition, and signal quality was evaluated using signal-to-noise ratio (SNR) and Pearson correlation coefficient, with medical gel electrodes as the reference. Martindale abrasion tests were conducted to assess durability under repeated friction.

Results The experimental results provided a comprehensive evaluation of how conductive yarn materials influence the structural, electrical, and functional properties of embroidery ECG electrodes. Among the four types tested, the nylon/silver electrode demonstrated the most favorable characteristics. It exhibited the lowest surface resistance across all measurement directions, with values significantly lower than those of the other electrodes. This can be attributed to its uniform silver coating and continuous conductive pathways formed during embroidery. The skin-electrode interface impedance for the nylon/silver electrode was also the lowest and remained the most stable over a 60-minute wearing period, indicating effective and consistent electrical coupling with the skin. In terms of dynamic signal acquisition, it achieved the highest signal-to-noise ratio (SNR) of 36.65 dB and the strongest Pearson correlation coefficient (0.97) with the standard Ag/AgCl gel electrode, confirming its superior accuracy in capturing ECG waveforms, including distinct P-waves, QRS complexes, and T-waves. The polyester/stainless steel fiber electrode ranked second in overall performance, which showed relatively low surface resistance and moderate skin-electrode impedance. Its rigidity, however, limited its ability to conform closely to skin during movement, leading to slight signal fluctuations. The polyester/copper fiber electrode suffered from discontinuous conductive networks due to fiber wear and breakage, resulting in higher resistance and unstable impedance. Meanwhile, the polyester/carbon fiber electrode, despite having the thinnest structure, displayed the highest electrical resistance and significant impedance variability, which led to poor signal stability and visible waveform distortion during ECG monitoring. Abrasion testing further differentiated the long-term usability of these electrodes. The nylon/silver electrode exhibited exceptional durability, maintaining a high SNR of 28.32 dB and a correlation coefficient above 0.8 even after 10 000 friction cycles. The polyester/stainless steel fiber electrode withstood up to 7 500 cycles before a noticeable decline in signal quality, benefiting from the inherent hardness of stainless steel fibers. In contrast, the polyester/copper fiber electrode experienced a rapid 181% increase in resistance after 10 000 cycles, while the polyester/carbon fiber electrode surged by 204% under the same conditions, indicating poor abrasion resistance. These mechanical limitations directly compromised their signal acquisition capabilities after repeated use. Overall, the combination of low initial electrical resistance, stable skin-electrode contact, high signal fidelity, and superior abrasion resistance makes the nylon/silver-based embroidery electrode a highly promising candidate for long-term, reliable ECG monitoring in practical wearable applications.

Conclusion This study confirms that the choice of conductive yarn material plays a critical role in determining the performance and durability of embroidery ECG electrodes. Nylon/silver yarn, with its uniform conductive layer and mechanical flexibility, provides optimal electrical properties, signal stability, and abrasion resistance, making it the most suitable material for long-term wearable health monitoring applications. Polyester/stainless steel fiber yarn offers a compromise between conductivity and durability but is limited by its rigidity. Polyester/copper fiber and polyester/carbon fiber yarns are less favorable due to their susceptibility to wear, high resistance variability, and poor dynamic response. These results provide a clear material selection guideline for developing high-performance textile-based electrodes, emphasizing the importance of both initial performance and mechanical resilience in practical use. Future work may focus on optimizing embroidery parameters and hybrid material designs to further enhance comfort and functionality.

Key words: smart wearable textile, embroidery electrode, conductive yarn, metal fiber, sensing performance, electrocardiogram signal, copper fiber, stainless steel fiber

CLC Number: 

  • TS941.6

Tab.1

Specifications and sources of conductive yarns"

编号 纱线成分 线密度/tex 纱线直径/mm 断裂强力/N 电阻率/(Ω·cm) 来源
1# 锦纶/银(82/18) 27.8 0.203 7.84 4.21×10-4 东莞市粤顺新材料有限公司
2# 涤纶/铜纤维(85/15) 27.8 0.209 4.59 1.18×10-3 惠州市兴利制线有限公司
3# 涤纶/不锈钢纤维(85/15) 27.8 0.238 4.90 4.73×10-3 惠州市兴利制线有限公司
4# 涤纶/碳纤维(85/15) 27.8 0.187 3.95 2.27×10-2 惠州市兴利制线有限公司

Fig.1

Surface microstructure of conductive yarns (×80). (a) Nylon/silver; (b) Polyester/copper fiber; (c) Polyester/stainless steel fiber; (d) Polyester/carbon fiber"

Fig.2

Schematic diagram of yarn arrangement for embroidery electrodes. (a)Satin stitch type; (b)Bionic stitch type"

Fig.3

Schematic diagram of embroidery electrode"

Fig.4

Test positions for surface resistance of embroidery electrodes"

Fig.5

Skin-electrode interface impedance test model"

Fig.6

Principle of ECG signal test"

Fig.7

Appearance of 4 types of embroidery electrodes. (a) Nylon/silver; (b) Polyester/copper fiber; (c) Polyester/stainless steel fiber; (d) Polyester/carbon fiber"

Tab.2

Thickness and flatness of embroidery electrodes"

纱线编号 厚度/mm 平整度/mm
1# 2.138 0.09
2# 2.762 0.12
3# 3.553 0.15
4# 1.841 0.06

Fig.8

Surface resistance of embroidery electrodes"

Fig.9

Skin-electrode interface impedance of embroidery electrodes"

Fig.10

Comparison of ECG measured by embroidery electrode and gel electrode"

Tab.3

ECG analysis measured by embroidery electrode and gel electrode"

电极编号 信噪比/dB 相关系数 显著性
1# 36.65 0.97 <0.01
2# 31.12 0.87 <0.01
3# 33.40 0.91 <0.01
4# 30.21 0.82 <0.01
凝胶电极 28.95 1

Fig.11

Dynamic changes of surface resistance and skin-electrode interface impedance with friction times"

Fig.12

Dynamic changes of signal-to-noise ratio and correlation coefficient with friction times"

[1] LIU X W, WANG H, LI Z J, et al. Deep learning in ECG diagnosis: a review[J]. Knowledge-Based Systems, 2021, 227: 107187.
doi: 10.1016/j.knosys.2021.107187
[2] 陆彤, 唐虹, 赵敏. 刺绣心电电极设计与性能分析[J]. 纺织学报, 2024, 45(9): 70-77.
LU Tong, TANG Hong, ZHAO Min. Design and performance analysis of embroidered electrocardiogram electrode[J]. Journal of Textile Research, 2024, 45(9): 70-77.
[3] MASIHI S, PANAHI M, MADDIPATLA D, et al. Development of a flexible wireless ECG monitoring device with dry fabric electrodes for wearable applications[J]. IEEE Sensors Journal, 2022, 22(12): 11223-11232.
doi: 10.1109/JSEN.2021.3116215
[4] 熊帆, 樊蒙召, 杨朝然, 等. 基于刺绣技术的多模生理传感织物面罩的制备与性能[J]. 现代纺织技术, 2025, 33(3): 126-135.
XIONG Fan, FAN Mengzhao, YANG Chaoran, et al. Preparation and properties of multi-modal physiological sensing fabric masks based on embroidery technology[J]. Advanced Textile Technology, 2025, 33(3): 126-135.
[5] ZHOU J L, ZHANG Y Z, YANG H Y, et al. Fabric electrode monitoring of dynamic and static ECG signal and comfort performance[J]. Coatings, 2023, 13(2): 256446626.
[6] SHEKHAR R, CHOUDHRY N A, ISLAM S, et al. A novel elastic conductive yarn for smart textile applications[J]. Advanced Engineering Materials, 2023, 25(22): 2300572.
doi: 10.1002/adem.v25.22
[7] SINHA A, STAVRAKIS A K, SIMIC M, et al. Polymer-thread-based fully textile capacitive sensor embroidered on a protective face mask for humidity detection[J]. ACS Omega, 2022, 7(49): 44928-44938.
doi: 10.1021/acsomega.2c05162 pmid: 36530326
[8] RIBAS J O, FERNÁNDEZ-GARCÍA R, GIL I. Design and measurement of cost-balanced and electronic-efficient embroidered textile electrodes[J]. The Journal of the Textile Institute, 2024, 115(1): 41-47.
doi: 10.1080/00405000.2022.2157163
[9] 吴玲娅, 李正清, 韩潇, 等. 石墨烯在提高聚苯胺/芳纶复合纱线导电能力中的应用[J]. 印染, 2022, 48(2): 45-48, 72.
WU Lingya, LI Zhengqing, HAN Xiao, et al. Improving conductivity of polyaniline/p-aramide composite yarn with graphene[J]. China Dyeing and Finishing, 2022, 48(2): 45-48, 72.
[10] UZUN S, SCHELLING M, HANTANASIRISAKUL K, et al. Additive-free aqueous MXene inks for thermal inkjet printing on textiles[J]. Small, 2021, 17(1): 2006376.
doi: 10.1002/smll.v17.1
[11] 王建萍, 邵熠萌, 杨雅岚, 等. 针迹类型对表面肌电用刺绣型织物电极性能影响[J]. 纺织学报, 2024, 45(7): 55-62.
WANG Jianping, SHAO Yimeng, YANG Yalan, et al. Influences of stitch types on performance of embroidered fabric electrodes for surface electromyography[J]. Journal of Textile Research, 2024, 45(7): 55-62.
[12] BEN OTHMAN G, KUMAR A A, BEN HASSINE F, et al. Sustainability and predictive accuracy evaluation of gel and embroidered electrodes for ECG monitoring[J]. Biomedical Signal Processing and Control, 2024, 96: 106632.
doi: 10.1016/j.bspc.2024.106632
[13] KIM H, KIM S, LIM D, et al. Development and characterization of embroidery-based textile electrodes for surface EMG detection[J]. Sensors, 2022, 22(13): 4746.
doi: 10.3390/s22134746
[14] 刘旭华, 苗锦雷, 曲丽君, 等. 用于可穿戴智能纺织品的复合导电纤维研究进展[J]. 复合材料学报, 2021, 38(1): 67-83.
LIU Xuhua, MIAO Jinlei, QU Lijun, et al. Research progress of composite conductive fiber in wearable intelligent textiles[J]. Acta Materiae Compositae Sinica, 2021, 38(1): 67-83.
[15] 李龙, 张弦, 吴磊. 导电纱线制备方法与应用的研究进展[J]. 纺织学报, 2023, 44(7): 214-221.
LI Long, ZHANG Xian, WU Lei. Research progress in preparation and application of conductive yarn materials[J]. Journal of Textile Research, 2023, 44(7): 214-221.
doi: 10.1177/004051757404400313
[16] 陆彤, 唐虹, 赵敏, 等. 针织柔性传感器研制现状与展望[J]. 针织工业, 2024(9): 91-94.
LU Tong, TANG Hong, ZHAO Min, et al. Development status and prospect of knitting flexible sensor[J]. Knitting Industries, 2024(9): 91-94.
[17] ZHOU W, ZHANG L, ZHANG J C, et al. Textile electrodes for electrocardiogram monitoring[J]. Advanced Materials Technologies, 2025, 10(10): 2401279.
doi: 10.1002/admt.v10.10
[18] 王恬雨, 王傲, 曹少杰, 等. 刺绣工艺影响金属混纺纱线织物电极的结构与性能[J]. 传感技术学报, 2023, 36(10): 1522-1530.
WANG Tianyu, WANG Ao, CAO Shaojie, et al. Effect of embroidery processing on structure and performance of metal-based textile electrodes[J]. Chinese Journal of Sensors and Actuators, 2023, 36(10): 1522-1530.
[19] LAN T X, TIAN H M, CHEN X L, et al. Treefrog-inspired flexible electrode with high permeability, stable adhesion, and robust durability[J]. Advanced Materials, 2024, 36(31): 2404761.
doi: 10.1002/adma.v36.31
[20] RUAN R C, LI J W, XU K, et al. Hydrogel patch with biomimetic tree frog micropillars for enhanced adhesion and perspiration wicking[J]. ACS Applied Polymer Materials, 2024, 6(8): 4599-4606.
doi: 10.1021/acsapm.4c00147
[21] 唐虹, 沈钰茜, 姜萌, 等. 一种基于树蛙足掌吸盘结构的仿生刺绣心电电极: CN119366926A[P]. 2025-01-28.
TANG Hong, SHEN Yuqian, JIANG Meng, et al. Bionic embroidered electrocardiogram electrode based on toe pad sucker structure of tree frog: CN119366926A[P]. 2025-01-28.
[22] 周金利, 郑俊杰, 刘思琪, 等. 不同制备工艺对织物电极心电信号质量的影响[J]. 现代纺织技术, 2025, 33(4): 113-121.
ZHOU Jinli, ZHENG Junjie, LIU Siqi, et al. Effect of different manufacturing processes on ECG signal quality of textile electrodes[J]. Advanced Textile Technology, 2025, 33(4): 113-121.
[23] KANNAIAN T, NEELAVENI R, THILAGAVATHI G. Design and development of embroidered textile electrodes for continuous measurement of electrocardiogram signals[J]. Journal of Industrial Textiles, 2013, 42(3): 303-318.
doi: 10.1177/1528083712438069
[24] LUO N Q, DAI W X, LI C L, et al. Flexible piezoresistive sensor patch enabling ultralow power cuffless blood pressure measurement[J]. Advanced Functional Materials, 2016, 26(8): 1178-1187.
doi: 10.1002/adfm.v26.8
[1] PENG Yangyang, SUN Fengxin, PAN Ruru. Multiscale construction and characterization of switchable textile strain sensor [J]. Journal of Textile Research, 2026, 47(02): 111-118.
[2] LIU Yiming, LI Lin, DU Xianjing, LIU Pan, YIN Xia, TIAN Mingwei. Preparation of elastic conductive yarns with internal spiral structure and regulation of their strain-insensitive performance [J]. Journal of Textile Research, 2026, 47(01): 115-122.
[3] SHAO Jianbo, YUE Xinyan, CHEN Yu, HAN Xiao, HONG Jianhan. Construction and sensing performance of all knitted multi-modal flexible capacitive sensor [J]. Journal of Textile Research, 2026, 47(01): 123-131.
[4] WANG Xiaohu, BAO Anna, WEI Jingwen, ZHAO Xiaoman, HAN Xiao, HONG Jianhan. One-step fabrication and application of cross-scale sensing yarns via synergistic electrospinning-electrospraying process [J]. Journal of Textile Research, 2025, 46(12): 101-109.
[5] ZHANG Ying, GUO Mingjing, WANG Lijun. Design of knitted temperature sensors and their sensing performance under wearing conditions [J]. Journal of Textile Research, 2025, 46(12): 123-132.
[6] WANG Liangyu, GAO Xiaohong, YU Caijiao, ZHANG Xueting, YANG Xuli. Preparation and sensing performance of reduced graphene oxide/copper nanoparticles conductive cotton fabrics [J]. Journal of Textile Research, 2025, 46(12): 181-187.
[7] YANG Mengxiao, QIU Xiaoxue, WU Fang, LIU Lin, YAO Juming. Preparation and strain sensing performance of silk-based conductive hydrogel fibers [J]. Journal of Textile Research, 2025, 46(12): 49-56.
[8] DENG Jing, WANG Ruining, SUN Runjun, ZHANG Yajuan, GUO Haibing, LEI Ke. Sodium alginate modified waterborne polyurethane/liquid metal conductive sensing fibers for pulse monitoring [J]. Journal of Textile Research, 2025, 46(12): 74-82.
[9] LIU Fei, LIU Lu, ZHENG Zhichao, LIU Junhong, WU Dequn, JIANG Qiuran. Preparation and properties of self-adhesive Zein-based ultrafine fibrous mats [J]. Journal of Textile Research, 2025, 46(11): 34-42.
[10] ZHANG Hongxia, QI Fangxi, ZHAO Jing, XING Yi, LÜ Zhijia. One-piece molding preparation of fabric-based sensors with honeycomb-structured dielectric layers and their properties [J]. Journal of Textile Research, 2025, 46(10): 86-94.
[11] JIA Chennuowa, ZHANG Yong, ZHU Weiyan, LIU Sai, TANG Ning. Influence of core types on performance of conductive core-spun yarn prepared from polyacrylonitrile nanofibers [J]. Journal of Textile Research, 2025, 46(07): 87-95.
[12] ZHANG Jinqin, LI Jing, XIAO Ming, BI Shuguang, RAN Jianhua. Preparation of polystyrene/reduced graphene oxide microsphere sensing electrothermal fabrics by self-assembly method [J]. Journal of Textile Research, 2025, 46(05): 202-213.
[13] SHE Yemei, PENG Yangyang, WANG Fameng, PAN Ruru. Preparation and performance of flexible pressure sensor based on warp knitted spacer fabric [J]. Journal of Textile Research, 2025, 46(03): 158-166.
[14] FAN Mengjing, YUE Xinyan, SHAO Jianbo, CHEN Yu, HONG Jianhan, HAN Xiao. Construction and sensing performance of capacitive torsion sensor made from electrospinning fiber core-spun yarn [J]. Journal of Textile Research, 2025, 46(02): 106-112.
[15] YANG Teng, SUN Zhihui, WU Siyu, YU Hui, WANG Fei. Preparation and performance of fabric sensor based on polyurethane/ carbon black/polyamide conductive yarn [J]. Journal of Textile Research, 2024, 45(12): 80-88.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备14006648号
Copyright 2021 © Editorial office of Journal of Textile Research
Supported by Beijing Magtech Co.Ltd