Wireless batteryless soft sensors for ambulatory cardiovascular health monitoring

Matthew Guess; Ira Soltis; Bruno Rigo; Nathan Zavanelli; Sara Kapasi; Hyeonseok Kim; Woon-Hong Yeo

doi:10.20517/ss.2023.17

Soft Science ›› 2023, Vol. 3 ›› Issue (3) :23 DOI: 10.20517/ss.2023.17

Research Article

Wireless batteryless soft sensors for ambulatory cardiovascular health monitoring

Matthew Guess ¹^,²
, Ira Soltis ¹^,²
, Bruno Rigo ²^,³
, Nathan Zavanelli ¹^,²
, Sara Kapasi ²^,⁴
, Hyeonseok Kim ¹^,²
, Woon-Hong Yeo ¹^,²^,⁴^,⁵^,^*

Author information +

History +

PDF

Abstract

Seismocardiography (SCG) is the measure of local vibrations in the chest due to heartbeats. Typically, SCG signals are measured using rigid integrated circuit (IC) accelerometers and bulky electronics. However, as alternatives, recent studies of emerging flexible sensors show promise. Here, we introduce the development of wireless soft capacitive sensors that require no battery or rigid IC components for measuring SCG signals for cardiovascular health monitoring. Both the capacitive and inductive components of the circuit are patterned with laser micromachining of a polyimide-coated copper and are encapsulated with an elastomer. The wearable soft sensor can detect small strain changes on the skin, which is wirelessly measured by examining the power reflected from the antenna at a stimulating frequency. The performance of the device is verified by comparing the fiducial points to SCG measured by a commercial accelerometer and electromyograms from a commercial electrode. Overall, the human subject study demonstrates that the fiducial points are consistent with data from commercial devices, showing the potential of the ultrathin soft sensors for ambulatory cardiovascular monitoring without bulky electronics and rigid components.

Keywords

Soft sensor / capacitive strain sensor / passive wireless / laser micromachining / LC resonance sensor / ambulatory monitoring / cardiovascular health

Cite this article

Download citation ▾

Matthew Guess, Ira Soltis, Bruno Rigo, Nathan Zavanelli, Sara Kapasi, Hyeonseok Kim, Woon-Hong Yeo. Wireless batteryless soft sensors for ambulatory cardiovascular health monitoring. Soft Science, 2023, 3(3): 23 DOI:10.20517/ss.2023.17

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Tsao CW,Almarzooq ZI.American Heart Association Council on Epidemiology and Prevention Statistics Committee and Stroke Statistics SubcommitteeHeart disease and stroke statistics-2023 update: a report from the american heart association.Circulation2023;147:e93-e621

[2]	Kim YS,Lee Y.All-in-one, wireless, stretchable hybrid electronics for smart, connected, and ambulatory physiological monitoring.Adv Sci2019;6:1900939 PMCID:PMC6724359

[3]	Inan OT,Park KS.Ballistocardiography and seismocardiography: a review of recent advances.IEEE J Biomed Health Inform2015;19:1414-27

[4]	Guess M,Yeo WH.Recent advances in materials and flexible sensors for arrhythmia detection.Materials2022;15:724 PMCID:PMC8836661

[5]	Liu Y,Qazi R.Epidermal mechano-acoustic sensing electronics for cardiovascular diagnostics and human-machine interfaces.Sci Adv2016;2:e1601185 PMCID:PMC5262452

[6]	Yang C.Combined seismo- and gyro-cardiography: a more comprehensive evaluation of heart-induced chest vibrations.IEEE J Biomed Health Inform2018;22:1466-75

[7]	Ha T,Liu S.A chest-laminated ultrathin and stretchable e-tattoo for the measurement of electrocardiogram, seismocardiogram, and cardiac time intervals.Adv Sci2019;6:1900290 PMCID:PMC6662084

[8]	Lim HR,Qazi R,Jeong JW.Advanced soft materials, sensor integrations, and applications of wearable flexible hybrid electronics in healthcare, energy, and environment.Adv Mater2020;32:e1901924

[9]	Herbert R,Kim YS,Yeo WH.Soft material-enabled, flexible hybrid electronics for medicine, healthcare, and human-machine interfaces.Materials2018;11:187 PMCID:PMC5848884

[10]	He W,Cheng Y.Intrinsic elastic conductors with internal buckled electron pathway for flexible electromagnetic interference shielding and tumor ablation.Sci China Mater2020;63:1318-29

[11]	Niu L,Wang K.High-speed sirospun conductive yarn for stretchable embedded knitted circuit and self-powered wearable device.Adv Fiber Mater2023;5:154-67

[12]	Liu X,Fan Q.Recent progress on smart fiber and textile based wearable strain sensors: materials, fabrications and applications.Adv Fiber Mater2022;4:361-89

[13]	Nayeem MOG,Jin H.All-nanofiber-based, ultrasensitive, gas-permeable mechanoacoustic sensors for continuous long-term heart monitoring.Proc Natl Acad Sci U S A2020;117:7063-70 PMCID:PMC7132136

[14]	Presti D, Santucci F, Massaroni C, Formica D, Setola R, Schena E. A multi-point heart rate monitoring using a soft wearable system based on fiber optic technology.Sci Rep2021;11:21162 PMCID:PMC8551187

[15]	Zavanelli N,Kim J.At-home wireless monitoring of acute hemodynamic disturbances to detect sleep apnea and sleep stages via a soft sternal patch.Sci Adv2021;7:eabl4146 PMCID:PMC8694628

[16]	Rienzo M, Rizzo G, Işılay ZM, Lombardi P. SeisMote: a multi-sensor wireless platform for cardiovascular monitoring in laboratory, daily life, and telemedicine.Sensors2020;20:680 PMCID:PMC7038355

[17]	Dinh A,Ko SB.A heart rate sensor based on seismocardiography for vital sign monitoring systems. In: 2011 24th Canadian Conference on Electrical and Computer Engineering(CCECE); 2011 May 8-11; Niagara, ON, Canada. IEEE; 2011. p. 000665-8.

[18]	Hesar M, Khan D, Seyedsadrkhani NS, Ingebrandt S. Contactless, battery-free, and stretchable wearable for continuous recording of seismocardiograms.ACS Appl Electron Mater2021;3:11-20

[19]	Sørensen K,Jensen AS,Struijk JJ.Definition of fiducial points in the normal seismocardiogram.Sci Rep2018;8:15455 PMCID:PMC6193995

[20]	Herbert R,Rigo B.Fully implantable wireless batteryless vascular electronics with printed soft sensors for multiplex sensing of hemodynamics.Sci Adv2022;8:eabm1175 PMCID:PMC9094660

[21]	Herbert R,Rigo B.Fully implantable batteryless soft platforms with printed nanomaterial-based arterial stiffness sensors for wireless continuous monitoring of restenosis in real time.Nano Today2022;46:101557 PMCID:PMC9970263

[22]	Yang S,Wu Q.Lignin-derived porous graphene for wearable and ultrasensitive strain sensors.J Mater Chem C2022;10:11730-8

[23]	Cao H,Oseng ML.Development and characterization of a novel interdigitated capacitive strain sensor for structural health monitoring.IEEE Sensors J2015;15:6542-8

[24]	Delalleau A,Lagarde JM,Bergheau JM.A nonlinear elastic behavior to identify the mechanical parameters of human skin in vivo.Skin Res Technol2008;14:152-64