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Main Authors: Zolfaghari, Parviz, Koca, Beril Yagmur, Abbasiasl, Taher, Urey, Hakan, Mirzajani, Hadi
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.20415
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author Zolfaghari, Parviz
Koca, Beril Yagmur
Abbasiasl, Taher
Urey, Hakan
Mirzajani, Hadi
author_facet Zolfaghari, Parviz
Koca, Beril Yagmur
Abbasiasl, Taher
Urey, Hakan
Mirzajani, Hadi
contents We present a multifunctional, antenna-integrated capacitive sensing (MAiCaS) platform for passive, wireless, and real-time cardiovascular monitoring. Unlike conventional systems that require separate sensors and wireless modules, our device unifies sensing, telemetry, and mechanical functionality into a compact and scalable design by exploiting the parasitic capacitance of an inductive antenna as a strain-sensitive element. The sensor is fabricated using a cleanroom-free, single-step UV laser patterning process on a flexible PDMS substrate, reducing manufacturing complexity and enabling high reproducibility. The MAiCaS is suitable for three different applications: as a sensor for epicardial strain measurement, a stent as a sensor, and a vascular graft sensor. We demonstrate MAiCaS's versatility by validating its wireless resonance-based response to strain, pressure, and deformation across unrolled and rolled forms. In vitro experiments demonstrated consistent resonance frequency shifts under physiological conditions, with stable performance on skin, in PBS, human serum, and simulated vascular environments. Repeatability and aging tests confirmed its long-term reliability and elasticity under cyclic loading. Calibration curves revealed high sensitivity across all configurations, with wireless interrogation achieved through S11 parameter measurements and resonance frequency shift as the output metric. The sensitivity of the device was measured to be 2.9 MHz per 1% strain, 0.43 MHz/mmHg, and 309.6kHz/\textmu m for epicardial patch, graft, and stent integrated sensor, respectively. The operation of MAiCaS was evaluated in a human experiment. This monolithic sensor architecture provides a scalable and cost-effective solution for battery-free monitoring of vascular dynamics, with potential for remote diagnostics, post-surgical follow-up, and continuous cardiovascular health management.
format Preprint
id arxiv_https___arxiv_org_abs_2510_20415
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Multifunctional Capacitive Sensing Platform for Wireless Vascular and Heart Monitoring
Zolfaghari, Parviz
Koca, Beril Yagmur
Abbasiasl, Taher
Urey, Hakan
Mirzajani, Hadi
Systems and Control
We present a multifunctional, antenna-integrated capacitive sensing (MAiCaS) platform for passive, wireless, and real-time cardiovascular monitoring. Unlike conventional systems that require separate sensors and wireless modules, our device unifies sensing, telemetry, and mechanical functionality into a compact and scalable design by exploiting the parasitic capacitance of an inductive antenna as a strain-sensitive element. The sensor is fabricated using a cleanroom-free, single-step UV laser patterning process on a flexible PDMS substrate, reducing manufacturing complexity and enabling high reproducibility. The MAiCaS is suitable for three different applications: as a sensor for epicardial strain measurement, a stent as a sensor, and a vascular graft sensor. We demonstrate MAiCaS's versatility by validating its wireless resonance-based response to strain, pressure, and deformation across unrolled and rolled forms. In vitro experiments demonstrated consistent resonance frequency shifts under physiological conditions, with stable performance on skin, in PBS, human serum, and simulated vascular environments. Repeatability and aging tests confirmed its long-term reliability and elasticity under cyclic loading. Calibration curves revealed high sensitivity across all configurations, with wireless interrogation achieved through S11 parameter measurements and resonance frequency shift as the output metric. The sensitivity of the device was measured to be 2.9 MHz per 1% strain, 0.43 MHz/mmHg, and 309.6kHz/\textmu m for epicardial patch, graft, and stent integrated sensor, respectively. The operation of MAiCaS was evaluated in a human experiment. This monolithic sensor architecture provides a scalable and cost-effective solution for battery-free monitoring of vascular dynamics, with potential for remote diagnostics, post-surgical follow-up, and continuous cardiovascular health management.
title A Multifunctional Capacitive Sensing Platform for Wireless Vascular and Heart Monitoring
topic Systems and Control
url https://arxiv.org/abs/2510.20415