QUARTZ PULSE WAVE SENSOR WITH A CAPACITIVE CONTROL FOR HEALTHCARE SOLUTIONS

Bernhard Hametner & Siegfried Wassertheurer, “Pulse Waveform Analysis: Is It Ready for Prime Time?”, Curr Hypertens Rep., Center for Health & Bioresources, AIT Austrian Institute of Technology, 2017, Vienna, Austria, Vol. 19, Article number: 73.

Poleszczuk J, Debowska M, Dabrowski W, Wojcik-Zaluska A, Zaluska W, Waniewski J, “Subject-specific pulse wave propagation modeling: Towards enhancement of cardiovascular assessment methods”, PLoS ONE 13(1): e0190972, eCollection 2018.

Alberto P Avolio, Mark Butlin and Andrew Walsh, “Arterial blood pressure measurement and pulse wave analysis—their role in enhancing cardiovascular assessment”, Physiological Measurement: Institute of Physics and Engineering in Medicine, Vol. 31, No.1, 2009.

J. McLaughlin, M. McNeill, B. Braun and P. McCormack, “Piezoelectric sensor determination of arterial pulse wave velocity”, Physiological Measurement: Institute of Physics Publishing, No. 24, 2003, pp. 693–702.

Paolo Salvi, Filippo Scalise, Matteo Rovina, Francesco Moretti, et al. “Noninvasive Estimation of Aortic Stiffness Through Different Approaches Comparison With Intra-Aortic Recordings”, Hypertension, 2019, No.74, pp. 117-129.

Chen, Y.; Lu, B.; Chen, Y.; Feng, X. “Biocompatible and ultra-flexible inorganic strain sensors attached to skin for long-term vital signs monitoring”, IEEE Electron Device Lett, 2016, Vol. 37, pp. 496–499.

Wang Z., Wang S., Zeng J., Ren X. et al. “High sensitivity, wearable, piezoresistive pressure sensors based on irregular microhump structures and its applications in body motion sensing”. Small, 2016, Vol. 12, pp. 3827–3836.

Lovinsky L. “Urgent problems of metrological assurance of optical pulse oximetry”, IEEE Trans. Instrum. Meas., 2006, Vol. 55, pp. 869–875.

Loukogeorgakis S., Dawson R., Phillips N.; Martyn C., Greenwald S. “Validation of a device to measure arterial pulse wave velocity by a photoplethysmographic method”. Physiol. Meas. 2002, Vol. 23, pp. 581–596.

J. Muehlsteff, K. Dellimore, V. Aarts, R. Derkx, C. Peiker, C. Meyer, “Pulse Detection with a Single Accelerometer placed at the Carotid Artery: Performance in a Real-Life Diagnostic Test during Acute Hypotension”, Conf Proc IEEE Eng Med Biol Soc., 2015, pp. 435-437.

M. Theodor, J. Fiala, D. Ruh, et al. “Implantable accelerometer system for the determination of blood pressure using reflected wave transit time,” Sensor Actuat A-Phys, vol. 206, pp. 151-158, 2014.

McLaughlin J., McNeill M., Braun B., McCormack P., “Piezoelectric sensor determination of arterial pulse wave velocity”, Physiol. Meas., 2003,

Vol. 24, pp. 693–702.

Clemente F., Arpaia P., Cimmino P., “A piezo-film-based measurement system for global haemodynamic assessment”. Physiol. Meas., 2010, Vol. 31, pp. 697–714.

Murphy J., Morrison K., McLaughlin J., Manoharan G., Adgey A., “An innovative piezoelectric-based method for measuring pulse wave velocity in patients with hypertension”, J. Clin. Hypertens, 2011, Vol. 13, pp. 497–505.

Wang H, Wang L, Sun N, Yao Y, Hao L, Xu L and Greenwald SE, “Quantitative Comparison of the Performance of Piezoresistive, Piezoelectric, Acceleration, and Optical Pulse Wave Sensors”, Frontiers in Physiology, 2020, Volume 10, Article 1563.

A. Taranchuk, S. Pidchenko, “Design Methodology to Construct Information Measuring Systems Built on Piezoresonant Mechanotrons with a Modulated Interelectrode Gap”, Applied Measurement System, pp. 229-258, Published by InTech, Janeza Trdine 9, 51000 Rijeka, Croatia (2012).

B. Holbeche, G. Allen, “Influence of series reactance on quartz-crystal resonators”, IEE Proceedings, Vol. 130, Pt. G, No. 4, August 1983, pp. 145-152.

A. Taranchuk, S. Pidchenko and A. Zhyznevskyi “Modeling of Electro-mechanical Characteristics of Piezoresonance Pressure Sensors with Membrane Control of the Interelectrode Gap of a Piezoelectric Element”, Visnyk NTUU KPI, Seriia - Radiotekhnika, Radioaparatobuduvannia, (74), 2018, pp. 51-59.

A. Taranchuk, S. Pidchenko, “Diagnosis methods of cardiovascular disease, based on the acoustic-mechanotron principle of pulse wave sensing”, 2017 XXIInd Int. Seminar/Workshop on Direct and Inverse Problems of Electromagnetic and Acoustic Wave Theory (DIPED)], pp. 75 – 79, IEEE publ., 25-28 Sept., Dnepr, Ukraine (2017).

A. Taranchuk, “Construction of measuring piezoresonance mechanotrons and their practical implementation for telemedicine diagnostic systems”, Telecommunication and Radio Engineering, vol. 77, issue 3, pp. 269-281, Published by Begell House, Inc., USA (2018).

Piezoelectric Sensors (Springer Series on Chemical Sensors and Biosensors Book 5). Volume editors: Claudia Steinem, Andreas Janshoff; with contributions by M.A. Cooper ... [et al.]. Springer: Berlin, New York, 2006. 483 p.

O. Sergiyenko, B. Hernandez, V. Tyrsa, M. Rosas, W. Hernandez, J. Nieto Hipolito, O. Starostenko, M. Rivas Lopez, “Automotive FDS Resolution Improvement by Using the Principle of Rational Approximation”. IEEE Sensors Journal, Volume: 12, Issue: 5, May, 2012, pp. 1112 - 1121.