An Extreme Learning Machine for Blood Pressure Waveform Estimation using the Photoplethysmography Signal

Journal of Engineering Research and Sciences Pub Date : 2022-04-01 DOI:10.55708/js0104018

G. Tapia, Rodrigo F. Salas, Matías Salinas, C. Saavedra, A. Veloz, Alexis Arriola, S. Chabert, A. Glaria

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Abstract

: Blood Pressure (BP) waveform is a result of the response of the arteries to the blood ejection produced by the heart and, therefore, it is an important indicator of the state of the cardiovascular system. Currently, its measurement is performed invasively in critically ill patients who need a continuous and real time monitoring of their treatment response, however, it is possible to measure the BP, continuously and non-invasively, in non-critical patients to detect, monitor and control possible hypertensive events. Nevertheless, current non-invasive techniques can cause discomfort in patients and they are not used in critically ill patients. Consequently, non-Invasive and minimally-Intrusive methodologies (nImI) are required to estimate BP and its waveform. In the current study, the performance of machine learning algorithms, speciﬁcally the Extreme Learning Machine (ELM) algorithm, is evaluated to estimate both Blood Pressure and its waveform from the Photoplethysmography (PPG) signal and its ﬁrst derivative’s (VPG) waveforms. A total of 15 healthy volunteers participated in this study. They performed two handgrips, which is isometric maneuver to induce controlled BP rises. The ﬁrst handgrip is used to train ELM and the second handgrip is used to test the ELM. Our results show that there are high correlation performances ( 0 . 98 ) between the estimated and measured BP waveforms, and a relative error of 3 . 3 ± 1 . 4% . An arterial volume-clamp at the middle ﬁnger is used as the gold-standard measurement. Meanwhile, BP extreme values estimations, Systolic BP (SBP) and Diastolic BP (DBP), are also performed. ELMs have a performance with an average RMSE of 5 . 9 ± 2 . 7 mmHG for SBP and 4 . 8 ± 2 . 0 mmHg for DBP and, an average relative error of 5 . 0 ± 2 . 7% for SBP and 7 . 0 ± 4 . 0% for DBP.

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利用光电容积脉搏波信号估计血压波形的极限学习机

血压(BP)波形是动脉对心脏喷射出的血液作出反应的结果，因此，它是心血管系统状态的重要指标。目前，对危重患者进行血压测量是有创的，需要对其治疗反应进行连续、实时的监测，而对非危重患者进行连续、无创的血压测量，以发现、监测和控制可能发生的高血压事件是可能的。然而，目前的非侵入性技术可能会引起患者不适，并且不会用于危重患者。因此，需要非侵入性和最小侵入性方法(nImI)来估计血压及其波形。在目前的研究中，评估了机器学习算法的性能，特别是极限学习机(ELM)算法，以从光容积脉搏波(PPG)信号及其一阶导数(VPG)波形中估计血压及其波形。共有15名健康志愿者参加了这项研究。他们进行了两次手握，这是一种等距操作，以诱导可控的血压升高。第一个握把用于训练ELM，第二个握把用于测试ELM。我们的研究结果表明，有很高的相关性能(0。98)在估计和测量的BP波形之间，相对误差为3。3±1。4%。在中指处使用动脉容量钳作为金标准测量。同时，还进行了血压极值估计，收缩压(SBP)和舒张压(DBP)。elm的平均RMSE为5。9±2。收缩压7毫米汞柱，4。8±2。DBP为0 mmHg，平均相对误差为5。0 ± 2 ．收缩压7%，7。0±4。DBP为0%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Engineering Research and Sciences

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