Abstract
Abstract Arterial blood pressure is one of the most important cardiovascular parameters. Yet, current-generation devices for continuous, noninvasive acquisition are few, expensive and bulky. Novel signal processing applied to easily acquired unimodal signals can alleviate this issue, reducing size, cost and expanding the use of such devices to ambulatory, everyday settings. The features of pulse waves acquired by photo- or impedance-plethysmography can be used to estimate the underlying blood pressure. We present a progressive dynamic time warping algorithm, which implicitly parametrizes the morphological changes in these waves. This warping method is universally applicable to most pulse wave shapes, as it is largely independent of fiducial point detection or explicit parametrization. The algorithm performance is validated in a feature selection and regression framework against a continuous, noninvasive Finapres NOVA monitor, regarding systolic, mean and diastolic pressures during a light physical strain test protocol on four clinically healthy subjects (age18- 33, one female). The obtained mean error is 2.13 mmHg, the mean absolute error is 5.4 mmHg and the standard deviation is 5.6 mmHg. These results improve on our previous work on dynamic time warping. Using single-sensor, peripherally acquired pulse waves, progressive dynamic time warping can thus improve the flexibility of noninvasive, continuous blood pressure estimation.
Highlights
The monitoring of cardiovascular parameters is an important part of modern healthcare, with arterial blood pressure (ABP) being one of the most prominent ones
We propose progressive dynamic time warping (PDTW) as an alternative processing of plethysmographic waveforms, which does not rely on identifying fiducial points or performing pulse decomposition analysis (PDA)
This explains the similar results to our previous work on spectral parametrization of pulse waves, where the phase information proved to be very predictive of ABP [7]
Summary
1.1 MotivationThe monitoring of cardiovascular parameters is an important part of modern healthcare, with arterial blood pressure (ABP) being one of the most prominent ones. Noninvasive methods, of which volume clamping is the most readily available, are held back by an inconvenient recording setup, or/and by low accuracy in real world conditions. They require dedicated, custom hardware, incurring large supplementary costs. Pulse wave analysis (PWA) methods rely on such unimodal, localized plethysmographic signals to infer the underlying blood pressure and other parameters (e.g. arterial stiffness) [1][2]. They can be fed with photoplethysmographic (PPG) or impedance plethysmographic (IPG) waveforms
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