Frequency spectrum analysis of finger photoplethysmographic waveform variability during haemodialysis

Javed, Faizan; Middleton, Paul; Malouf, Philip; Grace, Clare; Savkin, Andrey V.; Lovell, Nigel H.; Steel, Elizabeth; Mackie, James

doi:10.1088/0967-3334/31/9/010

Cited by 29 publications

(37 citation statements)

References 27 publications

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“…While previous studies have demonstrated clear links between PPGV and conditions associated with sympathetic changes [5,7,10,11,16,17,26], no study has ever been performed to establish a relationship between the spectral pattern of PPGV and a quantitative measure of vascular tone. In addition, since the suppression of sympathetic vascular tone could lead to a relative dominance of HF over LF power in PPGV [11,26], we also examined whether the PPGV spectral powers were useful for the categorical identification of patients in highly vasodilated states (indicated by the low SVR).…”

Section: Introductionmentioning

confidence: 99%

“…Infrared light can penetrate deep into the skin and subcutaneous tissue and is relatively insensitive to blood oxygenation [8,12], thus the resultant PPG signal reflects total blood volume change in the fingertip circulation, under the combined influences of central perfusion pressure and local sympathetic vascular control [2]. Similar to BPV, the frequency spectrum of PPG variability (PPGV) consists of both low frequency (LF) vasomotor waves, and high frequency (HF) respiratory fluctuations [5,10,11,16,17,23,26]. Sympathetic activation induced by active standing has been shown to augment normalized LF power of PPGV [5,17], whereas suppression of basal sympathetic tone by induction of anesthesia leads to a relative reduction in LF and enhancement of HF fluctuations [11,26].…”

Section: Introductionmentioning

confidence: 99%

“…Sympathetic activation induced by active standing has been shown to augment normalized LF power of PPGV [5,17], whereas suppression of basal sympathetic tone by induction of anesthesia leads to a relative reduction in LF and enhancement of HF fluctuations [11,26]. Recent studies by our group have highlighted the potential of PPGV for identifying changes in sympathetic vascular control associated with various critical conditions in the clinical setting, including blood volume loss, sepsis, and endotoxic shock [7,10,16,31], and raised the exciting possibility of detecting these complications at an early stage using an easy-to-measure non-invasive PPG signal.…”

Section: Introductionmentioning

confidence: 99%

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Fingertip photoplethysmographic waveform variability and systemic vascular resistance in intensive care unit patients

Middleton

Grace

Steel

et al. 2011

Med Biol Eng Comput

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Low frequency variability in the fingertip photoplethysmogram (PPG) waveform has been utilized for inferring sympathetic vascular control, but its relationship with a quantitative measure of vascular tone has not been established. In this study, we examined the association between fingertip PPG waveform variability (PPGV) and systemic vascular resistance (SVR) obtained from thermodilution cardiac output (CO) and intra-arterial pressure measurements in 48 post cardiac surgery intensive care unit patients. Among the hemodynamic measurements, both CO (P < 0.05) and SVR (P < 0.0001) had statistically significant relationships with the normalized low frequency power (LF(nu)) of PPGV. The LF(nu) of baseline PPGV had moderate but significant positive correlation with SVR (r = 0.54, P < 0.0001), and a value below 52.5 nu was able to identify SVR < 900 dyn s cm⁻⁵ with sensitivity of 59% and specificity of 95%. The results have provided quantitative evidence to confirm the link between fingertip PPGV and sympathetic vascular control. Suppression of LF vasomotor waves leading to dominance of respiration-related HF fluctuations in the fingertip circulation was a specific (though not sensitive) marker of systemic vasodilatation, which could be potentially utilized for the assessment of critical care patients.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Fingertip photoplethysmographic waveform variability and systemic vascular resistance in intensive care unit patients

Middleton

Grace

Steel

et al. 2011

Med Biol Eng Comput

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“…It is well-known that PPG signal contains information related to the cardiovascular dynamics. Some low frequency oscillations in PPG also reflect the function of autonomic nervous system [11,23,24]. The sources of these frequency components may be blood pressure control, thermoregulation, central baroreflex activity, vasomotoric rhythms, autonomous nervous system (ANS), neurogenic activity, myogenic rhythm, sympathetic modulation of peripheral vasculature (e.g., finger skin), and heart-synchronous pulse waveform [11,14,23,25,32].…”

Section: Introductionmentioning

confidence: 99%

“…Some low frequency oscillations in PPG also reflect the function of autonomic nervous system [11,23,24]. The sources of these frequency components may be blood pressure control, thermoregulation, central baroreflex activity, vasomotoric rhythms, autonomous nervous system (ANS), neurogenic activity, myogenic rhythm, sympathetic modulation of peripheral vasculature (e.g., finger skin), and heart-synchronous pulse waveform [11,14,23,25,32]. Other than the cardiac and respiratory rhythm, the sources of the low frequency oscillations present in PPG signal are not fully understood because of the highly complicated nature of the circulatory system, especially the interaction between the circulatory system and the ANS [15,24].…”

Section: Introductionmentioning

confidence: 99%

Reconstruction of gastric slow wave from finger photoplethysmographic signal using radial basis function neural network

Yacin

Chakravarthy

Manivannan

2011

Med Biol Eng Comput

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Extraction of extra-cardiac information from photoplethysmography (PPG) signal is a challenging research problem with significant clinical applications. In this study, radial basis function neural network (RBFNN) is used to reconstruct the gastric myoelectric activity (GMA) slow wave from finger PPG signal. Finger PPG and GMA (measured using Electrogastrogram, EGG) signals were acquired simultaneously at the sampling rate of 100 Hz from ten healthy subjects. Discrete wavelet transform (DWT) was used to extract slow wave (0-0.1953 Hz) component from the finger PPG signal; this slow wave PPG was used to reconstruct EGG. A RBFNN is trained on signals obtained from six subjects in both fasting and postprandial conditions. The trained network is tested on data obtained from the remaining four subjects. In the earlier study, we have shown the presence of GMA information in finger PPG signal using DWT and cross-correlation method. In this study, we explicitly reconstruct gastric slow wave from finger PPG signal by the proposed RBFNN-based method. It was found that the network-reconstructed slow wave provided significantly higher (P < 0.0001) correlation (≥ 0.9) with the subject's EGG slow wave than the correlation obtained (≈0.7) between the PPG slow wave from DWT and the EEG slow wave. Our results showed that a simple finger PPG signal can be used to reconstruct gastric slow wave using RBFNN method.

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Ambulatory and Popular Sensor Measurements

2020

Body Sensor Networking, Design and Algorithms

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Frequency spectrum analysis of finger photoplethysmographic waveform variability during haemodialysis

Cited by 29 publications

References 27 publications

Fingertip photoplethysmographic waveform variability and systemic vascular resistance in intensive care unit patients

Fingertip photoplethysmographic waveform variability and systemic vascular resistance in intensive care unit patients

Reconstruction of gastric slow wave from finger photoplethysmographic signal using radial basis function neural network

Ambulatory and Popular Sensor Measurements

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