Advanced waveform analysis of the photoplethysmogram signal using complementary signal processing techniques for the extraction of biomarkers of cardiovascular function

Aristide Jun Wen Mathieu; Miquel Serna Pascual; Peter H Charlton; Maria Volovaya; Jenny Venton; Philip J Aston; Manasi Nandi; Jordi Alastruey

doi:10.1177/20480040231225384

Advanced waveform analysis of the photoplethysmogram signal using complementary signal processing techniques for the extraction of biomarkers of cardiovascular function

JRSM Cardiovasc Dis. 2024 Feb 1:13:20480040231225384. doi: 10.1177/20480040231225384. eCollection 2024 Jan-Dec.

Authors

Aristide Jun Wen Mathieu¹, Miquel Serna Pascual², Peter H Charlton³, Maria Volovaya², Jenny Venton², Philip J Aston⁴, Manasi Nandi², Jordi Alastruey¹

Affiliations

¹ Department of Biomedical Engineering, School of Biomedical Engineering and Imaging Sciences, Faculty of Life Sciences and Medicine, King's College London, St Thomas' Hospital, London, UK.
² School of Cancer and Pharmaceutical Science, Faculty of Life Sciences and Medicine, King's College London, London, UK.
³ Department of Public Health and Primary Care, University of Cambridge, Cambridge, Cambridgeshire, UK.
⁴ Department of Mathematics, University of Surrey, Guildford, UK.

Abstract

Introduction: Photoplethysmogram signals from wearable devices typically measure heart rate and blood oxygen saturation, but contain a wealth of additional information about the cardiovascular system. In this study, we compared two signal-processing techniques: fiducial point analysis and Symmetric Projection Attractor Reconstruction, on their ability to extract new cardiovascular information from a photoplethysmogram signal. The aim was to identify fiducial point analysis and Symmetric Projection Attractor Reconstruction indices that could classify photoplethysmogram signals, according to age, sex and physical activity.

Methods: Three datasets were used: an in-silico dataset of simulated photoplethysmogram waves for healthy male participants (25-75 years old); an in-vivo dataset containing 10-min photoplethysmogram recordings from 57 healthy subjects at rest (18-39 or > 70 years old; 53% female); and an in-vivo dataset containing photoplethysmogram recordings collected for 4 weeks from a single subject, in daily life. The best-performing indices from the in-silico study (5/48 fiducial point analysis and 6/49 Symmetric Projection Attractor Reconstruction) were applied to the in-vivo datasets.

Results: Key fiducial point analysis and Symmetric Projection Attractor Reconstruction indices, which showed the greatest differences between groups, were found to be consistent across datasets. These indices were related to systolic augmentation, diastolic peak positioning and prominence, and waveform variability. Both fiducial point analysis and Symmetric Projection Attractor Reconstruction techniques provided indices that supported the classification of age and physical activity, but not sex.

Conclusions: Both fiducial point analysis and Symmetric Projection Attractor Reconstruction techniques demonstrated utility in identifying cardiovascular differences between individuals and within an individual over time. Future research should investigate the potential utility of these techniques for extracting information on fitness and disease, to support healthcare-decision making.

Keywords: Photoplethysmogram; Symmetric Projection Attractor Reconstruction; fiducial point analysis; pulse wave morphology; pulse wave variability; vascular aging.

Abstract

Grants and funding