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Main Authors: Nateghi, Masoud, Sameni, Reza
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.15687
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author Nateghi, Masoud
Sameni, Reza
author_facet Nateghi, Masoud
Sameni, Reza
contents Oscillometry is the standard method for non-invasive, cuff-based blood pressure (BP) measurement, but it introduces systematic errors that may impact clinical accuracy. This study investigates the sources of these errors--primarily the limitations of oscillometry itself and respiration-induced fluctuations--using BP waveform data from the MIMIC database. Oscillometry tends to underestimate systolic BP and overestimate diastolic BP, while respiration introduces cyclical variations that further degrade measurement precision. To mitigate these effects, we propose an estimation-theoretic framework employing least squares (LS) and maximum likelihood (ML) methods for correcting both single and repeated BP measurements. LS estimation supports conventional multi-measurement averaging protocols, whereas the ML approach incorporates prior knowledge of measurement errors, offering improved performance. Our results demonstrate that leveraging statistical priors across multiple readings can enhance the accuracy of non-invasive BP monitoring, with potential implications for improving cardiovascular diagnosis and treatment.
format Preprint
id arxiv_https___arxiv_org_abs_2508_15687
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Estimation-Theoretic Bias Reduction for Oscillometric Blood Pressure Readings
Nateghi, Masoud
Sameni, Reza
Signal Processing
Oscillometry is the standard method for non-invasive, cuff-based blood pressure (BP) measurement, but it introduces systematic errors that may impact clinical accuracy. This study investigates the sources of these errors--primarily the limitations of oscillometry itself and respiration-induced fluctuations--using BP waveform data from the MIMIC database. Oscillometry tends to underestimate systolic BP and overestimate diastolic BP, while respiration introduces cyclical variations that further degrade measurement precision. To mitigate these effects, we propose an estimation-theoretic framework employing least squares (LS) and maximum likelihood (ML) methods for correcting both single and repeated BP measurements. LS estimation supports conventional multi-measurement averaging protocols, whereas the ML approach incorporates prior knowledge of measurement errors, offering improved performance. Our results demonstrate that leveraging statistical priors across multiple readings can enhance the accuracy of non-invasive BP monitoring, with potential implications for improving cardiovascular diagnosis and treatment.
title Estimation-Theoretic Bias Reduction for Oscillometric Blood Pressure Readings
topic Signal Processing
url https://arxiv.org/abs/2508.15687