TY - JOUR
T1 - Computational modelling and application of mechanical waves to detect arterial network anomalies
T2 - Diagnosis of common carotid stenosis
AU - Flores Gerónimo, Joaquín
AU - Keramat, Alireza
AU - Alastruey, Jordi
AU - Duan, Huan Feng
N1 - Funding Information:
JFG acknowledges support of a postdoctoral fellowship from the Hong Kong Polytechnique University. through project 1-YY4Y. JA acknowledges support of the Wellcome EPSRC Centre for Medical Engineering at King's College London under Grant [WT 203148/Z/16/Z] and the Department of Health through the National Institute for Health Research Cardiovascular MedTech Co-Operative at Guy's and St Thomas’ NHS Foundation Trust. HFD acknowledges the support of the Hong Kong Research Grants Council (RGC) under project 15200719.
Funding Information:
JFG acknowledges support of a postdoctoral fellowship from the Hong Kong Polytechnique University. through project 1-YY4Y. JA acknowledges support of the Wellcome EPSRC Centre for Medical Engineering at King’s College London under Grant [WT 203148/Z/16/Z] and the Department of Health through the National Institute for Health Research Cardiovascular MedTech Co-Operative at Guy’s and St Thomas’ NHS Foundation Trust. HFD acknowledges the support of the Hong Kong Research Grants Council (RGC) under project 15200719 .
Publisher Copyright:
© 2022 Elsevier B.V.
PY - 2022/12
Y1 - 2022/12
N2 - Background and Objective: This paper proposes a novel strategy to localize anomalies in the arterial network based on its response to controlled transient waves. The idea is borrowed from system identification theories in which wave reflections can render significant information about a target system. Cardiovascular system studies often focus on the waves originating from the heart pulsations, which are of low bandwidth and, hence, can hardly carry information about the arteries with the desired resolution. Methods: Our strategy uses a relatively higher bandwidth transient signal to characterize healthy and unhealthy arterial networks through a frequency response function (FRF). We tested our novel approach on data simulated using a one-dimensional cardiovascular model that produced pulse waves in the larger arteries of the arterial network. Specifically, we excited the blood flow from the brachial artery with a relatively high bandwidth flow disturbance and collected the subsequent pressure waveform at peripheral positions. To better differentiate FRFs of healthy and unhealthy networks, we used a FRF that removes the effects of heart pulsations. Results: Results demonstrate the ability of the proposed FRF to detect and follow-up on the development of a common carotid artery (CCA) stenosis. We tested distinct geometrical variations of the stenosis (size, length and position) and observed differences between the FRFs of healthy and unhealthy networks in all cases; such differences were mainly due to geometrical variations determined by the stenosis. Conclusions: We have provided a theoretical proof of concept that demonstrates the ability of our novel strategy to detect and track the development of CCA stenosis by using peripheral pressure waves that can be measured non-invasively in clinical practice.
AB - Background and Objective: This paper proposes a novel strategy to localize anomalies in the arterial network based on its response to controlled transient waves. The idea is borrowed from system identification theories in which wave reflections can render significant information about a target system. Cardiovascular system studies often focus on the waves originating from the heart pulsations, which are of low bandwidth and, hence, can hardly carry information about the arteries with the desired resolution. Methods: Our strategy uses a relatively higher bandwidth transient signal to characterize healthy and unhealthy arterial networks through a frequency response function (FRF). We tested our novel approach on data simulated using a one-dimensional cardiovascular model that produced pulse waves in the larger arteries of the arterial network. Specifically, we excited the blood flow from the brachial artery with a relatively high bandwidth flow disturbance and collected the subsequent pressure waveform at peripheral positions. To better differentiate FRFs of healthy and unhealthy networks, we used a FRF that removes the effects of heart pulsations. Results: Results demonstrate the ability of the proposed FRF to detect and follow-up on the development of a common carotid artery (CCA) stenosis. We tested distinct geometrical variations of the stenosis (size, length and position) and observed differences between the FRFs of healthy and unhealthy networks in all cases; such differences were mainly due to geometrical variations determined by the stenosis. Conclusions: We have provided a theoretical proof of concept that demonstrates the ability of our novel strategy to detect and track the development of CCA stenosis by using peripheral pressure waves that can be measured non-invasively in clinical practice.
KW - Cardiovascular modelling
KW - Common carotid stenosis
KW - Frequency response function
KW - System identification
KW - Transient signal
UR - http://www.scopus.com/inward/record.url?scp=85141372062&partnerID=8YFLogxK
U2 - 10.1016/j.cmpb.2022.107213
DO - 10.1016/j.cmpb.2022.107213
M3 - Journal article
C2 - 36356386
AN - SCOPUS:85141372062
SN - 0169-2607
VL - 227
JO - Computer Methods and Programs in Biomedicine
JF - Computer Methods and Programs in Biomedicine
M1 - 107213
ER -