In hypertension and aging, central elastic arteries become stiffer and hence the central pulse pressure is augmented due to the increase in the pulse wave velocity and the early return of reflected waves to the heart from the periphery. Valuable information on arterial properties, such as stiffness, can be obtained from both central (aortic) and peripheral (radial) pressure wave forms. A feasibility study for the noninvasive estimation of arterial stiffness using pressure waves detected by a pneumatic cuff wrapped around the upper arm is presented. The propagation and reflection of arterial pressure waves (generated by the heart) in the central elastic arteries are simulated using a simplified water hammer acoustic model. Furthermore, a lumped parameter model is used to describe the transmission of the pressure waves from the brachial artery to the cuff external wall. By combining the two models, we were able to simulate the pressure contours in the brachial artery and illustrate how these pressures transmit to the cuff’s external wall. The effects of aortic stiffness are investigated by simulating the model at different values of aortic elastic moduli and observing the pressure augmentation and the timing of feature points. This work was done as part of the development of a noninvasive diagnostic device by Pulsecor Ltd. The model results obtained in this work are in agreement with published experimental results and the device output; hence, the model can be used to develop the device’s stiffness estimation algorithm.
Issue Section:
Research Papers
1.
Liu
, H.
, Fukasaku
, K.
, Lwase
, H.
, Matsunaga
, N.
, He
, Y.
, Yokoi
, K.
, and Himeno
, R.
, 2003, “Influences of Non-planarity, Bifurcation, Dynamics, Inflow and Outflows on Blood Flow Patterns in the Aortic Arch: A Multi-scale Computational Study
,” Summer Bioengineering Conference
, Sonesta Beach Resort in Key Biscayne, FL
.2.
Fung
, Y.
, 1997, Biomechanics Circulation
, 2nd ed., Springer
, New York
, Vol. 3, pp. 155
–160
.3.
Nichols
, W. W.
, and O’Rourke
, F. M.
, 1998, McDonald’s Blood Flow in Arteries Theoretical, Experimental and Clinical Principles
, 4th ed., Arnold
, London
.4.
Pontrelli
, G.
, and Rossoni
, E.
, 2003, “Numeric Modelling of the Pressure Wave Propagation in the Arterial Flow
,” Int. J. Numer. Methods Fluids
0271-2091, 43
, pp. 651
–671
.5.
Giannattasio
, C.
, Achilli
, F.
, Failla
, M.
, Capra
, A.
, Vincenzi
, G.
, Corsi
, D.
, and Zazzeron
, C.
, 2004, “Arterial Stiffness in Heart Failure Patients: Dependence on Diastolic Dysfunction and Plasma Aldosterone Levels
,” Eur. Heart J.
0195-668X, 6
, pp. F30
–F34
.6.
Berger
, D. S.
, Li
, J. K.
, Laskey
, W. K.
, Noordergraaf
, A.
, 1993, “Repeated Reflection of Waves in the Systemic Arterial System
,” Am. J. Physiol. Heart Circ. Physiol.
0363-6135, 264
, pp. H269
–H281
.7.
Mackenzie
, I. S.
, Wilkinson
, I. B.
, and Cockcroft
, J. R.
, 2002, “Assessment of Arterial Stiffness in Clinical Practice
,” QJM
1460-2725, 95
, pp. 67
–74
.8.
O’Rourke
, M. F.
, 1982, Arterial Function in Health and Disease
Edinburgh
, Churchill
.9.
London
, G.
, Guerin
, A.
, Pannier
, B.
, Marchais
, S.
, Benetos
, A.
, and Safar
, M.
, 1992, “Increased Systolic Pressure in Chronic Uremia, Role of Arterial Wave Reflections
,” Hypertension
0194-911X, 2
, pp. 10
–19
.10.
Chen
, C.-H.
, Nevo
, E.
, Fetics
, B.
, Pak
, P.
, Yin
, F.
, and Maughan
, L.
, 1997, “A. Estimation of Central Aortic Pressure Waveform by Mathematical Transformation of Radial Tonometry Pressure: Validation of Generalized Transfer Function
,” Circulation
0009-7322, 95
, pp. 1827
–1836
.11.
Pauca
, A. L.
, O’Rourke
, M. F.
, and Kon
, N. D.
, 2001, “Prospective Evaluation of a Method for Estimating Ascending Aortic Pressure From the Radial Artery Pressure Waveform
,” Hypertension
0194-911X, 38
, pp. 932
–937
.12.
Takazawa
, K.
, Tanaka
, N.
, Fujita
, M.
, Matsuoka
, O.
, Saiki
, T.
, Aikawa
, M.
, and Tamura
, S.
, 1998, “Assessment of Vasoactive Agents and Vascular Ageing by the Second Derivative of Photoplethysmogram Waveform
,” Hypertension
0194-911X, 32
, pp. 365
–370
.13.
Chowienczyk
, P. J.
, Kelly
, R.
, MacCallum
, H.
, Millasseau
, S. C.
, Andersson
, T.
, Gosling
, R.
, and Ritter
, J.
, 1999, “Photoplethysmographic Assessment of Pulse Wave Reflection: Blunted Response to Endothelium Dependent Beta2 Adrenergic Vasodilation in Type II Diabetes Mellitus
,” J. Am. Coll. Cardiol.
0735-1097, 34
, pp. 2007
–2014
.14.
Nichols
, W. W.
, 2005, “Clinical Measurement of Arterial Stiffness Obtained From Non-Invasive Pressure Waveforms
,” Am. J. Hypertens.
0895-7061, 18
, pp. S3
–S10
.15.
Formaggia
, L.
, Lamponi
, D.
, and Quarteroni
, A.
, 2003, “One Dimensional Models for Blood Flow in Arteries
,” J. Eng. Math.
0022-0833, 47
, pp. 251
–276
.16.
Pontrelli
, G.
, and Rossoni
, E.
, 2002, “Numeric Modelling of the Pressure Wave Propagation in the Arterial Flow
,” Int. J. Numer. Methods Fluids
0271-2091, 43
, pp. 651
–671
.17.
Olfusen
, M.
, 1999, “Structured Tree Outflow Condition for Blood Flow in Larger Systemic Arteries
,” Am. J. Physiol.
0002-9513, 276
, pp. H257
–H268
.18.
Steele
, N.
, and Taylor
, C.
, 2003, “Simulation of Blood Flow in the Abdominal Aorta at Rest and During Exercise Using a 1-D Finite Element Method With Impedance Boundary Conditions Derived From a Fractal Tree
,” Summer Bioengineering Conference
, Sonesta Beach Resort in Key Biscayne, FL
.19.
Tang
, D.
, Yang
, C.
, and Huang
, Y.
, 1999, “Wall Stress and Strain Analysis Using a Three-Dimensional Thick-Wall Model With Fluid-Structure Interactions For Blood Flow in Carotid Arteries With Stenoses
,” Comput. Struct.
0045-7949, 72
, pp. 341
–356
.20.
Shahcheraghi
, N.
, Dwyer
, H.
, Cheer
, A.
, Barakat
, A.
, and Rutaganira
, T.
, 2002, “Unsteady and Three Dimensional Simulation of Blood Flow in the Human Aortic Arch
,” ASME J. Biomech. Eng.
0148-0731, 124
, pp. 378
–387
.21.
Mauck
, G.
, Smith
, C.
, Geddes
, L.
, and Bourland
, J.
, 1980, “The Meaning of the Point of Maximum Oscillations in Cuff Pressure in the Indirect Measurement of Blood Pressure: Part 11
,” ASME J. Biomech. Eng.
0148-0731, 102
, pp. 28
–33
.22.
Forster
, F.
, and Turney
, D.
, 1986, “Oscillometric Determination of Diastolic, Mean, and Systolic Blood Pressure: A Numerical Model
,” ASME J. Biomech. Eng.
0148-0731, 108
, pp. 359
–364
.23.
Drzewiecki
, G.
, Bansal
, V.
, Karam
, E.
, Hood
, R.
, and Apple
, H.
, 1993, “Mechanics of the Occlusive Arm Cuff and Its Application as a Volume Sensor
,” IEEE Trans. Biomed. Eng.
0018-9294, 40
, pp. 704
–708
.24.
Ursino
, M.
, and Cristalli
, C.
, 1995, “Mathematical Modeling of Noninvasive Blood Pressure Estimation Techniques—Part I—Pressure Transmission Across the Arm Tissue
,” ASME J. Biomech. Eng.
0148-0731, 117
, pp. 107
–116
.25.
Ursino
, M.
, and Cristalli
, C.
, 1995, “Mathematical Modeling of Noninvasive Blood Pressure Estimation Techniques—Part II—Brachial Hemodynamics
,” ASME J. Biomech. Eng.
0148-0731, 117
, pp. 117
–126
.26.
Ursino
, M.
, and Cristalli
, C.
, 1996, “A Mathematical Study of Some Biomechanical Factors Affecting the Oscillometric Blood Pressure Measurement
,” IEEE Trans. Biomed. Eng.
0018-9294, 43
, pp. 761
–778
.27.
Taylor
, M.
, 1959, “The Influence of the Anomalous Viscosity of Blood Upon Its Oscillatory Flow
,” Phys. Med. Biol.
0031-9155, 3
, pp. 273
–290
.28.
Womersley
, J. R.
, 1955, “Oscillatory Motion of a Viscous Liquid in a Thin-Walled Elastic Tube-I: The Linear Approximation For Long Waves
,” Philos. Mag.
0031-8086, 46
(7
), pp. 199
–221
.29.
Chang
, C.
, and Atabek
, H.
, 1961, “The Inlet Length For Oscillatory Flow and Its Effects on the Determination of the Rate of Flow in the Arteries
,” Phys. Med. Biol.
0031-9155, 6
, pp. 303
–317
.30.
Westerhof
, N.
, Bosman
, F.
, De Vries
, C. J.
, and Noordergraff
, A.
, 1969, “Analog Studies of Human Systemic Arterial Tree
,” J. Biomech.
0021-9290, 2
, pp. 121
–143
.31.
Bergel
, D. H.
, and Milnor
, W. R.
, 1965, “Pulmonary Vascular Impedance in the Dog
,” Circ. Res.
0009-7330, 26
, pp. 401
–415
.32.
Pollack
, G. H.
, Reddy
, R. V.
, and Noordergraaf
, A.
, 1968, “Input Impedance, Wave Travel and Reflections in the Human Pulmonary Arterial Tree: Studies Using an Electrical Analogue
,” IEEE Trans. Biomed. Eng.
0018-9294, 15
, pp. 151
–164
.33.
O’Rourke
, E. F. M.
, and Taylor
, M. G.
, 1967, “Input Impedance of the Systemic Circulation
,” Circ. Res.
0009-7330, 20
, pp. 365
–380
.34.
Mills
, C. J.
, Gabe
, I. T.
, Gault
, J. H.
, Mason
, D. T.
, Ross
, Jr., J.
, Braunwald
, E.
, and Shillingford
, J. P.
, 1970, “Pressure-Flow Relationships and Vascular Impedance in Man
,” Cardiovasc. Res.
0008-6363, 4
, pp. 405
–417
.35.
Mills
, C. J.
, and Gabe
, I. T.
, 1972, “Pulsatile Blood Velocity and Pressure and the Computer Analysis of Cardiovascular Data
,” Quantitation in cardiology
, H. A.
Snellen
, H. C.
Hemker
, P. G.
Hugenholtz
, and J. H.
Van Bemmel
, Leiden University Press
, Amsterdam
, pp. 99
–113
.36.
Newman
, D.
, King
, D.
, Gosling
, R.
, and Wille
, S.
, 1972, “Reflections at Aortic-Iliac Junctions
,” Blood Flow Measurement
. V. C.
Roberts
, Sector Publishing Ltd.
, London
, pp. 44
–47
.37.
Murgo
, J.
, Westerhof
, N.
, Giolma
, J.
, and Altobelli
, S.
, 1980, “Aortic Input Impedance in Normal Man: Relationship to Pressure Wave Shapes
,” Circulation
0009-7322, 62
, pp. 105
–116
.38.
Nichols
, W.
, O’Rourke
, M.
, Avolio
, A.
, et al., 1987, “Age Related Changes in Left Vemtricular-Arterial Coupling
,” Vascular/Ventricular Coupling
, F. C. P.
Yan
, ed., Springer-Verlag
, New York
, pp. 79
–114
39.
Hamilton
, W.
, and Dow
, P.
, 1939, “An Experimental Study of the Standing Waves in the Pulse Propagated Through the Aorta
,” Am. J. Physiol.
0002-9513, 125
, pp. 48
–59
.40.
Alexander
, R.
, 1952, “The Genesis of the Aortic Standing Waves
,” Circ. Res.
0009-7330, 1
, pp. 145
–51
.41.
Remington
, J.
, 1963, “The Physiology of the Aorta and the Major Arteries
,” American Physiological Society Handbook of Physiology
, American Physiology Society
, Washington, DC
, pp. 799
–838
.42.
Remington
, J.
, 1965, “Quantitative Synthesis of Head and Foreleg Arterial Pulsed in the Dog
,” Am. J. Physiol.
0002-9513, 208
, pp. 968
–983
.43.
Dewood
, M.
, Spores
, J.
, Notske
, R.
, Mouser
, L.
, Burroughs
, R.
, Golden
, M.
, and Lang
, H.
, 1980, “Prevalence of Total Coronary Occlusion During the Early Hours of Transmural Myocardial Infraction
,” N. Engl. J. Med.
0028-4793, 303
(16
), pp. 897
–902
44.
Pearson
, A.
, Guo
, R.
, Orsinellid
, A.
, Binkley
, P.
, and Pasierski
, J.
, 1994, “Transesophageal Echocardiographic Assessment of the Effects of Age, Gender, and Hypertension on Thoracic Aortic Wall Size, Thickness, and Stiffness
,” Am. Heart J.
0002-8703, 128
, pp. 344
–351
.45.
Ho
, K.
, 1982, “Effects of Aging on Arterial Distensibility and Left Ventricular Load in An Australian Population
,” thesis, University of New South Wales.46.
Hirai
, T.
, Sasayama
, T.
, Kawasaki
, T.
, and Yagi
, S.
, 1989, “Stiffness of Systemic Arteries in Patients With Myocardial Infraction
,” Circulation
0009-7322, 80
, pp. 78
–86
.47.
Stefanadis
, C.
, Stratos
, C.
, Boudoulas
, H.
, Kourouklis
, C.
, and Toutouzas
, P.
, 1990, “Distensibility of the Ascending Aorta: Comparison of Invasive and Non-Invasive Techniques in Healthy Men and in Men With Coronary Heart Disease
,” Eur. Heart J.
0195-668X, 11
, pp. 990
–996
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