Blood Flow in Human Arterial System-A Review

Regulation of blood flow depends on changes in the sum of arterial (Ra) and venous (Rv) resistances, whereas regulation of capillary pressure (Pc) depends on the ratio of Rv to Ra. If the myogenic response of the arterial system (i.e., delta Ra) is the primary mechanism for controlling pressure and flow when perfusion pressure is lowered, then Pc and total flow should be regulated to the same degree under these conditions. This hypothesis was tested by making direct measurements of Pc and flow in skin and skeletal muscle in the wings of unanesthetized bats. The box method was used to reduce perfusion pressure to the wing. Pressures were measured with a servo-null system; flows were computed from measurements of vascular diameters and red cell velocities using intravital microscopy. All branching orders of arterioles dilated significantly during decreases in box pressure (Pb). For 0 less than Pb less than or equal to -30 mmHg, total flow (1st-order arteriolar flow) remained nearly constant, whereas Pc was "regulated" only approximately 60%. These results cannot be explained by changes in arteriolar resistance alone and suggest that changes in Rv may be important. The possible consequences of flow redistribution, capillary recruitment, and micropressure sampling procedures are discussed in relationship to local regulation of capillary pressure and flow.

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ASME Centennial Historical Perspective Paper: Mechanics of Blood Flow

Journal of Biomechanical Engineering ◽

10.1115/1.3138253 ◽

1981 ◽

Vol 103 (2) ◽

pp. 102-115 ◽

Cited By ~ 53

Author(s):

R. Skalak ◽

S. R. Keller ◽

T. W. Secomb

Keyword(s):

Blood Flow ◽

Wave Propagation ◽

Viscoelastic Behavior ◽

Leonardo Da Vinci ◽

Arterial System ◽

Elastic Membrane ◽

Biological Knowledge ◽

Collapsible Tubes ◽

Precise Understanding ◽

Leonhard Euler

The historical development of the mechanics of blood flow can be traced from ancient times, to Leonardo da Vinci and Leonhard Euler and up to the present times with increasing biological knowledge and mathematical analysis. In the last two decades, quantitative and numerical methods have steadily given more complete and precise understanding. In the arterial system wave propagation computations based on nonlinear one-dimensional modeling have given the best representation of pulse wave propagation. In the veins, the theory of unsteady flow in collapsible tubes has recently been extensively developed. In the last decade, progress has been made in describing the blood flow at junctions, through stenoses, in bends and in capillary blood vessels. The rheological behavior of individual red blood cells has been explored. A working model consists of an elastic membrane filled with viscous fluid. This model forms a basis for understanding the viscous and viscoelastic behavior of blood.

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Cinematic Angiography for Measurements of Blood Flow in Cerebral Aneurysms With Stents

Volume 2: Fora, Parts A and B ◽

10.1115/fedsm2007-37254 ◽

2007 ◽

Author(s):

Makoto Ohta ◽

Naoko Fujimura ◽

Luca Augsburger ◽

Hasan Yilmaz ◽

Daniel A. Ru¨fenacht

Keyword(s):

Blood Flow ◽

High Speed ◽

Cerebral Aneurysms ◽

Flow Speed ◽

Circulation System ◽

Parent Artery ◽

Vortex Center ◽

System A ◽

Before And After ◽

Movement Distance

Background and Purpose: The assessment of blood flow speed by imaging modalities is important for endovascular treatments, such as stent implantation, of cerebral aneurysms. The subtracted vortex centers path line method (SVC method) is one of the ways of determining flow speed quantitatively using the image sequence. And a cinematic angiography (CA) is a high speed image acquisition system using X-ray and contrast media integrated in Digital Subtraction Angiography (DSA) for endovascular therapy. The combination of SVC and CA may useful for determining the blood flow speed during the operation using DSA. In this study, we applied this combination to analyze hemodynamic changes before and after stenting. Methods: A transparent tubular model was constructed of silicone which included an aneurysm 10 mm in diameter and having a 5 mm neck on a straight parent artery with a diameter of 3.5 mm. The model was integrated into a pulsatile circulation system. A double layer stent was placed in the parent artery on the aneurysm. By CA, successive images at 25 frames per second with injection of contrast were obtained. Results and conclusion: Rotating vortexes of contrast, which advanced along the wall of the aneurysm, were observed in successive images of the aneurysm cavity. The movement distance of the vortex center was measured and the results show that the vortex speed decrease after stenting. This indicates the possibility of applying the SVC method to medical imaging equipment for analysis of the flow in aneurysms containing stent.

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The Rheology of Blood Flow in a Branched Arterial System

Applied Rheology ◽

10.1515/arh-2005-0020 ◽

2005 ◽

Vol 15 (6) ◽

pp. 398-405 ◽

Cited By ~ 92

Author(s):

Shewaferaw S. Shibeshi ◽

William E. Collins

Keyword(s):

Blood Flow ◽

Finite Volume Method ◽

Finite Volume ◽

Power Law ◽

Numerical Study ◽

Arterial System ◽

Magnitude Distribution ◽

Velocity Magnitude ◽

Percentage Difference ◽

Volume Method

AbstractBlood flow rheology is a complex phenomenon. Presently there is no universally agreed upon model to represent the viscous property of blood. However, under the general classification of non-Newtonian models that simulate blood behavior to different degrees of accuracy, there are many variants. The power law, Casson and Carreau models are popular non-Newtonian models and affect hemodynamics quantities under many conditions. In this study, the finite volume method is used to investigate hemodynamics predictions of each of the models. To implement the finite volume method, the computational fluid dynamics software Fluent 6.1 is used. In this numerical study the different hemorheological models are found to predict different results of hemodynamics variables which are known to impact the genesis of atherosclerosis and formation of thrombosis. The axial velocity magnitude percentage difference of up to 2 % and radial velocity difference up to 90 % is found at different sections of the T-junction geometry. The size of flow recirculation zones and their associated separation and reattachment point’s locations differ for each model. The wall shear stress also experiences up to 12 % shift in the main tube. A velocity magnitude distribution of the grid cells shows that the Newtonian model is close dynamically to the Casson model while the power law model resembles the Carreau model.

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Differential Effects of Isoflurane and Halothane on Aortic Input Impedance Quantified Using a Three-element Windkessel Model

Anesthesiology ◽

10.1097/00000542-199508000-00017 ◽

1995 ◽

Vol 83 (2) ◽

pp. 361-373. ◽

Cited By ~ 31

Author(s):

Douglas A. Hettrick ◽

Paul S. Pagel ◽

David C. Warltier

Keyword(s):

Blood Flow ◽

Input Impedance ◽

Wave Reflection ◽

Conscious State ◽

Left Ventricular ◽

Arterial System ◽

Windkessel Model ◽

Frequency Dependent ◽

Aortic Input Impedance ◽

Arterial Wave Reflection

Background Systemic vascular resistance (the ratio of mean aortic pressure [AP] and mean aortic blood flow [AQ]) does not completely describe left ventricular (LV) afterload because of the phasic nature of pressure and blood flow. Aortic input impedance (Zin) is an established experimental description of LV afterload that incorporates the frequency-dependent characteristics and viscoelastic properties of the arterial system. Zin is most often interpreted through an analytical model known as the three-element Windkessel. This investigation examined the effects of isoflurane, halothane, and sodium nitroprusside (SNP) on Zin. Changes in Zin were quantified using three variables derived from the Windkessel: characteristic aortic impedance (Zc), total arterial compliance (C), and total arterial resistance (R). Methods Sixteen experiments were conducted in eight dogs chronically instrumented for measurement of AP, LV pressure, maximum rate of change in left ventricular pressure, subendocardial segment length, and AQ. AP and AQ waveforms were recorded in the conscious state and after 30 min equilibration at 1.25, 1.5, and 1.75 minimum alveolar concentration (MAC) isoflurane and halothane. Zin spectra were obtained by power spectral analysis of AP and AQ waveforms and corrected for the phase responses of the transducers. Zc and R were calculated as the mean of Zin between 2 and 15 Hz and the difference between Zin at zero frequency and Zc, respectively. C was determined using the formula C = (Ad.MAP).[MAQ.(Pes-Ped)]-1, where Ad = diastolic AP area; MAP and MAQ = mean AP and mean AQ, respectively; and Pes and Ped = end-systolic and end-diastolic AP, respectively. Parameters describing the net site and magnitude of arterial wave reflection were also calculated from Zin. Eight additional dogs were studied in the conscious state before and after 15 min equilibration at three equihypotensive infusions of SNP. Results Isoflurane decreased R (3,205 +/- 315 during control to 2,340 +/- 2.19 dyn.s.cm-5 during 1.75 MAC) and increased C(0.55 +/- 0.02 during control to 0.73 +/- 0.06 ml.mmHg-1 during 1.75 MAC) in a dose-related manner. Isoflurane also increased Zc at the highest dose. Halothane increased C and Zc but did not change R. Equihypotensive doses of SNP decreased R and produced marked increases in C without changing Zc. No changes in the net site or the magnitude of arterial wave reflection were observed with isoflurane and halothane, in contrast to the findings with SNP. Conclusions The major difference between the effects of isoflurane and halothane on LV afterload derived from the Windkessel model of Zin was related to R, a property of arteriolar resistance vessels, and not to Zc or C, the mechanical characteristics of the aorta. No changes in arterial wave reflection patterns determined from Zin spectra occurred with isoflurane and halothane. These results indicate that isoflurane and halothane have no effect on frequency-dependent arterial properties.

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Estimation of Forearm Arterial Compliance in Essential Hypertension: A Preliminary Report

Clinical Science ◽

10.1042/cs063087s ◽

1982 ◽

Vol 63 (s8) ◽

pp. 87s-88s ◽

Cited By ~ 3

Author(s):

A. CH. Simon ◽

J. A. Levenson ◽

S. P. Laurent ◽

M. E. Safar

Keyword(s):

Blood Flow ◽

Essential Hypertension ◽

Brachial Artery ◽

Diastolic Pressure ◽

Arterial Compliance ◽

Normal Subjects ◽

Arterial System ◽

Flow Measurements ◽

Blood Pressures ◽

Blood Flow Measurements

1. Simultaneous brachial artery pressure and blood flow measurements were made in 21 men, including six normal subjects and 15 patients with essential hypertension of the same age and diastolic pressure at the time of investigation. 2. Blood flow was evaluated by means of a pulsed Doppler device with a double transducer probe, enabling a precise evaluation of the calibre of the brachial artery. From analysis of the pressure-flow curves during diastole, forearm arterial compliance was estimated by using an original first-order model of the forearm arterial system. 3. Forearm arterial compliance was significantly decreased in hypertensive subjects. 4. Since patients and hypertensive subjects had similar blood pressures, the results indicate that the reduced forearm compliance was independent of blood pressure per se but may reflect in hypertensive subjects adaptive changes in the walls of peripheral large arteries.

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Propagation of Blood Flow Pulse in the Normal Human Pulmonary Arterial System: ANALYSIS OF THE PULSATILE CAPILLARY FLOW

Circulation Research ◽

10.1161/01.res.25.1.11 ◽

1969 ◽

Vol 25 (1) ◽

pp. 11-21 ◽

Cited By ~ 28

Author(s):

NICHOLAS B. KARATZAS ◽

GRANT DE J. LEE

Keyword(s):

Blood Flow ◽

System Analysis ◽

Capillary Flow ◽

Arterial System ◽

Flow Pulse ◽

Normal Human ◽

Pulmonary Arterial

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Design and 3D-model of a dynamic bubble trap for cardiopulmonary bypass

Russian Journal of Transplantology and Artificial Organs ◽

10.15825/1995-1191-2021-4-79-85 ◽

2021 ◽

Vol 23 (4) ◽

pp. 79-85

Author(s):

A. P. Kuleshov ◽

A. S. Buchnev ◽

A. A. Drobyshev ◽

G. P. Itkin

Keyword(s):

Blood Flow ◽

Cardiopulmonary Bypass ◽

3D Model ◽

Pediatric Patients ◽

Air Embolism ◽

Arterial System ◽

Postoperative Rehabilitation ◽

Bubble Separation ◽

Bubble Trap ◽

Small Bubbles

The use of extracorporeal circulation systems (cardiopulmonary bypass pumps, ECMO) can lead to brain and coronary artery microembolism, which significantly reduces postoperative rehabilitation and often leads to severe complications. Microembolism occurs when oxygen or air microbubbles (MBs) enter the arterial system of patients. Existing CPB pumps come with built-in bubble trap systems but cannot remove bubbles in the circuit. ECMO devices have arterial filters but cannot reliably filter out <40 μm bubbles in a wide flow range. We have proposed an alternative method that involves the use of an efficient dynamic bubble trap (DBT) for both large and small bubbles. The design includes development of two DBT variants for hemodynamic conditions of adult and pediatric patients. The device is installed in the CPB pump and ECMO outlet lines. It provides sufficient bubble separation from the lines in a blood flow of 3.0–5.0 L/min for adults and 0.5–2.0 L/min for children. The developed computer models have shown that MBs smaller than 10 μm can be filtered. The use of this device will greatly reduce the likelihood of air embolism and provide the opportunity to reconsider the concept of expensive arterial filters.

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Modeling blood flow in the arterial system

Periodica Polytechnica Mechanical Engineering ◽

10.3311/pp.me.2011-1.07 ◽

2011 ◽

Vol 55 (1) ◽

pp. 49 ◽

Cited By ~ 6

Author(s):

Gergely Bárdossy ◽

Gábor Halász

Keyword(s):

Blood Flow ◽

Arterial System

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