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  • 标题:Predictions of the extent of Renal Artery Stenosis in the context of rise in blood pressure.
  • 作者:Shukla, V. V. ; Padole, P. M. ; Sonolikar, R. L.
  • 期刊名称:International Journal of Applied Engineering Research
  • 印刷版ISSN:0973-4562
  • 出版年度:2009
  • 期号:October
  • 语种:English
  • 出版社:Research India Publications
  • 摘要:Combination of a dormant lifestyle, a rich diet, lack of exercise and smoking leads to an increase in blocked blood vessels, hypertension and strokes [4-6]. A material called plaque builds up on the inner wall of arteries cause stenosis. The plaque makes the artery wall narrow and hard [3]. The renal arteries branch off directly from the abdominal aorta and supply blood to the kidneys for filtration, wherein homeostasis is maintained [1-2]. Narrowing, hardening and blocking of renal artery due to plaque deposition is Renal Artery Stenosis (RAS). One of the primary stages of RAS is Fibro muscular dysplasia (FMD). FMD causes growth of fibrous tissues on the arterial wall. The most common clinical manifestation of fibro muscular dysplasia (FMD) is hypertension. [9-10]. RAS diminishes the blood supply to the kidneys, which can cause them to atrophy and may ultimately lead to kidney failure. The kidney with RAS suffers from the decreased blood flow and often shrinks in size (ischemic nephropathy). The other kidney is at risk for developing damage from the hypertension. This often develops hypertensive nephrosclerosis [7-8]. The persistent elevated blood pressures in the normal kidney can cause progressive scarring (sclerosis) leading to progressive loss of filtering function in this kidney as well. Both unilateral RAS and bilateral RAS can ultimately lead to chronic renal failure. With total kidney failure, one needs dialysis or a kidney transplant to stay alive [9].
  • 关键词:Blood flow;Blood pressure;Finite element method;Hypertension;Prediction theory;Renal artery obstruction;Stenosis

Predictions of the extent of Renal Artery Stenosis in the context of rise in blood pressure.


Shukla, V. V. ; Padole, P. M. ; Sonolikar, R. L. 等


Introduction

Combination of a dormant lifestyle, a rich diet, lack of exercise and smoking leads to an increase in blocked blood vessels, hypertension and strokes [4-6]. A material called plaque builds up on the inner wall of arteries cause stenosis. The plaque makes the artery wall narrow and hard [3]. The renal arteries branch off directly from the abdominal aorta and supply blood to the kidneys for filtration, wherein homeostasis is maintained [1-2]. Narrowing, hardening and blocking of renal artery due to plaque deposition is Renal Artery Stenosis (RAS). One of the primary stages of RAS is Fibro muscular dysplasia (FMD). FMD causes growth of fibrous tissues on the arterial wall. The most common clinical manifestation of fibro muscular dysplasia (FMD) is hypertension. [9-10]. RAS diminishes the blood supply to the kidneys, which can cause them to atrophy and may ultimately lead to kidney failure. The kidney with RAS suffers from the decreased blood flow and often shrinks in size (ischemic nephropathy). The other kidney is at risk for developing damage from the hypertension. This often develops hypertensive nephrosclerosis [7-8]. The persistent elevated blood pressures in the normal kidney can cause progressive scarring (sclerosis) leading to progressive loss of filtering function in this kidney as well. Both unilateral RAS and bilateral RAS can ultimately lead to chronic renal failure. With total kidney failure, one needs dialysis or a kidney transplant to stay alive [9].

Atherosclerotic RAS may present with hypertension, renal failure (ischemic nephropathy), recurrent episodes of congestive heart failure and flash pulmonary edema or may be discovered incidentally during an imaging procedure for some other reason [11-13]. The high blood pressure that is sometimes associated with RAS may be the first sign that it is present, particularly if the hypertension is not responding to standard treatment. Presence of a a swooshing sound from the artery indicates an obstruction, may be heard through a stethoscope. It is vital to develop effective treatments that prolong the life of a patient. Prompt diagnosis and timely intervention done by a skilled vascular surgeon can significantly decrease target organ damage and potentially cure high blood pressure due to renal artery disease. Management of RAS consists of three possible strategies: medical management, surgical management or percutaneous therapy with balloon angioplasty and stent implantation. If RAS is detected, the vascular surgeon will determine which of the method of repair, Angioplasty, stent placement or arterial Bypass would be the most appropriate and beneficial for each patient's unique situation [14]. Renal artery stenting has replaced surgical revascularization for most patients with atherosclerotic disease who meet the criteria for intervention [20]. Patients with generalized atherosclerosis and renal artery stenosis (RAS) more often die from cardiovascular causes than renal failure. While physicians speak to patients about expanding narrowed renal arteries and controlling blood pressure (BP), patients desire to live longer, have fewer strokes [9].

In general, blood pressure in the circulatory system specifically in aorta is affected by RAS; hence the relationship between rise in blood pressure and the extent of RAS should be investigated thoroughly. Although it is difficult to verify conclusively such relationships without suitable in vivo studies, CFD can provide an excellent research tool to help understand these underlying issues [15]. CFD is being employed by several researchers to explore further the nature of flow stagnation patterns [16-19]. Extensive work has been devoted to the cardiovascular fluid dynamics during the last 25 years. For a general mathematical modeling of arterial flow we refer [22-23]. Several numerical studies dedicated to smaller (dia. Less than 2 mm) coronary, carotid arteries and larger like AAA (Abdominal aortic Aneurysms, dia. More than 22 mm) with their bifurcations, compliance mismatch, with and without stent-grafts have been found in literature [21, 26-28], however to the best of our knowledge, studies related to the influence of Renal Artery Stenosis (RAS) on the rise of blood pressure have not yet been reported. Arterial stenoses in the range 0-78% reduction of the cross sectional areas have been previously investigated to estimate plaque progression and wall stresses, both numerically and experimentally [24]. In this paper, authors have investigated, established and quantified the relation between RAS and hypertension using Finite element method (FEM).

Materials and methods

Hemodynamic factors such as velocity gradients, shear stresses etc. are believed to affect a number of cardiovascular diseases including stenosis and aneurysms. Since resolving phenomenon in living body is beyond the capabilities of in vivo measurement techniques, computer modeling is expected to play an important role in gaining better understanding of the relationship between cardiovascular disease and hemodynamic factors [25]. When physical test methods are difficult (or even impossible), computational models may sometimes be the only alternative [24].

In Biomechanics, Finite Element Analysis (FEA) and computational Fluid Dynamics (CFD) are increasingly used to perform strength analysis, system response studies and design optimization of implants without the need for time- and cost- intensive prototyping. The rapidly improving computer performance enables a low-cost simulation of complex components or composite structures. Different medical and technical demands on the modeling or material laws can be examined by FEA.

Finite element method (FEM) based and not finite volume method (FVM) based CFD is used to investigate the effect of renal artery stenosis on the rise of blood pressure. This is because of inherited advantages of FEM like it caters to the needs of geometric flexibility; allow applying physical boundary conditions easily and accurately. It satisfies global physical (linear) conservation laws automatically especially quadratic quantities and even for which divergence theorems are not applicable. Laplacian, divergence and gradient operators are adjoint to each other in continuum in FEM and not in FVM. Phase speed of FEM is always more accurate than that of FVM. Elliptic problem solutions are more accurate in FEM than FVM.

Computational Model

a) Model geometry--Renal artery connecting aorta is almost straight and symmetric. Therefore 2-D geometries of healthy and stenosed renal arteries were created, as shown in Fig.1, with the FEM general purpose computational fluid dynamics code ANSYS v 11.0 (ANSYS [R] Inc., USA). The actual length of renal artery is less than 1 m; however blood pressure variations are quantified on the basis of pressure drop per meter length of the artery. Hence renal artery model constructed was 1 m long and 6 mm in diameter. The various symmetrical stenoses model were subsequently created at the center i.e. at 0.5 m from the inlet, by creating arcs with three key points as shown in Fig.2. The length of all the arcs along the inside arterial wall was 10 mm as shown in Fig.2 (inset). The minimum diameter at the site of stenoses and percentage of stenoses based on diameters and areas calculated as shown in Table 1. In general, Stenoses are specified relative to blocked areas, therefore henceforth in this study, stenosis based on areas are followed.

[FIGURE 1 OMITTED]

[FIGURE 2 OMITTED]

b) Material properties--Although blood is known to be non-Newtonian in general we assume it to be Newtonian in this study. This is because the renal artery considered in this study has maximum diameter of 6.0 mm. The velocity and shear rates in the larger arteries are high. The apparent viscosity of blood in renal artery with relatively large diameter is nearly constant and therefore non-Newtonian effects are neglected [25]. Blood is modeled as an incompressible, homogeneous, Newtonian viscous fluid, with a specific mass of 1050 kg/[m.sup.3] and a constant dynamic viscosity of 3.5 X [10.sup.-3] Pa s [25]. The flow is assumed to be steady state, Laminar and adiabatic [30].

c) Meshing-The mesh was built with 2--D Fluid 141 elements, each having four nodes and 4 degrees of freedom (two translational velocities and two pressures). The number of iterations are determined by using different meshes, from coarse to progressively fine, until the inlet pressure distribution is mesh convergent to within a prescribed tolerance (~0.5%) [30]. The total numbers of nodes are about 23725 and elements about 21888 for the normal configuration i.e. with 0% stenosis, which slightly differs for the stenosed configurations due to local mesh adaptations. While meshing the artery walls are set for desired number of mesh divisions. The specific ratio of -2 for entry length and inlet and outlets produces denser mesh at distal ends and near the walls respectively. Uniform finer mesh using spacing ratio of 1 is applied for stenosis section. The exit length mesh is obtained using spacing ratio of 3 indicates coarser mesh towards outlet.

d) Boundary conditions and loads--A normal renal artery has a blood flow of about 1 L/min (about 20%) of the total cardiac output from heart [9]. The pressure profile along the intra-renal vasculature starts with a mean arterial pressure of 100 mm Hg, and significantly drops between the renal artery and the capillaries [1, 29].

Therefore to impose boundary conditions, the axial inlet velocity of 0.57 m/s was assigned in X-direction and zero transverse velocity components at the entrance of the vessel. No slip boundary conditions were imposed on the impermeable, rigid vessel walls. At the outlet zero atmospheric pressure was imposed [30]. The numerical simulations were carried out for different values of Reynolds number (Re) ranging from 1125 to 1421.The external forces, such as those due to gravity or human motion are assumed to be not significant and are neglected [25].

e) Methodology--To enable efficient and accurate numerical solution to the modeled boundary value problem two key factors must be addressed: the modeling phase and the solution phase. Each have these phases have uncertainties linked with them and thus sensible selection of suitable techniques, mathematical and numerical, must be taken to guarantee the final approximate solution accurately represents the initial physical system. The rise in the blood pressure depends not only on the viscosity and density of the blood but also on the extent of the stenosis. Therefore simulation of flow of water ([rho] = 1000 Kg/[m.sup.3] and [mu] = 0.798 X [10.sup.-3] Pa-s) through various stenoses have also been carried out.

f) Validation experiments--

Simple experimental setup has been designed to investigate the effect of stenoses on the rise of pressure. The experimental setup as shown in Fig. 3 consists of a positive displacement gear pump with torque of 0.04 Nm. The outlet of the pump was connected to a polyethylene tube resembling artery of diameter 6 mm and length 1 m connected by means of a Tee. One end of the Tee is attached to the polyethylene tube while the other is connected to a vertical tube of diameter 12 mm and length 2 meters. This vertical tube acts as both a piezometer and a surge tank in the experiment. Nine numbers of converging-diverging Nylon66 specimens of length 10 mm were manufactured; these represent variable stenosis (30.55% to 99.82%). The specimens were fitted in the polyethylene tube one at a time. During the experiment care is taken to maintain the flow rate through the polyethylene tube to be fixed and is 1.64 x [10.sup.-3] [m.sup.3]/s.

[FIGURE 3 OMITTED]

The excessive power consumed by the pump and excessive head acting on the pump is estimated by Eq. (1) and Eq. (2)

Power = 2[pi]NT/60 - - - - - - - - - - - (1)

Hf = Power/[rho]gQ + Piezometer correction - (2)

Where P--Power (Watt), N--speed of the pump (rpm), [rho]--Density of liquid (Kg/[m.sup.3]), Q--Flow rate ([m.sup.3]/s), Hf--Excessive Head (m), T--Torque (Nm)

Governing equations of motion

The blood flow in the renal arteries is assumed to be laminar [25,38]. Flow motion was described by Navier-Stokes equations (principle of momentum conservation and continuity equations) of incompressible flow. For a steady-state analysis, the flow motion governing equations, in the Cartesian coordinates.

[rho]([partial derivative]u/[partial derivative]t + u x [gradient] u) - [gradient] x [sigma] = 0 - - - - - - - - - - (3a)

[gradient] x u = 0 - - - - - - - - - - - - - - - - - - - (3b)

Equation for fully developed laminar flow through a straight tube (Hagen- Poiseullie flow) is given in Eq. (3c)

Q = [pi][D.sup.4]/128 [micro] ([partial derivative]p/[partial derivative]z - - - - - - - - - - - - - - - - (3c)

Results and discussion

The effect of stenosis on the pressure distribution, velocity profile, wall shear stress, stream function, Reynolds number and pressure coefficients are studied. However the main focus was to study the rise of pressure at inlet of the flow for water as well as the blood. The flow of water was simulated using ANSYS [R] Inc. FLOTRAN CFD and validated against the experimental observations. The flow of blood was simulated and could not be verified by the experimentation. But we comprehend that the results can be justified on the basis of experimental validation of water flow and also against the published data. In addition, a few medical cases have been examined successfully with appreciable conformance.

Simulation Results

a) Flow of water

The flow of water through tube without blockage is turbulent (Re = 4648). The velocity profile as shown in Fig 4(a) indicates highest velocity of 0.6182 m/s at the center of tube and fairly follows power law near the wall. The highest velocity of 4.665 m/s (Re = 4676) is observed in 99% stenosis at 0.16 mm from the wall. It is shown in Fig. 4(b); it fairly remains the same within the core of the tube except at central region of the stenosis where velocity drops little to 4.147 m/s. The CFD models of the tube with increasing size of blockages were then solved using similar manner. The trends for increasing velocity, increasing pressure drops, increasing fluid shear stress near wall and constant pressure coefficients were observed, they are listed in Table 2. Fluctuations of Reynolds number have been observed, this may be because water flow is turbulent in nature and very close to transition zone. The velocity profile of tube with maximum blockage (99%) is shown in Fig. 5(a). The pressure loss distribution is shown in Fig. 5(b). It shows there is a loss of about 508.743 N/[m.sup.2] (3.9 mm of Hg) between the entry and exit of the tube for zero stenosis. This means that if there is gauge pressure of 13243.5 N/[m.sup.2] (100 mm of Hg) at inlet, the gauge pressure at the outlet would be 12734.757 N/[m.sup.2] (96.1 mm of Hg). The pressure loss distribution is shown in Fig. 5(c). It shows there is a loss of about 4353 N/[m.sup.2] (32.8 mm of Hg) between the entry and exit of the 99% blocked tube. Maximum fluid shear stress (very small value of 1.439 Pa) is found near the wall at the inlet of the flow. Maximum fluid shear stress (103.554 Pa) is found at the center of stenosis wall as shown in Fig. 5(d).

[FIGURE 4 OMITTED]

[FIGURE 5 OMITTED]

a) Flow of blood The flow of blood through renal artery without blockage is Laminar (Re = 1421.1). The velocity profile as shown in Fig 6(a) indicates highest velocity of 0.789 m/s at the center of artery and is parabolic. The velocity profile of tube with maximum blockage (99%) is shown in Fig. 6(b). The highest velocity of 4.688 m/s (Re = 1125.12) is observed at 0.16 mm from the wall. And as shown in Fig. 7(a), it fairly remains the same within the core of the renal artery. There exist recirculations both up and down stream of the stenosis as shown in Fig. 7(a). The stenosis forms a jet and the impasse of the jet results in recirculation upstream and the jet flow induces recirculation downstream. One of the important things noticed in the study is little reduction in velocities downstream and far away from the stenosis region. The CFD model of the renal artery with increasing size of stenoses are then solved using similar manner. The trends for increasing velocity, increasing pressure drops, increasing fluid shear stress near wall and constant pressure coefficients are observed, they are listed in Table.3. The pressure loss distribution is shown in Fig. 7(b). It shows there is a loss of about 684.377 N/[m.sup.2] (6.97 mm of Hg) between the entry and exit of the artery. This means that if there is gauge pressure of 13243.5 N/[m.sup.2] (100 mm of Hg) at inlet, the gauge pressure at the outlet would be 12599.123 N/[m.sup.2] (94.8 mm of Hg). Maximum fluid shear stress (4.19 Pa) is found near the wall at the inlet of the flow.

[FIGURE 6 OMITTED]

[FIGURE 7 OMITTED]

Reynolds number in blood flow simulation is observed to be gradually reducing from 1421 to 1125 for 0% to 99% stenoses. This could be because the average velocity does not increase by the rate at which diameter of the flow reduces and also there may be slight increase in effective viscosity. This suggests that reducing velocity minimizes the blood flow to kidney because of the presence of stenosis. The pressure loss distribution is shown in Fig. 7(c). It shows there is a loss of about 5829 N/[m.sup.2] (44 mm of Hg) between the entry and exit of the 99% stenosed artery. Maximum fluid shear stress (183.856 Pa) is found at the center of stenosis wall as shown in Fig. 7(d).

The percent pressure rise as shown in table 2 and 3 are computed by Equation (4).

% pressure rise at inlet = [(13243.5 + Pr essuredifference) - 13243.5]/13243.5 X 100 (4)

And relative % pressure rise at inlet as shown in table 2 and 3 are computed by the Equation (4)

Relative % pressure rise at inlet = {(% pressure rise at inlet} - {(% pressure rise at inlet for 0% stenosis} (5)

And relative % pressure rise at inlet as shown in table 2 and 3 are computed by the Equation (2) Equation (4) helps in computing relative percent increase over the initial pressure of 100 mm of Hg at inlet. Whereas Equation (2) helps in setting the initial relative percentage of pressure rise to zero in order to standardize the reference relative percentage of pressure. Thus the results of pressure difference from each CFD analysis is substituted in Eq. (4) and then in Eq. (5) in order to compute Relative percentage of pressure rise for rest of the cases. Referring Table 2 and Table 3, Pressure drop increases and therefore pressure at inlet rises in both the cases. Rise of pressure in blood flow is found higher as compared to water flow. This is because of viscosity of water is approximately 4.3 times to that of blood.

Also this is quite expected as water flow is turbulent where as blood flow is laminar and similar to Poiseullie flow. Velocities in both cases increases gradually with increasing extent of the blockage in both the cases and are almost equal, this is because the flow rate and cross sectional areas are identical. Variations of velocity and 2-D stream function are shown in Fig. 8.

[FIGURE 8 OMITTED]

A very interesting flow structure is that the secondary blood flow from aorta while entering renal artery (0% stenosis) forms vortices near the inlet wall of renal artery. Also the wall shear stresses at Re = 1421 at the entry point are considerably high. This is supposed to be the favorable location for plaque deposition and arterial remodeling and would eventually lead to stenosis location. The trends of rise of pressure are found similar but different regression coefficients for blood flow and water flow; based on CFD results have been determined.

The comparison of the CFD results for relative percentage of pressure rise is shown in Fig. 9. It is observe that for the same extent of stenosis, the blood pressure rise at inlet of the renal artery is more than that of water pressure rise in the tube. Also up to 82% there is about 5.5% rise in blood pressure but then onwards blood pressure shoots up rapidly.

[FIGURE 9 OMITTED]

Limitations

The present CFD study of blood flow through renal artery considers steady-state boundary condition, while blood flow in arteries with larger diameters is highly pulsatile. Steady flow results are not physiologically relevant (16-19); however they demonstrate clinically acceptable patterns. In future, the condition of pulsatile blood flow through renal artery based on patient specific data needs to addressed using transient analysis [30, 33, and 36]. Also the displacement variation of the left and right kidney during normal respiration [29, 34, and 35] is to be accounted in computing arterial wall parameters.

Experimental Results

It is found that, to maintain the flow rate constant, the pump draws increasingly higher power i.e. speed increases. Therefore it was necessary to track pump speed for each of the specimen fitted. When the pump was switched on, water flows through the polyethylene tube. The readings of rise of water in piezometer tube and pump speed were noted for full open and thereafter for each fit of the nylon specimen. The pump speed for each of stenoses and rest of the determined parameters are shown in Table 4. Equation (3) is used to compute the power consumed by the pump and Equation (4) is used to compute pressure (Head) Loss for each run. The piezometer correction is a small difference in the rise of water level due to maintained constant flow rate and the blockage fitting in piezometer tube, measured in unit time interval.

The experimental results are in good agreement with CFD results of water. The comparison for experimental pressure difference of water at the inlet and outlet of the polyethylene tube and the CFD pressure difference is shown in Fig. 10.

[FIGURE 10 OMITTED]

Closing Remarks--Based on the CFD analyses, data obtained for % RAS and blood pressure rise. A mathematical model is researched to fit this data. Sigmoidal family of curves producing growth curves is common in a wide variety of applications such as biology and engineering.. These curves start at a fixed point and increase their growth rate monotonically to reach an inflection point. After this, the growth rate approaches a final value asymptotically. Selected Logistic Model has the equation (6) Covariance matrix is computed and listed in Table 4

y = a/(1 + b * [e.sup.-cx]) - (6)

With a Standard error of 3.42 and a correlation coefficient of 0.97, the values of the constants to be used in Eq. (6) are computed as shown in Table 6. Model verification is shown in Fig. 11.

[FIGURE 11 OMITTED]

Conclusion

The objective of this study was to establish the effect of RAS upon the rise in blood pressure acting through aorta and thus on the aortic valve of heart. The percent increase in stenosis increases pumping load on heart, this ultimately reduces the volume of blood from heart to the tissues beyond the stenosis. The reduced volume flow to kidney results in ischemic nephropathy. For a single flow conduit this can be justified by the basic laws of science, however human body is comprised of several arteries and veins and thus complex blood flow networks exists. In such multifarious case it would be precarious to state that pumping load on heart alone will rise or in general blood pressure will increase. Rather the test case dealt here assumes 100% stenosis elsewhere in the circulatory system, which cannot be true. On the contrary, when there is rise in blood pressure the Entire healthy circulatory system soothe out this effect by distributing the blood pressure rise proportionately, however, total nullification of the blood pressure rise effect is also impossible. And therefore, it is possible that this analysis may not be accurate, however it gives an overall idea and the trends towards the future risk to the patients, diagnosis and treatments to general medical practitioners. Although this basic work is one of its kinds, the numerical technique is validated reasonably, against the clinical data and published results. The present study provides easy to use information and one of the clinical steps to general medical practitioners to diagnose Renal Artery Stenosis (RAS). The information could be used in the tabular or graphical form to conjecture the likelihood of RAS based on measured blood pressure of the patient.

Following conclusions can be drawn from the computed results

(a) As stenosis increases there is rise in blood pressure. The rise in blood pressure is steeper towards the far end of the graph, indicating rate of increase in blood pressure/gradients are higher for stenoses above 88% and precipitously rises thereafter.

(b) For and above 88% stenosis, velocity vectors are sharp and if oriented towards artery can lead to erosion kind of forces, which would facilitate in remodeling artery leading to further stenosis at that site.

(c) Reynolds number throughout the renal artery ranges from 1125 to 1421 clearly indicates laminar flow.

(d) Blood Pressure rise due to severe renal artery stenosis (99.82%) are observe to be maximum (about 38%). Stagnation pressure remains little higher than the static pressure in the stenosed renal artery.

(e) The simulation has revealed that under steady flow conditions, the size of flow recirculation zone increases with flow Reynolds' number.

(f) Higher shear stress at the entry of the normal renal artery indicates favorable location to form stenosis.

Acknowledgements

The authors wish to thank Dr. S. S. Gokhale (Director, V.N.I.T), Nagpur, Dr. Shirish Deshpande (Radiologist, CIIMS Hospital), Dr. H. M. Mardikar (Spandan Hospital) Nagpur, for guidance, verification and validation of the research work.

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V. V. Shukla (a), *, P. M. Padole (a), R. L. Sonolikar (a), Shirish Deshpande (b) and H. M. Mardikar (c)

(a) Dept. of Mech. Engg., Visvesvaraya National Institute of Tech., Nagpur, M.S., India.

(b) Dept. of Radiology, Central Indian Institute of Medical Science, Nagpur, M.S., India.

(c) Spandan Heart Institute & Research Center, Nagpur, M.S., India.
Table 1: Percentage of stenosis for stenosed arterial diameters and
areas.

Inside       Inside cross      Stenosis based    Stenosis based
diameter   Area ([m.sup.2])     on the inside     on the cross
(m)                               diameter       sectional area

0.006         0.00002826             0%                0%
0.005         0.000019625          16.66%            30.55%
0.0043        1.45147E-05          28.33%            48.64%
0.0035        9.61625E-06          41.66%            65.97%
0.0031        7.54385E-06          48.33%             73.3%
0.0025        4.90625E-06          58.33%            82.63%
0.002         0.00000314           66.66%            88.88%
0.0015        1.76625E-06            75%             93.75%
0.001         0.000000785          83.33%            99.72%
0.0008         5.024E-07           86.66%            99.82%

Table 2: CFD results of investigated parameters for water flow.

%        Pressure        Max.         Shear        pressure
Sten    difference     Velocity      Stress       coefficient
osis   (N/[m.sup.2])    (m/s)     (N/[m.sup.2])

00        508.743       0.618         1.439         0.01077
30        549.150       0.777         2.391         0.01906
48        559.928       0.881         3.469         0.01906
65        583.204       1.075         5.547         0.01874
75        605.108       1.213         7.177         0.01877
82        668.572       1.525         11.21         0.01903
99         2820         3.756         67.88         0.01904

%        2-D         %       Relative   Reynolds
Sten    stream    pressure      %        Number
osis   function   rise at    pressure
                   inlet       rise

00      2.836      3.841      0.000       4648
30      3.307      4.146      0.305       4873
48      3.343      4.227      0.386       4747
65      3.306      4.403      0.562       4714
75      3.337      4.569      0.727       4712
82      3.397      5.048      1.206       4777
99      3.445      21.293     17.452      4706

Table 3: CFD results of investigated parameters for blood flow.

%        Pressure        Max.         Shear        pressure
Sten    difference     Velocity      Stress       coefficient
osis   (N/[m.sup.2])    (m/s)     (N/[m.sup.2])

00       684.377        0.7895        4.190         0.0550
30       767.821        0.8925        8.978         0.0779
48       776.281        0.9782        8.978         0.0779
65       803.69         1.142         8.978         0.0781
75       854.692        1.266        12.201         0.0781
82         1030         1.538        19.37          0.0781
99         3910         3.759        117.10         0.0781

%        2-D         %       Relative   Reynolds
Sten    stream    pressure      %        Number
osis   function   rise at    pressure
                   inlet       rise

00      3.290      5.1676     0.000      1421
30      3.472      5.797      0.630      1338
48      3.500      5.861      0.693      1261
65      3.470      6.068      0.900      1199
75      3.579      6.453      1.286      1177
82      3.816      7.777      2.609      1153
99      3.614      29.523     24.356     1127

Table 4: Experimental results for the pump speed during induced
stenoses (0 to 99%).

%           Pump    Piezo meter    Power    Head loss  Pressure differ
Stenosis   speed    correction    P(watt)    Hf (m)    (N/[m.sup.2])
           N (rpm)      (m)

0           198        0.001      0.8289     0.052          513
30          217        0.0015     0.90850    0.058          566
48          224        0.002      0.9378     0.060          589
65          231        0.0025     0.9671     0.062          611
73          241        0.003      1.0089     0.065          642
82          269        0.005      1.1262     0.075          732
88          299        0.007      1.2518     0.084          828
93          571        0.009      2.3905     0.157          1539
99          1742       0.015      7.2931     0.466          4575

Table 5: Covariance matrix for the Logistic Model.

F parameter a   21.7343   829.771     -0.140
parameter b     829.771   32035.258   -5.410
parameter c     -0.14     -5.410       0.0091

Table 6: Best fit Constants of Logistic model Eq. (6).

a       -4.06294
b       -56.1312
c        0.0392398
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