Relationship between blood flow direction and endothelial cell orientation at arterial branch sites in rabbits and mice.

A quantitative study of the en face size and shape of endothelial cells from aortic intercostal ostia has been carried out in rabbits. Photomicrographs were taken from vascular casts of the rabbit aorta and the endothelial cell outlines were analyzed quantitatively using a digitizer and digital computer. The morphology of the endothelial cells was described using 8 calculated parameters (area, perimeter, length, width, angle of orientation, width: length ratio, axis-intersection ratio and shape index). Marked changes in cell morphology were found in the regions proximal and distal to ostia as well as around flow dividers. Cells on the aorta are aligned with the flow direction, and the endothelial cells within the ostia have an angle of orientation of approximately 45 deg to the axis of the vessel. The results obtained to date suggest that endothelial cell morphology and orientation around a branch vessel may be a natural marker or indicator of the detailed features of blood flow.

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Endothelial cell morphometry near branch junctions of rabbit aortae

Canadian Journal of Physiology and Pharmacology ◽

10.1139/y87-289 ◽

1987 ◽

Vol 65 (9) ◽

pp. 1864-1871 ◽

Cited By ~ 7

Author(s):

Ralph G. Kratky ◽

Margot R. Roach

Keyword(s):

Shear Stress ◽

Endothelial Cell ◽

Flow Direction ◽

Cell Orientation ◽

Second Moments ◽

Straight Line ◽

Flow Divider ◽

New Zealand White Rabbits ◽

Tensile Forces ◽

Orientation Index

Endothelial cell morphometric data were gathered from corrosion casts of the aorta and its branches of six New Zealand white rabbits weighing 2–3 kg. The endothelial cell outlines were ditigized to provide cell orientation index (COI) from the equation COI = 2Mg/2Ml−1, where 2Ms and 2Ml are the second moments of area about short and lone axes of the cell. The COI varies from zero to infinity. The former occurs when cells are symmetrical (e.g., circular) since 2Ms = 2Ml and the latter occurs for a straight line. Large values of COI were found distal to intercostals, lumbars, and the aortorenal junction, and probably reflect relatively stable high shear regions. Values close to zero occur on the flow divider where the shear stress approaches zero. Other values were less predictable and we concluded that while the long axis of the cell appears to indicate flow direction, the shape of the cell does not appear to be a reliable indicator of either tensile forces or shear stress acting in it, but probably reflects a combination of the two.

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Advanced Constitutive Modeling of the Thixotropic Elasto-Visco-Plastic Behavior of Blood: Steady-State Blood Flow in Microtubes

Materials ◽

10.3390/ma14020367 ◽

2021 ◽

Vol 14 (2) ◽

pp. 367

Author(s):

Konstantinos Giannokostas ◽

Yannis Dimakopoulos ◽

Andreas Anayiotos ◽

John Tsamopoulos

Keyword(s):

Blood Flow ◽

Steady State ◽

Constitutive Model ◽

Blood Plasma ◽

Constitutive Modeling ◽

Flow Direction ◽

Momentum Balance ◽

Plastic Behavior ◽

Flow Investigation ◽

The Impact

The present work focuses on the in-silico investigation of the steady-state blood flow in straight microtubes, incorporating advanced constitutive modeling for human blood and blood plasma. The blood constitutive model accounts for the interplay between thixotropy and elasto-visco-plasticity via a scalar variable that describes the level of the local blood structure at any instance. The constitutive model is enhanced by the non-Newtonian modeling of the plasma phase, which features bulk viscoelasticity. Incorporating microcirculation phenomena such as the cell-free layer (CFL) formation or the Fåhraeus and the Fåhraeus-Lindqvist effects is an indispensable part of the blood flow investigation. The coupling between them and the momentum balance is achieved through correlations based on experimental observations. Notably, we propose a new simplified form for the dependence of the apparent viscosity on the hematocrit that predicts the CFL thickness correctly. Our investigation focuses on the impact of the microtube diameter and the pressure-gradient on velocity profiles, normal and shear viscoelastic stresses, and thixotropic properties. We demonstrate the microstructural configuration of blood in steady-state conditions, revealing that blood is highly aggregated in narrow tubes, promoting a flat velocity profile. Additionally, the proper accounting of the CFL thickness shows that for narrow microtubes, the reduction of discharged hematocrit is significant, which in some cases is up to 70%. At high pressure-gradients, the plasmatic proteins in both regions are extended in the flow direction, developing large axial normal stresses, which are more significant in the core region. We also provide normal stress predictions at both the blood/plasma interface (INS) and the tube wall (WNS), which are difficult to measure experimentally. Both decrease with the tube radius; however, they exhibit significant differences in magnitude and type of variation. INS varies linearly from 4.5 to 2 Pa, while WNS exhibits an exponential decrease taking values from 50 mPa to zero.

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Altered biventricular hemodynamic forces in patients with repaired tetralogy of Fallot and right ventricular volume overload because of pulmonary regurgitation

AJP Heart and Circulatory Physiology ◽

10.1152/ajpheart.00330.2018 ◽

2018 ◽

Vol 315 (6) ◽

pp. H1691-H1702 ◽

Cited By ~ 5

Author(s):

Pia Sjöberg ◽

Johannes Töger ◽

Erik Hedström ◽

Per Arvidsson ◽

Einar Heiberg ◽

...

Keyword(s):

Blood Flow ◽

Right Ventricular ◽

Tetralogy Of Fallot ◽

Flow Direction ◽

Pulmonary Regurgitation ◽

Ventricular Volume ◽

Left Ventricular ◽

Hemodynamic Forces ◽

Control Subjects ◽

Repaired Tetralogy Of Fallot

Intracardiac hemodynamic forces have been proposed to influence remodeling and be a marker of ventricular dysfunction. We aimed to quantify the hemodynamic forces in patients with repaired tetralogy of Fallot (rToF) to further understand the pathophysiological mechanisms as this could be a potential marker for pulmonary valve replacement (PVR) in these patients. Patients with rToF and pulmonary regurgitation (PR) > 20% ( n = 18) and healthy control subjects ( n = 15) underwent MRI, including four-dimensional flow. A subset of patients ( n = 8) underwent PVR and MRI after surgery. Time-resolved hemodynamic forces were quantified using 4D-flow data and indexed to ventricular volume. Patients had higher systolic and diastolic left ventricular (LV) hemodynamic forces compared with control subjects in the lateral-septal/LV outflow tract ( P = 0.011 and P = 0.0031) and inferior-anterior ( P < 0.0001 and P < 0.0001) directions, which are forces not aligned with blood flow. Forces did not change after PVR. Patients had higher RV diastolic forces compared with control subjects in the diaphragm-right ventricular (RV) outflow tract (RVOT; P < 0.001) and apical-basal ( P = 0.0017) directions. After PVR, RV systolic forces in the diaphragm-RVOT direction decreased ( P = 0.039) to lower levels than in control subjects ( P = 0.0064). RV diastolic forces decreased in all directions ( P = 0.0078, P = 0.0078, and P = 0.039) but were still higher than in control subjects in the diaphragm-RVOT direction ( P = 0.046). In conclusion, patients with rToF and PR had LV hemodynamic forces less aligned with intraventricular blood flow compared with control subjects and higher diastolic RV forces along the regurgitant flow direction in the RVOT and that of tricuspid inflow. Remaining force differences in the LV and RV after PVR suggest that biventricular pumping does not normalize after surgery. NEW & NOTEWORTHY Biventricular hemodynamic forces in patients with repaired tetralogy of Fallot and pulmonary regurgitation were quantified for the first time. Left ventricular hemodynamic forces were less aligned to the main blood flow direction in patients compared with control subjects. Higher right ventricular forces were seen along the pulmonary regurgitant and tricuspid inflow directions. Differences in forces versus control subjects remain after pulmonary valve replacement, suggesting that altered biventricular pumping does not normalize after surgery.

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Shear-induced endothelial cell-cell junction inclination

AJP Cell Physiology ◽

10.1152/ajpcell.00156.2010 ◽

2010 ◽

Vol 299 (3) ◽

pp. C621-C629 ◽

Cited By ~ 31

Author(s):

Benoît Melchior ◽

John A. Frangos

Keyword(s):

Endothelial Cell ◽

Flow Direction ◽

Cell Junction ◽

Structural Basis ◽

Retrograde Flow ◽

Arterial Circulation ◽

Mouse Aorta ◽

Cell Cell

Atheroprone regions of the arterial circulation are characterized by time-varying, reversing, and oscillatory wall shear stress. Several in vivo and in vitro studies have demonstrated that flow reversal (retrograde flow) is atherogenic and proinflammatory. The molecular and structural basis for the sensitivity of the endothelium to flow direction, however, has yet to be determined. It has been hypothesized that the ability to sense flow direction is dependent on the direction of inclination of the interendothelial junction. Immunostaining of the mouse aorta revealed an inclination of the cell-cell junction by 13° in direction of flow in the descending aorta where flow is unidirectional. In contrast, polygonal cells of the inner curvature where flow is disturbed did not have any preferential inclination. Using a membrane specific dye, the angle of inclination of the junction was dynamically monitored using live cell confocal microscopy in confluent human endothelial cell monolayers. Upon application of shear the junctions began inclining within minutes to a final angle of 10° in direction of flow. Retrograde flow led to a reversal of junctional inclination. Flow-induced junctional inclination was shown to be independent of the cytoskeleton or glycocalyx. Additionally, within seconds, retrograde flow led to significantly higher intracellular calcium responses than orthograde flow. Together, these results show for the first time that the endothelial intercellular junction inclination is dynamically responsive to flow direction and confers the ability to endothelial cells to rapidly sense and adapt to flow direction.

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