Dynamic Association between Artery Shear flow Condition and Platelet Cytosolic Free Ca2+ Concentration in Human Hypertension

1990 ◽  
Vol 79 (6) ◽  
pp. 613-618 ◽  
Author(s):  
Jaime Levenson ◽  
Marie-Aude Devynck ◽  
Isabelle Pithois-Merli ◽  
Kim Hanh Le Quan Sang ◽  
Vincenzo Filitti ◽  
...  
Keyword(s):  
Shear Stress ◽  
Shear Rate ◽  
Vascular Endothelial Cells ◽  
Cell Metabolism ◽  
Shear Stresses ◽  
Double Blind ◽  
Wide Range ◽  
Membrane Stretching ◽  
Positive Correlations

1. Blood cells and vascular endothelial cells are subjected to a wide range of haemodynamically generated shear stress forces. In vitro, membrane stretching or shear stress have been observed to activate ion channels and cell metabolism and to facilitate erythrocyte and platelet aggregation. 2. The present study was designed to evaluate the participation of shear stresses in the control of apparent platelet cytosolic free Ca2+ concentration in hypertensive patients. 3. Shear conditions and platelet cytosolic free Ca2+ concentration in vitro were studied after a dynamic perturbation induced by 3 months of double-blind treatment with one of two β-antagonists, carteolol and atenolol. Brachial artery wall shear rate and stress were estimated by means of a pulsed Doppler velocimeter, and blood viscosity was measured by a co-axial viscometer at a shear rate of 96 s−1. Platelet cytosolic free Ca2+ concentration was simultaneously measured by using the Quin-2 fluorescent chelator. The direct effect of atenolol and carteolol on platelet cytosolic free Ca2+ concentration in vitro was also measured after addition of the β-blockers to plateletrich plasma. 4. Atenolol and carteolol decreased blood pressure similarly but their effects on shear rate (P < 0.02), shear stress (P < 0.01) and platelet cytosolic free Ca2+ concentration (P < 0.05) differed after 3 months of therapy. In contrast, neither of the drugs significantly altered platelet cytosolic free Ca2+ concentration, in vitro per se. 5. In the overall population, strong positive correlations existed not only between changes in platelet cytosolic free Ca2+ concentration and those in shear rate (r = 0.81, P < 0.001) and shear stress (r = 0.83, P < 0.001), but also between their absolute values, suggesting a possible haemodynamic shear-dependent modulation of transmembrane Ca2+ transport.

Wall Shear Stress Measurements in an Arterial Flow Bioreactor

2011 ◽  
Author(s):  
Elizabeth Voigt ◽  
Cara Buchanan ◽  
Jaime Schmieg ◽  
M. Nichole Rylander ◽  
Pavlos Vlachos
Keyword(s):  
Endothelial Cells ◽  
Shear Stress ◽  
Vascular System ◽  
Vascular Endothelial Cells ◽  
Shear Stresses ◽  
Bulk Flow Rate ◽  
Wall Shear ◽  
Endothelial Cell Response ◽  
And Function

Physiological flow parameters such as pressure and stress inside the vascular system strongly influence the physiology and function of vascular endothelial cells [1]. Variations in the shear stress experienced by endothelial cells affect morphology, alignment with the flow, mechanical strength, rate of proliferation, and gene expression [2]. Although it is known that these factors are dependent on the hemodynamics of the flow, the relationship has not been accurately quantified. In vitro bioreactor flow loops have been developed to simulate vascular flow for tissue conditioning and measurement of the endothelial cell response to varying shear [3–5]; however, wall shear stresses (WSS) have been estimated from the bulk flow rate by assuming Poiseuille flow [2, 6]. Due to the pulsatility of the flow, biochemical interactions, and the typically short vessel length, this assumption is fundamentally incorrect; however, the level of inaccuracy has not been quantified.

scholarly journals VISCOMETRY OF NANODISPERSE MAGNETIC LIQUIDS AND LUBRICATING OILS. 1. INSTRUMENTATION FOR RHEOLOGICAL STUDIES OF MAGNETIC NANODISPERSE LIQUID MEDIA

2021 ◽  
pp. 44-55
Author(s):  
Александр Николаевич Болотов ◽  
Ольга Олеговна Новикова
Keyword(s):  
Magnetic Field ◽  
Shear Stress ◽  
Shear Rate ◽  
Viscosity Coefficient ◽  
Structural Features ◽  
Shear Stresses ◽  
Low Viscosity ◽  
Wide Range ◽  
Magnetic Nanofluids ◽  
The Magnetic Field

Анализ литературных источников показывает, что существующие вискозиметры не всегда и не полностью могут обеспечить комплексные исследования магнитных наножидкостей для научных и практических целей. Разработана конструкция магнитного ротационного вискозиметра, на котором исследования могут проводиться в широком диапазоне значений индукции магнитного поля. Магнитное поле в приборе направлено ортогонально напряжению сдвига и может изменяться от нуля до 1,7·10 А/м. Прибор имеет два измерительных зазора заполненных жидкостью, что повышает точность результатов исследований маловязких жидкостей. Вискозиметр позволяет измерять стандартные характеристики магнитных наножидкостей (коэффициент вязкости, пластическая вязкость, предельное напряжение сдвига и др.), а также изучать структурные особенности жидкостей при сдвиговых напряжениях. Скорость сдвига в жидкости может стабильно поддерживаться в широком диапазоне (1 ÷5)·10 с. Вязкость исследуемых жидкостей может изменяться от 10 Па·с до ≈ 10 Па·с. Для исследований на вискозиметре требуется небольшое количество магнитной наножидкости объемом около 3,5 см. Математическое описание процесса ламинарного течения жидкости в кольцевом зазоре вискозиметра позволило оптимизировать его геометрические размеры и получить формулы для расчета коэффициента вязкости, напряжения сдвига и скорости сдвига, используя экспериментальные данные. Analysis of the literature sources shows that the existing viscometers are not always and not completely able to provide comprehensive studies of magnetic nanofluids for scientific and practical purposes. Design has been developed of a magnetic rotary viscometer which makes it possible to carry out investigations in a wide range of the magnetic field induction. The magnetic field in the device is directed orthogonally to the shear stress and can vary from zero to 1,7·10 A/m. The device has two measuring gaps filled with liquid, that increases the accuracy of the results of studies of low-viscosity liquids. The viscometer allows you to measure the standard characteristics of magnetic nanofluids (viscosity coefficient, plastic viscosity, ultimate shear stress, etc.), as well as to study the structural features of liquids under shear stresses. The shear rate in the liquid can be stably maintained in a wide range of (1÷5)·10 c. The viscosity of the studied liquids can vary from 10 Pa·s to ≈10 Pa·s. For studies on a viscometer, a small amount of magnetic nanofluid with a volume of about 3,5 cm is required. Using experimental data, the mathematical description of the process of laminar fluid flow in the annular gap of the viscometer made it possible to optimize its geometric dimensions and obtain formulas for calculating the viscosity coefficient, shear stress and shear rate.

Application of the EYTEX™ System to the Evaluation of Cosmetic Products and their Ingredients

1992 ◽  
Vol 20 (1) ◽  
pp. 146-163
Author(s):  
Francis H. Kruszewski ◽  
Laura H. Hearn ◽  
Kyle T. Smith ◽  
Janice J. Teal ◽  
Virginia C. Gordon ◽  
...  
Keyword(s):  
Double Blind ◽  
Eye Irritation ◽  
Ocular Irritation ◽  
Rabbit Eye ◽  
Wide Range ◽  
High Concentrations ◽  
Alkaline Membrane ◽  
Positive Agreement

465 cosmetic product formulations and raw ingredients were evaluated with the EYTEX™ system to determine the potential of this in vitro alternative for identifying eye irritation potential. The EYTEX™ system is a non-animal, biochemical procedure developed by Ropak Laboratories, Irvine, CA, that was designed to approximate the Draize rabbit eye irritation assay for the evaluation of ocular irritation. Avon Products Inc. provided all the test samples, which included over 30 different product types and represented a wide range of eye irritancy. All the EYTEX™ protocols available at the time of this study were used. Samples were evaluated double-blind with both the membrane partition assay (MPA) and the rapid membrane assay (RMA). When appropriate, the standard assay (STD) and the alkaline membrane assay (AMA) were used, as well as specific, documented protocol modifications. EYTEX™ results were correlated with rabbit eye irritation data which was obtained from the historical records of Avon Products Inc. A positive agreement of EYTEX™ results with the in vivo assay was demonstrated by an overall concordance of 80%. The assay error was 20%, of which 18% was due to an overestimation of sample irritancy (false positives) and 2% was attributed to underestimation (false negatives). Overestimation error in this study was due in part to the inability of the protocols to accurately classify test samples with very low irritation potential. Underestimation of sample irritancy was generally associated with ethoxylated materials and high concentrations of specific types of surfactants. 100% sensitivity and 85% predictability were described by the data, indicating the efficiency of EYTEX™ in identifying known irritants. A specificity rate of 39% showed the EYTEX™ assay to be weak in discerning non-irritants. However, the EYTEX™ protocols used in this study were not designed to identify non-irritants. A compatibility rate of 99% proved the effectiveness of the EYTEX™ assay in accommodating a diversity of product types. The EYTEX™ system protocols, when used appropriately, can provide a conservative means of assessing the irritant potential of most cosmetic formulations and their ingredients.

scholarly journals Computational Analysis of Fluid Flow Within a Device for Applying Biaxial Strain to Cultured Cells

2015 ◽  
Vol 137 (5) ◽  
Author(s):  
Jason Lee ◽  
Aaron B. Baker
Keyword(s):  
Shear Stress ◽  
Cultured Cells ◽  
Fluid Velocity ◽  
Mechanical Strain ◽  
Cell Types ◽  
Linear Increase ◽  
Shear Stresses ◽  
Biaxial Strain ◽  
Maximal Strain

In vitro systems for applying mechanical strain to cultured cells are commonly used to investigate cellular mechanotransduction pathways in a variety of cell types. These systems often apply mechanical forces to a flexible membrane on which cells are cultured. A consequence of the motion of the membrane in these systems is the generation of flow and the unintended application of shear stress to the cells. We recently described a flexible system for applying mechanical strain to cultured cells, which uses a linear motor to drive a piston array to create biaxial strain within multiwell culture plates. To better understand the fluidic stresses generated by this system and other systems of this type, we created a computational fluid dynamics model to simulate the flow during the mechanical loading cycle. Alterations in the frequency or maximal strain magnitude led to a linear increase in the average fluid velocity within the well and a nonlinear increase in the shear stress at the culture surface over the ranges tested (0.5–2.0 Hz and 1–10% maximal strain). For all cases, the applied shear stresses were relatively low and on the order of millipascal with a dynamic waveform having a primary and secondary peak in the shear stress over a single mechanical strain cycle. These findings should be considered when interpreting experimental results using these devices, particularly in the case when the cell type used is sensitive to low magnitude, oscillatory shear stresses.

Hemodynamic Shear Stress And Endothelial Cell Function: In Vitro Studies

1981 ◽  
Author(s):  
M A Gimbrone ◽  
C F Dewey ◽  
P F Davies ◽  
S R Bussolari
Keyword(s):  
Shear Stress ◽  
Endothelial Cell ◽  
Fluid Shear Stress ◽  
Cell Structure ◽  
Structure And Function ◽  
Cellular Migration ◽  
Shear Stresses ◽  
Endothelial Cell Function ◽  
And Function

The vascular endothelial lining in vivo is constantly subjected to hemodynamic shear stresses resulting from normal and altered patterns of blood flow. To facilitate the study of effects of fluid shear stress on endothelial cell structure and function, we have developed an in vitro system, utilizing a cone-plate apparatus, to subject coverslip cultures of bovine aortic endothelial cells (BAEC) to controlled levels of shear (up to 102 dynes/cm2) in either laminar or turbulent flow. The magnitude and direction of shear stress within the system are accurately known from both theory and experimental measurements. The data reported here are for laminar flow. Subconfluent BAEC cultures continuously exposed to 1-5 dynes/cm2 shear proliferated at a rate comparable to that of static cultures, and postconfluent monolayers appeared unaltered morphologically for up to 1 week. In contrast, BAEC cultures (both postconfluent and subconfluent) exposed to 8 dynes/cm2 developed dramatic, time-dependent morphological changes. By 48 hrs, cells uniformly assumed an ellipsoidal configuration, with their major axes aligned in the direction of flow. Exposure to >10 dynes/cm2 caused variable cell detachment from plain glass substrates. Cellular migration into linear “wounds”, created in confluent areas, was influenced by both the direction and amplitude of applied shear. Exposure to 8 dynes/ cm2 induced functional alterations, including increased fluid (bulk phase) endocytosis, prostaglandin production and platelet reactivity. These observations indicate that fluid mechanical forces can directly influence endothelial cell structure and function. Hemodynamic modulation of endothelial cell behavior may be relevant to normal vessel wall physiology, as well as the pathogenesis of atherosclerosis and thrombosis.

Eulerian-Eulerian Multiphase Modeling of Blood Cells Segregation in Flow Through Microtubes

2017 ◽  
Author(s):  
Yertay Mendygarin ◽  
Luis R. Rojas-Solórzano ◽  
Nurassyl Kussaiyn ◽  
Rakhim Supiyev ◽  
Mansur Zhussupbekov
Keyword(s):  
Shear Stress ◽  
Red Blood Cells ◽  
Blood Cells ◽  
Heart Diseases ◽  
Accurate Determination ◽  
Shear Stresses ◽  
High Shear ◽  
Blood Damage ◽  
Solid Phases

Cardiovascular Diseases, the common name for various Heart Diseases, are responsible for nearly 17.3 million deaths annually and remain the leading global cause of death in the world. It is estimated that this number will grow to more than 23.6 million by 2030, with almost 80% of all cases taking place in low and middle income countries. Surgical treatment of these diseases involves the use of blood-wetted devices, whose relatively recent development has given rise to numerous possibilities for design improvements. However, blood can be damaged when flowing through these devices due to the lack of biocompatibility of surrounding walls, thermal and osmotic effects and most prominently, due to the excessive exposure of blood cells to shear stress for prolonged periods of time. This extended exposure may lead to a rupture of membrane of red blood cells, resulting in a release of hemoglobin into the blood plasma, in a process called hemolysis. Moreover, exposure of platelets to high shear stresses can increase the likelihood of thrombosis. Therefore, regions of high shear stress and residence time of blood cells must be considered thoroughly during the design of blood-contacting devices. Though laboratory tests are vital for design improvements, in-vitro experiments have proven to be costly, time-intensive and ethically controversial. On the other hand, simulating blood behavior using Computational Fluid Dynamics (CFD) is considered to be an inexpensive and promising tool to help predicting blood damage in complex flows. Nevertheless, current state-of-the-art CFD models of blood flow to predict hemolysis are still far from being fully reliable and accurate for design purposes. Previous work have demonstrated that prediction of hemolysis can be dramatically improved when using a multiphase (i.e., phases are plasma, red blood cells and platelets) model of the blood instead of assuming the blood as a homogeneous mixture. Nonetheless, the accurate determination of how the cells segregate becomes the critical issue in reaching a truthful prediction of blood damage. Therefore, the attempt of this study is to develop and validate a numerical model based on Granular Kinetic Theory (GKT) for solid phases (i.e., cells treated as particles) that provides an improved prediction of blood cells segregation within the flow in a microtube. Simulations were based on finite volume method using Eulerian-Eulerian modeling for treatment of three-phase (liquid-red blood cells and platelets) flow including the GKT to deal with viscous properties of the solid phases. GKT proved to be a good model to predict particle concentration and pressure drop by taking into account the contribution of collisional, kinetic and frictional effects in the stress tensor of the segregated solid phases. Preliminary results show that the improved segregated model leads to a better prediction of spatial distribution of blood cells. Simulations were performed using ANSYS FLUENT platform.

Effects of Fluid Shear Stress on Endothelial Cell Invasion Into Three-Dimensional Matrices

2007 ◽  
Author(s):  
Hojin Kang ◽  
Kayla J. Bayless ◽  
Roland Kaunas
Keyword(s):  
Endothelial Cells ◽  
Shear Stress ◽  
Endothelial Cell ◽  
Cell Invasion ◽  
Fluid Shear Stress ◽  
Vascular Endothelial Cells ◽  
Umbilical Vein ◽  
Shear Stresses ◽  
Collagen Gels ◽  
Fluid Shear

We have previously developed a cell culture model to study the effects of angiogenic factors, such as sphingosine-1-phosphate (S1P), on the invasion of endothelial cells into the underlying extracellular matrix. In addition to biochemical stimuli, vascular endothelial cells are subjected to fluid shear stress due to blood flow. The present study is aimed at determining the effects of fluid shear stress on endothelial cell invasion into collagen gels. A device was constructed to apply well-defined fluid shear stresses to confluent human umbilical vein endothelial cells (HUVECs) seeded on collagen gels. Fluid shear stress induced significant increases in cell invasion with a maximal induction at ∼5 dyn/cm2. These results provide evidence that fluid shear stress is a significant stimulus for endothelial cell invasion and may play a role in regulating angiogenesis.

Flow-induced dilation of rat soleus feed arteries

1997 ◽  
Vol 273 (5) ◽  
pp. H2423-H2427 ◽  
Author(s):  
Jeffrey L. Jasperse ◽  
M. Harold Laughlin
Keyword(s):  
Shear Stress ◽  
Maximum Flow ◽  
Intraluminal Pressure ◽  
Shear Stresses ◽  
Potential Contribution ◽  
Basal Diameter ◽  
Exercise Hyperemia ◽  
Feed Arteries

Flow-induced dilation is thought to contribute to dilation of skeletal muscle arteries and arterioles during exercise hyperemia. We sought to determine whether rat soleus feed arteries (SFA) exhibit flow-induced dilation and to evaluate the potential contribution of flow-induced dilation of SFA to exercise hyperemia. Rat SFA were isolated and cannulated to allow pressure and intraluminal flow to be independently controlled. Intraluminal pressure was maintained at 90 cmH2O throughout the experiment. All SFA ( n = 13) developed spontaneous tone and dilated in response to flow. Flow of 10 and 14 μl/min produced a 34 ± 14 and 56 ± 17 μm increase above basal diameter (135 ± 12 μm), respectively. Flows >14 μl/min produced little further dilation. Maximum flow-induced dilation was 86 ± 3% of passive diameter determined in calcium-free physiological saline solution. Calculated shear stress was maintained at 4–6 dyn/cm2 at flows of 10–20 μl/min but increased at greater flows because SFA did not dilate further. To determine whether dilation in response to flows in this range may contribute to exercise hyperemia, we estimated in vivo SFA blood flows from previously published soleus blood flow data. Anesthetized rats are estimated to have flows of 10 μl/min per SFA, and conscious rats are estimated to have flows of 95 (nonexercising), 153 (walking), and 225 (running) μl/min per SFA. Corresponding shear stresses were estimated to be 26 (anesthetized), 47 (conscious, nonexercising), 75 (walking), and 111 (running) dyn/cm2. Because estimated in vivo values for both flow and wall shear stress are far greater than the flow and/or shear stresses at which maximal flow-induced dilation occurs in vitro, we conclude that flow-induced dilation contributes little to dilation of SFA during locomotory exercise.

The Elongation and Orientation of Cultured Endothelial Cells in Response to Shear Stress

1985 ◽  
Vol 107 (4) ◽  
pp. 341-347 ◽  
Author(s):  
M. J. Levesque ◽  
R. M. Nerem
Keyword(s):  
Endothelial Cells ◽  
Shear Stress ◽  
Cell Elongation ◽  
Vascular Endothelial Cells ◽  
Flow Direction ◽  
Flow Chamber ◽  
Shear Stresses ◽  
Cell Alignment ◽  
Aortic Endothelial Cells ◽  
Time Required

Vascular endothelial cells appear to be aligned with the flow in the immediate vicinity of the arterial wall and have a shape which is more ellipsoidal in regions of high shear and more polygonal in regions of low shear stress. In order to study quantitatively the nature of this response, bovine aortic endothelial cells grown on Thermanox plastic coverslips were exposed to shear stress levels of 10, 30, and 85 dynes/cm2 for periods up to 24 hr using a parallel plate flow chamber. A computer-based analysis system was used to quantify the degree of cell elongation with respect to the change in cell angle of orientation and with time. The results show that (i) endothelial cells orient with the flow direction under the influence of shear stress, (ii) the time required for cell alignment with flow direction is somewhat longer than that required for cell elongation, (iii) there is a strong correlation between the degree of alignment and endothelial cell shape, and (iv) endothelial cells become more elongated when exposed to higher shear stresses.

Compaction and flow of potato starch and potato granules Compactación y flujo de almidón de patata y gránulos de patata

1997 ◽  
Vol 3 (5) ◽  
pp. 333-342 ◽  
Author(s):  
P.J. Halliday ◽  
A.C. Smith
Keyword(s):  
Shear Stress ◽  
Shear Rate ◽  
Wall Shear Stress ◽  
Water Content ◽  
Capillary Flow ◽  
Potato Starch ◽  
Slip Flow ◽  
Shear Stresses ◽  
Wall Shear ◽  
Water Contents

Potato starch and potato granules are materials that are often used in extrusion processes. It is important to quantify their rheology for modelling and prediction of process performance. The compaction behaviour of potato starch was examined at water contents of 4-18% wwb (wet weight basis) for pressures between 1 and 85 MPa. The Heckel deformation stress decreased as the water content increased up to 12% but became inaccurate at 18%. This decrease agreed qualitatively with other observations of the decrease in stiffness of starchy materials over this water content range. Potato granules were examined at water contents of 25-45% wwb and aspects of their rheo logical behaviour characterized using different approaches. A first approximation used the shear viscosity-shear rate power law which produced a law exponent for the resulting pastes (0.1-0.2). The classical Benbow equation was used to estimate yield and wall shear stresses in capillary flow. The latter indicates the presence of slip which was examined more fully as a function of wall shear stress. The Mooney technique was used together with a variation of the method where the shear rate for each die was subtracted from that for a non-slip flow, which was approximated using rough dies. A critical wall shear stress for slip was found to be 0.05-0.1 MPa, making it consistent with published results for other materials.

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