Three‐dimensional distribution of wall shear stress and its gradient in red cell‐resolved computational modeling of blood flow in in vivo‐like microvascular networks

Balogh, Péter; Bagchi, Prosenjit

doi:10.14814/phy2.14067

Cited by 34 publications

(43 citation statements)

References 75 publications

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“…However, the functional significance of this vascular anisotropy remains unclear. Future works including computational modeling considering additional information (e.g., blood pressure and viscosity) can help to gain a more complete understanding of brain blood perfusion (Balogh and Bagchi, 2019;.…”

Section: Microvascular Map To Understand Regional Blood Flowmentioning

confidence: 99%

The cellular architecture of microvessels, pericytes and neuronal cell types in organizing regional brain energy homeostasis in mice

Chon

et al. 2021

Preprint

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The cerebrovascular network and its mural cells must meet the dynamic energy demands of different neuronal cell types across the brain, but their spatial relationship among these cells is largely unknown. Here, we apply brain-wide mapping methods to create a comprehensive cellular-resolution resource comprising the distribution of and quantitative relationship between microvessels, pericytes, and glutamatergic and GABAergic neurons including neuronal nitric oxide synthase-positive (nNOS+) neurons and their subtypes in mice. Leveraging these data, we discovered region-specific signatures of vasculature and cell type compositions across cortical and subcortical areas, including strikingly contrasting correlations between the density of vasculature, pericytes, glutamatergic neurons and parvalbumin-positive interneurons versus nNOS+ neurons in the isocortex. We also found surprisingly low vasculature and pericyte density in the hippocampus, and distinctly high pericyte to vasculature ratio in the hypothalamus. These findings suggest that vascular density and mural cell composition is finely tuned to maintain regional energy homeostasis.

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Section: Microvascular Map To Understand Regional Blood Flowmentioning

confidence: 99%

The cellular architecture of microvessels, pericytes and neuronal cell types in organizing regional brain energy homeostasis in mice

Chon

et al. 2021

Preprint

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“…The dynamics of soft capsules is widely studied at low Reynolds numbers in canonical flows [41][42][43][44][45] and cellular blood flow simulations. [46][47][48][49] Only recently, inertial microfluidics of deformable cells has caught attention. 20,[50][51][52][53][54][55][56][57][58] Using two-dimensional numerical simulations, Shin and Sung 51 showed that the final equilibrium position for a given value of capsule elasticity varies with the Reynolds number.…”

Section: Introductionmentioning

confidence: 99%

A pair of particles in inertial microfluidics: effect of shape, softness, and position

Patel

Stark

2021

Soft Matter

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“…As expected, the CFL exhibits a lower viscosity than the rest of the fluid and this facilitates blood flow through the microvessels. This is clearly pronounced by relevant studies that attempt to estimate wall shear stress [8,9] or pressure drop [10] values in such vessels. Although this phenomenon is significant for diameters less than 300 µm, most of the published work is focused on vessel diameters between 20 and 100 µm, e.g., [6], or on fairly different geometries [11].…”

Section: Introductionmentioning

confidence: 99%

Experimental and Numerical Study of Blood Flow in μ-vessels: Influence of the Fahraeus–Lindqvist Effect

Stergiou

Keramydas

Anastasiou

et al. 2019

Fluids

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The study of hemodynamics is particularly important in medicine and biomedical engineering as it is crucial for the design of new implantable devices and for understanding the mechanism of various diseases related to blood flow. In this study, we experimentally identify the cell free layer (CFL) width, which is the result of the Fahraeus–Lindqvist effect, as well as the axial velocity distribution of blood flow in microvessels. The CFL extent was determined using microscopic photography, while the blood velocity was measured by micro-particle image velocimetry (μ-PIV). Based on the experimental results, we formulated a correlation for the prediction of the CFL width in small caliber (D < 300 μm) vessels as a function of a modified Reynolds number (Re∞) and the hematocrit (Hct). This correlation along with the lateral distribution of blood viscosity were used as input to a “two-regions” computational model. The reliability of the code was checked by comparing the experimentally obtained axial velocity profiles with those calculated by the computational fluid dynamics (CFD) simulations. We propose a methodology for calculating the friction loses during blood flow in μ-vessels, where the Fahraeus–Lindqvist effect plays a prominent role, and show that the pressure drop may be overestimated by 80% to 150% if the CFL is neglected.

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Three‐dimensional distribution of wall shear stress and its gradient in red cell‐resolved computational modeling of blood flow in in vivo‐like microvascular networks

Cited by 34 publications

References 75 publications

The cellular architecture of microvessels, pericytes and neuronal cell types in organizing regional brain energy homeostasis in mice

The cellular architecture of microvessels, pericytes and neuronal cell types in organizing regional brain energy homeostasis in mice

A pair of particles in inertial microfluidics: effect of shape, softness, and position

Experimental and Numerical Study of Blood Flow in μ-vessels: Influence of the Fahraeus–Lindqvist Effect

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