Blood flow rate and wall shear stress in seven major cephalic arteries of humans

Seymour, Roger S.; Hu, Qiaohui; Snelling, Edward P.

doi:10.1111/joa.13119

“…Using the devices in series allowed modeling of multiple tissue barriers in a connected system. To further assess the device flow, sheer stress was calculated using the Navier–Stokes equation ( Seymour et al , 2020 ). At a flow rate of 2.94 μ l min −1 , the cells were subjected to 4.0 × 10 −3 dyn cm −2 shear stress.…”

Section: Resultsmentioning

confidence: 99%

Development of a dual-flow tissue perfusion device for modeling the gastrointestinal tract–brain axis

Baldwin,

Jones,

Iles

et al. 2023

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Despite the large number of microfluidic devices that have been described over the past decade for the study of tissues and organs, few have become widely adopted. There are many reasons for this lack of adoption, primarily that devices are constructed for a single purpose or because they are highly complex and require relatively expensive investment in facilities and training. Here, we describe a microphysiological system (MPS) that is simple to use and provides fluid channels above and below cells, or tissue biopsies, maintained on a disposable, poly(methyl methacrylate), carrier held between polycarbonate outer plates. All other fittings are standard Luer sizes for ease of adoption. The carrier can be coated with cells on both sides to generate membrane barriers, and the devices can be established in series to allow medium to flow from one cell layer to another. Furthermore, the carrier containing cells can be easily removed after treatment on the device and the cells can be visualized or recovered for additional off-chip analysis. A 0.4 μm membrane with cell monolayers proved most effective in maintaining separate fluid flows, allowing apical and basal surfaces to be perfused independently. A panel of different cell lines (Caco-2, HT29-MTX-E12, SH-SY5Y, and HUVEC) were successfully maintained in the MPS for up to 7 days, either alone or on devices connected in series. The presence of tight junctions and mucin was expressed as expected by Caco-2 and HT-29-MTX-E12, with Concanavalin A showing uniform staining. Addition of Annexin V and PI showed viability of these cells to be >80% at 7 days. Bacterial extracellular vesicles (BEVs) produced by Bacteroides thetaiotaomicron and labeled with 1,1′-dioctadecyl-3,3,3′,3′-tetramethylindocarbo-cyanine perchlorate (DiD) were used as a model component of the human colonic microbiota and were visualized translocating from an apical surface containing Caco-2 cells to differentiated SH-SY5Y neuronal cells cultured on the basal surface of connected devices. The newly described MPS can be easily adapted, by changing the carrier to maintain spheroids, pieces, or slices of biopsy tissue and joined in series to study a variety of cell and tissue processes. The cell layers can be made more complex through the addition of multiple cell types and/or different patterning of extracellular matrix and the ability to culture cells adjacent to one another to allow study of cell:cell transfer, e.g., passive or active drug transfer, virus or bacterial entry or BEV uptake and transfer.

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“…In the fluid, inlet velocities and outlet pressure conditions were prescribed as follows:

where

was built based on the waveform plotted in Figure 2 , corresponding to an averaged internal carotid pulse reported by [ 38 ]. It was prefixed with a

s linear ramp for a smoother initialization and scaled to reach an average flow rate of 4 mL·s −1 , which correponded to the mean ICA flow measured among 13 studies, as reported in a recent review [ 39 ].…”

Section: Materials and Methodsmentioning

confidence: 99%

“…where V(t) was built based on the waveform plotted in Figure 2, corresponding to an averaged internal carotid pulse reported by [38]. It was prefixed with a 0.2 s linear ramp for a smoother initialization and scaled to reach an average flow rate of 4 mL•s −1 , which correponded to the mean ICA flow measured among 13 studies, as reported in a recent review [39]. At the outflow, unlike in typical CFD simulations, the absolute value of the pressure was of major importance.…”

Section: Boundary Conditionsmentioning

confidence: 99%

Analysis of Intracranial Aneurysm Haemodynamics Altered by Wall Movement

Goetz,

Jeken-Rico,

Chau

et al. 2024

Bioengineering

1

0

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Computational fluid dynamics is intensively used to deepen our understanding of aneurysm growth and rupture in an attempt to support physicians during therapy planning. Numerous studies assumed fully rigid vessel walls in their simulations, whose sole haemodynamics may fail to provide a satisfactory criterion for rupture risk assessment. Moreover, direct in vivo observations of intracranial aneurysm pulsation were recently reported, encouraging the development of fluid–structure interaction for their modelling and for new assessments. In this work, we describe a new fluid–structure interaction functional setting for the careful evaluation of different aneurysm shapes. The configurations consist of three real aneurysm domes positioned on a toroidal channel. All geometric features, employed meshes, flow quantities, comparisons with the rigid wall model and corresponding plots are provided for the sake of reproducibility. The results emphasise the alteration of flow patterns and haemodynamic descriptors when wall deformations were taken into account compared with a standard rigid wall approach, thereby underlining the impact of fluid–structure interaction modelling.

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“…(Online version in colour.) [25]. Thus, the ICAs account for 88%, and the VAs account for 12%, of total cerebral perfusion.…”

Section: (A) Brain Perfusion In Extant Haplorhine Primatesmentioning

confidence: 99%

“…Although the ICAs supply approximately 75%, and the VAs 25%, of total brain perfusion ð _ Q TOTAL Þ in humans [25][26][27][28][29][30][31], these proportions approach each other in extant haplorhine species with smaller brains until they become approximately equal in brains smaller than 10 ml. (See the electronic supplementary material, including figure S5, for a detailed analysis of the roles of the VAs and ICAs in extant haplorhines.)…”

Section: (A) Brain Perfusion In Extant Haplorhine Primatesmentioning

confidence: 99%

Cerebral blood flow rates in recent great apes are greater than in Australopithecus species that had equal or larger brains

Seymour

¹

,

Bosiocic

²

,

Snelling

³

et al. 2019

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Brain metabolic rate (MR) is linked mainly to the cost of synaptic activity, so may be a better correlate of cognitive ability than brain size alone. Among primates, the sizes of arterial foramina in recent and fossil skulls can be used to evaluate brain blood flow rate, which is proportional to brain MR. We use this approach to calculate flow rate in the internal carotid arteries ( Q ˙ ICA ) , which supply most of the primate cerebrum. Q ˙ ICA is up to two times higher in recent gorillas, chimpanzees and orangutans compared with 3-million-year-old australopithecine human relatives, which had equal or larger brains. The scaling relationships between Q ˙ ICA and brain volume ( V br ) show exponents of 1.03 across 44 species of living haplorhine primates and 1.41 across 12 species of fossil hominins. Thus, the evolutionary trajectory for brain perfusion is much steeper among ancestral hominins than would be predicted from living primates. Between 4.4-million-year-old Ardipithecus and Homo sapiens , V br increased 4.7-fold, but Q ˙ ICA increased 9.3-fold, indicating an approximate doubling of metabolic intensity of brain tissue. By contrast, Q ˙ ICA is proportional to V br among haplorhine primates, suggesting a constant volume-specific brain MR.

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Blood flow rate and wall shear stress in seven major cephalic arteries of humans

Cited by 16 publications

References 62 publications

Development of a dual-flow tissue perfusion device for modeling the gastrointestinal tract–brain axis

Development of a dual-flow tissue perfusion device for modeling the gastrointestinal tract–brain axis

Analysis of Intracranial Aneurysm Haemodynamics Altered by Wall Movement

Cerebral blood flow rates in recent great apes are greater than in Australopithecus species that had equal or larger brains

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