An in vitro test bench reproducing coronary blood flow signals

Chodzynski, Kamil; Boudjeltia, Karim Zouaoui; Lalmand, Jacques; Aminian, Adel; Vanhamme, Luc; Sousa, Daniel Ribeiro de; Gremmo, Simone; Bricteux, Laurent; Renotte, C.; Courbebaisse, Guy; Coussement, Grégory

doi:10.1186/s12938-015-0065-x

Cited by 13 publications

(10 citation statements)

References 24 publications

(27 reference statements)

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“…Eight different configurations of symmetric Y-junction vessels were studied with angles ranging from 25° up to 180°. For the simulations here presented, an inlet velocity condition consisting in a flat profile of 0.2 m/s 21 was considered in the main vessel and atmospheric pressure outlet in both branching vessels, except specified otherwise. Although it is well known that there are other outflow conditions more suitable to correlate simulations with real circulatory system (such as Murray law-based conditions) an atmospheric pressure condition was used as a first approximation to the problem in order to compare the experimental data.…”

Section: Methodsmentioning

confidence: 99%

Determination of hemodynamic risk for vascular disease in planar artery bifurcations

Otero-Cacho

Aymerich

Flores-Arias

et al. 2018

Sci Rep

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Understanding hemodynamics in blood circulation is crucial in order to unveil the mechanisms underlying the formation of stenosis and atherosclerosis. In fact, there are experimental evidences pointing out to the existence of some given vessel configurations that are more likely to develop the above mentioned pathologies. Along this manuscript, we performed an exhaustive investigation in a simplified model aiming to characterize by means of physical quantities those regions and configurations in vessel bifurcations that are more likely to develop such pathologies. The two-fold analysis is based, on the one hand, on numerical simulations (via CFD) and, on the other hand, on experiments realized in an ad-hoc designed polydimethylsiloxane (PDMS) channel with the appropriate parameters and appropriate fluid flows. The results obtained demonstrate that low velocity regions and low shear stress zones are located in the outer walls of bifurcations. In fact, we found that there is a critical range of bifurcation angles that is more likely to vascular disease than the others in correspondence with some experimental evidence. The effect of the inflow velocity on this critical range is also analyzed.

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Section: Methodsmentioning

confidence: 99%

Determination of hemodynamic risk for vascular disease in planar artery bifurcations

Otero-Cacho

Aymerich

Flores-Arias

et al. 2018

Sci Rep

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“…Briefly, the experiments were carried out using the spherical transparent silicone model placed in the in vitro test bench developed previously 19 . The test bench was set at 37 °C.…”

Section: Methodsmentioning

confidence: 99%

“…In this article, the impact of harmonic flow complexity on flow diverter treatment of intracranial aneurysms was investigated experimentally using an in vitro analysis. For this purpose, a silicone model of a spherical aneurysm was connected to a test bench mimicking the pulsatile haemodynamic conditions encountered in vivo 19 . For the input flow signal, the flow from a reference patient was decomposed into four patterns with decreasing complexity and pulsatility indexes.…”

mentioning

confidence: 99%

The impact of arterial flow complexity on flow diverter outcomes in aneurysms

Chodzynski

Uzureau

Nuyens

et al. 2020

Sci Rep

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The flow diverter is becoming a standard device for treating cerebral aneurysms. The aim of this in vitro study was to evaluate the impact of flow complexity on the effectiveness of flow diverter stents in a cerebral aneurysm model. The flow pattern of a carotid artery was decomposed into harmonics to generate four flow patterns with different pulsatility indexes ranging from 0.72 to 1.44. The effect of flow diverters on the aneurysm was investigated by injecting red dye or erythrocytes as markers. The recorded images were postprocessed to evaluate the maximum filling of the aneurysm cavity and the washout time. There were significant differences in the cutoff flows between the markers, linked to the flow complexity. Increasing the pulsatility index altered the performance of the flow diverter. The red dye was more sensitive to changes in flow than the red blood cell markers. The flow cutoff depended on the diverter design and the diverter deployment step was crucial for reproducibility of the results. These results strongly suggest that flow complexity should be considered when selecting a flow diverter. Flow diverters are common devices for treating large or complex intracranial aneurysms. As the mechanisms underlying aneurysm occlusion are still not fully understood, the choice of flow diverter is mainly empirical and based on the physician's own experience 1,2. Outcomes range from complete or partial occlusion after varying periods to lack of thrombosis or even haemorrhage 3,4. The factors responsible for occlusion following flow diverter placement are still under debate 3,5. Analysis of the flow inside large aneurysms reveals that, by contrast with small aneurysms where flow is similar to the parent vessel, the flow pattern can be markedly altered 6. Recent studies show that flow complexity is a key factor in flow diverter performance. Computational fluid dynamics (CFD) simulations showed that flow reduction following flow diverter treatment was more noticeable during diastole than systole and that flow diverter performance was related to the flow pattern 7,8. Although blood flow complexity can be fully described using a Fourier decomposition into harmonics, these values are not commonly used in the medical field 9. Instead, the pulsatility index, which can be directly assessed from Doppler or magnetic resonance imaging (MRI) examinations, is more widely used to describe the complexity of patient blood flows 10. The pulsatility index varies within the cerebral arterial tree and within the same artery in different patients, reflecting the diversity of flow patterns that can be encountered within the vessels altered by aneurysms 11,12. Different outcomes are therefore observed when the same flow diverter is used in situations of different flow patterns associated with vessel geometry and position in the cerebral arterial tree, and the physiological state and activity of the patient 13,14. In addition, flow diverter design, including the number of layers, porosity, number of holes, weave angle, wire diameter, a...

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“…Gear pumps cause significant noise in the flow and pressure signal and should not be used for studies with blood cells. In [13][14][15] a centrifugal pump is used to provide the baseline flow because of its low noise signature compared to a roller pump. A piston pump superposes the pulsatile flow.…”

Section: Hemodynamic Flow Devices In Literaturementioning

confidence: 99%

Active Pneumatic Pulsation Damper for Peristaltic Pump Flow Loops

Liermann

2016

BATH/ASME 2016 Symposium on Fluid Power and Motion Control

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A novel concept of an active pulsation damper is described that cancels parasitic flow pulsatility of peristaltic pumps and is able to inject desired pulsatility signatures such as physiological heart beat. Peristaltic pumps avoid contact between the moving parts of a pump and the operating fluid. They are used for clean or sterile fluids as well as for highly aggressive fluids, whenever it is important to isolate the fluid from the environment. The background application for the proposed active pulsation damper is the simulation of hemodynamic flow. The paper presents a novel pulse damper concept that allows the use of roller or peristaltic pumps as primary pumps for hemodynamic flow loops. The problem with peristaltic pumps is that they exhibit a high parasitic pulsatility that needs to be canceled before a desired pulsatility can be injected. The active pulsation damper does this and is also used to superpose a desired flow pattern that resembles measured heart flow rate profiles. The nonlinear dynamic equations of a test system with active pulsation dampers are established and linearized to allow a first analysis of the achievable bandwidth. Simulation results of the closed loop system are presented based on the non-linear equations.

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An in vitro test bench reproducing coronary blood flow signals

Cited by 13 publications

References 24 publications

Determination of hemodynamic risk for vascular disease in planar artery bifurcations

Determination of hemodynamic risk for vascular disease in planar artery bifurcations

The impact of arterial flow complexity on flow diverter outcomes in aneurysms

Active Pneumatic Pulsation Damper for Peristaltic Pump Flow Loops

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