A predictive framework to elucidate venous stenosis: CFD &amp; shape optimization

Akherat, S. M. Javid Mahmoudzadeh; Cassel, Kevin W.; Boghosian, Michael; Hammes, Mary; Coe, Fredric L.

doi:10.1016/j.cma.2017.03.036

Cited by 11 publications

(5 citation statements)

References 62 publications

(52 reference statements)

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“…WSS results for this patient show that values are not restored to the pre-creation baseline set point as previously suggested (Javid Mahmoudzadeh Akherat et al 2017), but fluctuate around a new, higher value. This demonstrates a possible control mechanism in which the diameter is adjusted to maintain WSS within a narrow range of the new set point.…”

Section: Discussionsupporting

confidence: 60%

“…Studies to monitor newly created AVFs have reported elevated WSS in the artery when compared to baseline (precreation) values (Ene-Iordache et al 2003). It would follow that the artery will increase in lumen diameter to lower the WSS back to baseline, which has been a hypothesis of previous AVF studies (Javid Mahmoudzadeh Akherat et al 2017). It is generally accepted that arterial vasculature seeks to maintain constant WSS at a preferred, homeostatic value (Humphrey 2008), with the presence of a control mechanism demonstrated by Le Noble et al (2005).…”

Section: Introductionmentioning

confidence: 98%

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A longitudinal study of the arterio-venous fistula maturation of a single patient over 15 weeks

Colley

Carroll

Simmons

et al. 2022

Biomech Model Mechanobiol

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Arterio-venous fistula creation is the preferred vascular access for haemodialysis, but has a large failure rate in the maturation period. Previous research, considering the remodelling mechanisms for failure-to-mature patients, has been limited by obtaining the patient-specific boundary conditions at only a few points in the patient history. Here, a non-invasive imaging system was used to reconstruct the three-dimensional vasculature, and computational fluid dynamics was used to analyse the haemodynamics for one patient over 15 weeks. The analysis suggested evidence of a control mechanism, which adjusts the lumen diameter to keep the wall shear stress near constant in the proximal regions of the vein and artery. Additionally, the vein and artery were shown to remodel at different growth rates, and the blood flow rate also saw the largest increase within the first week. Wall shear stress at time of creation may be a useful indicator for successful AVF maturation.

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Section: Discussionsupporting

confidence: 60%

Section: Introductionmentioning

confidence: 98%

A longitudinal study of the arterio-venous fistula maturation of a single patient over 15 weeks

Colley

Carroll

Simmons

et al. 2022

Biomech Model Mechanobiol

View full text Add to dashboard Cite

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“…[22] On the other hand, the variation in vessel wall parameters increases turbulence and introduces ow separation, leading to damage repair and reconstruction of the endothelial cell. [27] Therefore, the hemorrhagic presentation in AVMs may result from the interaction of hemodynamics and speci c angioarchitecture resulting in occlusive congestion within the AVM nidus. [9] There were some limitations in our study.…”

Section: Discussionmentioning

confidence: 99%

Quantitative hemodynamics of draining veins in brain arteriovenous malformation: a preliminary study based on computational fluid dynamics

Ma,

Chen,

Chen

et al. 2024

Preprint

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Objective: This study initiated a preliminary computational fluid dynamics (CFD)-based study to investigate the relationship between quantitative hemodynamics of arteriovenous malformation (AVM) draining veins and rupture. Methods: The quantitative hemodynamics of AVM draining veins were generated from computed tomography angiography (CTA)-based steady-state CFD models. Morphological and hemodynamic parameters were compared between the ruptured and unruptured groups. The boundary conditions of the drainage vein were obtained from quantitative digital subtraction angiography (QDSA). The draining veins were divided into 15 consecutive segments to analyze the spatial distribution of the hemodynamic parameters by linear regression analysis. Results: From 11 AVMs, it was revealed that morphological parameters of drainage veins in ruptured and unruptured AVMs were similar. The intravascular pressure of the draining vein in the ruptured AVMs was significantly higher than those of the unruptured AVMs (pressure average: P = 0.006; pressure maximum: P = 0.045), and the WSS of the posterior segment was higher in ruptured AVMs (P = 0.045). WSS of draining veins in ruptured AVMs showed a linear increase trend with segmenting (R = 0.731, P < 0.001), and ruptured AVMs were more likely to be accompanied by high-velocity segments in the draining vein (40.0% vs. 14.7%, P = 0.037), especially in the posterior segment (P = 0.011). Conclusion: The draining veins of ruptured AVMs had significantly higher intravascular pressure and posterior segment WSS. WSS showed a linear increase with segmentation in ruptured AVMs, and they often had more high-velocity segments in the draining vein, especially in the posterior segment.

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“…The hemodynamic characteristics associated with a stenosis in an artery are 1) pre-stenotic pressure buildup and 2) post-stenotic pressure drop [5, 6]. When pressure waves pass through an inflow stenosis, the pressure energy is dissipated by being converted to kinetic energy and is attenuated downstream to the anastomosis along the length of an AVF according to Poiseuille’s law.…”

Section: Methodsmentioning

confidence: 99%

Measuring the palpable pulsatility length as a physical examination test in defining the severity of inflow stenosis for hemodialysis fistulas

Chen

Weng

et al. 2019

BMC Nephrol

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Background Pulsatility is an important property of hemodialysis arteriovenous fistulas (AVF) and can be perceived by the fingers as a gradual decrease in strength downstream from the anastomosis along the main trunk of the fistula. The distance from the point at which the pulse becomes imperceptible to the anastomosis is termed the palpable pulsatility length (PPL); we considered this length may play a role in assessing the severity of inflow stenosis for hemodialysis fistulas. Methods This study was performed by retrospective analysis of routinely collected data. Physical examinations and fistula measurements were performed in a selected population of 76 hemodialysis patients with mature fistulas during half a year. Fistula measurements included the PPL before and after treatment and the distance between the anastomosis and the arterial cannulation site (aPump length). The aPump index (API) was calculated by dividing the PPL by the aPump length. Angiograms were reviewed to determine the location and severity of stenosis. PPL and API were used to detect the critical inflow stenosis, which indicates severe inflow stenosis of an AVF. Results Receiver operating characteristic analysis showed that the area under the curve was 0.895 for API and 0.878 for PPL. A cutoff value of API < 1.29 and PPL < 11.0 cm were selected to detect the critical inflow stenosis. The sensitivity was 96.0% versus 80.0% and specificity was 84.31% versus 84.31% for API and PPL, respectively. Conclusions PPL and API are useful tools in defining the severity of pure inflow stenosis for mature AVFs in the hands of trained examiners with high sensitivity and specificity.

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A predictive framework to elucidate venous stenosis: CFD & shape optimization

Cited by 11 publications

References 62 publications

A longitudinal study of the arterio-venous fistula maturation of a single patient over 15 weeks

A longitudinal study of the arterio-venous fistula maturation of a single patient over 15 weeks

Quantitative hemodynamics of draining veins in brain arteriovenous malformation: a preliminary study based on computational fluid dynamics

Measuring the palpable pulsatility length as a physical examination test in defining the severity of inflow stenosis for hemodialysis fistulas

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