Increased Inlet Blood Flow Velocity Predicts Low Wall Shear Stress in the Cephalic Arch of Patients with Brachiocephalic Fistula Access

Abstract: BackgroundAn autogenous arteriovenous fistula is the optimal vascular access for hemodialysis. In the case of brachiocephalic fistula, cephalic arch stenosis commonly develops leading to access failure. We have hypothesized that a contribution to fistula failure is low wall shear stress resulting from post-fistula creation hemodynamic changes that occur in the cephalic arch.MethodsTwenty-two subjects with advanced renal failure had brachiocephalic fistulae placed. The following procedures were performed at map… Show more

“…In a parallel study, we have statistically and computationally identified a physiologic range of WSS in the cephalic vein pre-surgery. This range was determined to be 0.076 ≤ τ w ≤ 0.76 Pa [61] , which is consistent with the range given in previous literature [22] .…”

“…The flow is assumed to be Newtonian. Pulsatility and non-Newtonian effects were both attended to previously and were found to be insignificant in our patient cohort [61,62,63,64,77,75,76] . WBV for the CFD simulation is taken to be the patient-specific high-shear rate asymptotic viscosity values from the viscometry tests [62,78] .…”

“…The alternative would be to consider patient-specific cardiac waveforms and, instead, consider the TAWSS distribution in the domain, which is computationally very costly. In this specific application, as we showed before [61,62,63] , the WSS distribution is found to be insensitive to pulsatility and implementation of the non-Newtonian constitutive relations [61] .…”

“…Moreover, the simulations discussed thus far are all stationary and therefore, it stands to reason that no turbulent scales are present. We reiterate that the inlet pressure is time-independent [61,63] . The alternative would be to consider patient-specific cardiac waveforms and, instead, consider the TAWSS distribution in the domain, which is computationally very costly.…”

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

“…In a parallel study, we have statistically and computationally identified a physiologic range of WSS in the cephalic vein pre-surgery. This range was determined to be 0.076 ≤ τ w ≤ 0.76 Pa [61] , which is consistent with the range given in previous literature [22] .…”

“…The flow is assumed to be Newtonian. Pulsatility and non-Newtonian effects were both attended to previously and were found to be insignificant in our patient cohort [61,62,63,64,77,75,76] . WBV for the CFD simulation is taken to be the patient-specific high-shear rate asymptotic viscosity values from the viscometry tests [62,78] .…”

“…The alternative would be to consider patient-specific cardiac waveforms and, instead, consider the TAWSS distribution in the domain, which is computationally very costly. In this specific application, as we showed before [61,62,63] , the WSS distribution is found to be insensitive to pulsatility and implementation of the non-Newtonian constitutive relations [61] .…”

“…Moreover, the simulations discussed thus far are all stationary and therefore, it stands to reason that no turbulent scales are present. We reiterate that the inlet pressure is time-independent [61,63] . The alternative would be to consider patient-specific cardiac waveforms and, instead, consider the TAWSS distribution in the domain, which is computationally very costly.…”

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

“…25 More recent work, undertaken specifically in the context of vascular fluid mechanics, includes studies of stenotic flows, 26 pulsatile flow in curved pipes, [27][28][29][30] flow in helical pipes, [31][32][33][34] and flow at junctions. [35][36][37] In terms of simulating flow in AVF configurations, there have been a range of previous Computational Fluid Dynamics (CFD) studies, including 1D simulations, [38][39][40] 2D simulations, 41 3D simulations with rigid walls in idealised geometries, [42][43][44][45][46][47] 3D simulations with rigid walls in more realistic geometries, [48][49][50][51][52][53][54][55] and simulations with distensible walls. 56 Of these studies, several investigated flow unsteadiness.…”

Suppressing unsteady flow in arterio-venous fistulae

Swing Point Stenosis