Your search keyword '"Kasinpila, Patpilai"' showing total 3 results

1. Use of patient-specific computational models for optimization of aortic insufficiency after implantation of left ventricular assist device.

Author

Kasinpila P, Kong S, Fong R, Shad R, Kaiser AD, Marsden AL, Woo YJ, and Hiesinger W

Subjects

Adult, Aged, Aorta diagnostic imaging, Aortic Valve diagnostic imaging, Aortic Valve Insufficiency diagnostic imaging, Aortic Valve Insufficiency physiopathology, Aortography, Computed Tomography Angiography, Female, Heart Failure diagnostic imaging, Heart Failure physiopathology, Humans, Hydrodynamics, Male, Middle Aged, Predictive Value of Tests, Prosthesis Design, Retrospective Studies, Risk Factors, Stress, Mechanical, Treatment Outcome, Aorta physiopathology, Aortic Valve physiopathology, Aortic Valve Insufficiency etiology, Heart Failure surgery, Heart-Assist Devices, Hemodynamics, Models, Cardiovascular, Patient-Specific Modeling, Prosthesis Implantation adverse effects, Prosthesis Implantation instrumentation, Ventricular Function, Left

Abstract

Objective: Aortic incompetence (AI) is observed to be accelerated in the continuous-flow left ventricular assist device (LVAD) population and is related to increased mortality. Using computational fluid dynamics (CFD), we investigated the hemodynamic conditions related to the orientation of the LVAD outflow in these patients., Method: We identified 10 patients with new aortic regurgitation, and 20 who did not, after LVAD implantation between 2009 and 2018. Three-dimensional models of patients' aortas were created from their computed tomography scans. The geometry of the LVAD outflow graft in relation to the aorta was quantified using azimuth angles (AA), polar angles (PAs), and distance from aortic root. The models were used to run CFD simulations, which calculated the pressures and wall shear stress (rWSS) exerted on the aortic root., Results: The AA and PA were found to be similar. However, for combinations of high values of AA and low values of PA, there were no patients with AI. The distance from aortic root to the outflow graft was also smaller in patients who developed AI (3.39 ± 0.7 vs 4.07 ± 0.77 cm, P = .04). There was no significant difference in aortic root pressures in the 2 groups. The rWSS was greater in AI patients (4.60 ± 5.70 vs 2.37 ± 1.20 dyne/cm 2 , P < .001). Qualitatively, we observed a trend of greater perturbations, regions of high rWSS, and flow eddies in the AI group., Conclusions: Using CFD simulations, we demonstrated that patients who developed de novo AI have greater rWSS at the aortic root, and their outflow grafts were placed closer to the aortic roots than those patients without de novo AI., (Copyright © 2020 The American Association for Thoracic Surgery. Published by Elsevier Inc. All rights reserved.)

Published

2021

2. Patient-Specific Computational Fluid Dynamics Reveal Localized Flow Patterns Predictive of Post-Left Ventricular Assist Device Aortic Incompetence.

Author

Shad R, Kaiser AD, Kong S, Fong R, Quach N, Bowles C, Kasinpila P, Shudo Y, Teuteberg J, Woo YJ, Marsden AL, and Hiesinger W

Subjects

Aortic Valve Insufficiency physiopathology, Computer Simulation, Heart Failure physiopathology, Hemodynamics physiology, Humans, Models, Cardiovascular, Stress, Mechanical, Ventricular Function, Left physiology, Aortic Valve physiopathology, Aortic Valve Insufficiency etiology, Heart Failure etiology, Heart-Assist Devices adverse effects

Abstract

Background: Progressive aortic valve disease has remained a persistent cause of concern in patients with left ventricular assist devices. Aortic incompetence (AI) is a known predictor of both mortality and readmissions in this patient population and remains a challenging clinical problem., Methods: Ten left ventricular assist device patients with de novo aortic regurgitation and 19 control left ventricular assist device patients were identified. Three-dimensional models of patients' aortas were created from their computed tomography scans, following which large-scale patient-specific computational fluid dynamics simulations were performed with physiologically accurate boundary conditions using the SimVascular flow solver., Results: The spatial distributions of time-averaged wall shear stress and oscillatory shear index show no significant differences in the aortic root in patients with and without AI (mean difference, 0.67 dyne/cm 2 [95% CI, -0.51 to 1.85]; P =0.23). Oscillatory shear index was also not significantly different between both groups of patients (mean difference, 0.03 [95% CI, -0.07 to 0.019]; P =0.22). The localized wall shear stress on the leaflet tips was significantly higher in the AI group than the non-AI group (1.62 versus 1.35 dyne/cm 2 ; mean difference [95% CI, 0.15-0.39]; P <0.001), whereas oscillatory shear index was not significantly different between both groups (95% CI, -0.009 to 0.001; P =0.17)., Conclusions: Computational fluid dynamics serves a unique role in studying the hemodynamic features in left ventricular assist device patients where 4-dimensional magnetic resonance imaging remains unfeasible. Contrary to the widely accepted notions of highly disturbed flow, in this study, we demonstrate that the aortic root is a region of relatively stagnant flow. We further identified localized hemodynamic features in the aortic root that challenge our understanding of how AI develops in this patient population.

Published

2021

3. Modeling conduit choice for valve-sparing aortic root replacement on biomechanics with a 3-dimensional-printed heart simulator.

Author

Paulsen MJ, Kasinpila P, Imbrie-Moore AM, Wang H, Hironaka CE, Koyano TK, Fong R, Chiu P, Goldstone AB, Steele AN, Stapleton LM, Ma M, and Woo YJ

Subjects

Animals, Aorta pathology, Aorta physiopathology, Aortic Valve pathology, Aortic Valve physiopathology, Biomechanical Phenomena, Coronary Circulation, Echocardiography, Transesophageal, Hemodynamics, Models, Anatomic, Sinus of Valsalva pathology, Sinus of Valsalva physiopathology, Sinus of Valsalva surgery, Swine, Vascular Grafting methods, Aorta surgery, Aortic Valve surgery, Printing, Three-Dimensional

Abstract

Objective: The optimal conduit for valve-sparing aortic root replacement is still debated, with several conduit variations available, ranging from straight tubular grafts to Valsalva grafts. Benefits of neosinus reconstruction include enhanced flow profiles and improved hemodynamics. Curiously, however, some clinical data suggest that straight grafts may have greater long-term durability. In this study, we hypothesized that straight tubular grafts may help maintain the native cylindrical position of the aortic valve commissures radially, resulting in preserved leaflet coaptation, reduced stresses, and potentially improved valve performance., Methods: Using 3D printing, a left heart simulator with a valve-sparing root replacement model and a physiologic coronary circulation was constructed. Aortic valves were dissected from fresh porcine hearts and reimplanted into either straight tubular grafts (n = 6) or Valsalva grafts (n = 6). Conduits were mounted into the heart simulator and hemodynamic, echocardiographic, and high-speed videometric data were collected., Results: Hemodynamic parameters and coronary blood flow were similar between straight and Valsalva grafts, although the former were associated with lower regurgitant fractions, less peak intercommissural radial separation, preserved leaflet coaptation, decreased leaflet velocities, and lower relative leaflet forces compared with Valsalva grafts., Conclusions: Valsalva grafts and straight grafts perform equally well in terms of gross hemodyanics and coronary blood flow. Interestingly, however, the biomechanics of these 2 conduits differ considerably, with straight grafts providing increased radial commissural stability and leaflet coaptation. Further investigation into how these parameters influence clinical outcomes is warranted., (Copyright © 2018 The American Association for Thoracic Surgery. Published by Elsevier Inc. All rights reserved.)

Published

2019