Accelerated Estimation of Pulmonary Artery Stenosis Pressure Gradients with Distributed Lumped Parameter Modeling Vs. 3D CFD with Instantaneous Adaptive Mesh Refinement: Experimental Validation in Swine

Overview

Journal Ann Biomed Eng

Specialty Biomedical Engineering

Date 2021 May 5

PMID 33948748

Citations 4

Authors

Ryan Pewowaruk

Luke Lamers

Alejandro Roldan-Alzate

Affiliations

Soon will be listed here.

Abstract

Branch pulmonary artery stenosis (PAS) commonly occurs in congenital heart disease and the pressure gradient over a stenotic PA lesion is an important marker for re-intervention. Image based computational fluid dynamics (CFD) has shown promise for non-invasively estimating pressure gradients but one limitation of CFD is long simulation times. The goal of this study was to compare accelerated predictions of PAS pressure gradients from 3D CFD with instantaneous adaptive mesh refinement (AMR) versus a recently developed 0D distributed lumped parameter CFD model. Predictions were then experimentally validated using a swine PAS model (n = 13). 3D CFD simulations with AMR improved efficiency by 5 times compared to fixed grid CFD simulations. 0D simulations further improved efficiency by 6 times compared to the 3D simulations with AMR. Both 0D and 3D simulations underestimated the pressure gradients measured by catheterization (- 1.87 ± 4.20 and - 1.78 ± 3.70 mmHg respectively). This was partially due to simulations neglecting the effects of a catheter in the stenosis. There was good agreement between 0D and 3D simulations (ICC 0.88 [0.66-0.96]) but only moderate agreement between simulations and experimental measurements (0D ICC 0.60 [0.11-0.86] and 3D ICC 0.66 [0.21-0.88]). Uncertainty assessment indicates that this was likely due to limited medical imaging resolution causing uncertainty in the segmented stenosis diameter in addition to uncertainty in the outlet resistances. This study showed that 0D lumped parameter models and 3D CFD with instantaneous AMR both improve the efficiency of hemodynamic modeling, but uncertainty from medical imaging resolution will limit the accuracy of pressure gradient estimations.

Citing Articles

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References

Davies G, Reid L . Growth of the alveoli and pulmonary arteries in childhood. Thorax. 1970; 25(6):669-81. PMC: 472209. DOI: 10.1136/thx.25.6.669. View

Updegrove A, Wilson N, Merkow J, Lan H, Marsden A, Shadden S . SimVascular: An Open Source Pipeline for Cardiovascular Simulation. Ann Biomed Eng. 2016; 45(3):525-541. PMC: 6546171. DOI: 10.1007/s10439-016-1762-8. View

Hislop A, Reid L . Pulmonary arterial development during childhood: branching pattern and structure. Thorax. 1973; 28(2):129-35. PMC: 470003. DOI: 10.1136/thx.28.2.129. View

Zambrano B, McLean N, Zhao X, Tan J, Zhong L, Figueroa C . Image-based computational assessment of vascular wall mechanics and hemodynamics in pulmonary arterial hypertension patients. J Biomech. 2018; 68:84-92. PMC: 5783768. DOI: 10.1016/j.jbiomech.2017.12.022. View

Rinaudo A, DAncona G, Baglini R, Amaducci A, Follis F, Pilato M . Computational fluid dynamics simulation to evaluate aortic coarctation gradient with contrast-enhanced CT. Comput Methods Biomech Biomed Engin. 2014; 18(10):1066-1071. DOI: 10.1080/10255842.2013.869321. View

Prakash S, Ethier C . Requirements for mesh resolution in 3D computational hemodynamics. J Biomech Eng. 2001; 123(2):134-44. DOI: 10.1115/1.1351807. View

Bley T, Johnson K, Francois C, Reeder S, Schiebler M, Landgraf B . Noninvasive assessment of transstenotic pressure gradients in porcine renal artery stenoses by using vastly undersampled phase-contrast MR angiography. Radiology. 2011; 261(1):266-73. PMC: 3184231. DOI: 10.1148/radiol.11101175. View

Itu L, Sharma P, Ralovich K, Mihalef V, Ionasec R, Everett A . Non-invasive hemodynamic assessment of aortic coarctation: validation with in vivo measurements. Ann Biomed Eng. 2012; 41(4):669-81. DOI: 10.1007/s10439-012-0715-0. View

Pewowaruk R, Hermsen J, Johnson C, Erdmann A, Pettit K, Aesif S . Pulmonary artery and lung parenchymal growth following early versus delayed stent interventions in a swine pulmonary artery stenosis model. Catheter Cardiovasc Interv. 2020; 96(7):1454-1464. PMC: 10831906. DOI: 10.1002/ccd.29326. View

10.

Johnson N, Kirkeeide R, Gould K . Coronary anatomy to predict physiology: fundamental limits. Circ Cardiovasc Imaging. 2013; 6(5):817-32. DOI: 10.1161/CIRCIMAGING.113.000373. View

11.

Hiremath G, Qureshi A, Prieto L, Nagaraju L, Moore P, Bergersen L . Balloon Angioplasty and Stenting for Unilateral Branch Pulmonary Artery Stenosis Improve Exertional Performance. JACC Cardiovasc Interv. 2019; 12(3):289-297. DOI: 10.1016/j.jcin.2018.11.042. View

12.

Taylor C, Fonte T, Min J . Computational fluid dynamics applied to cardiac computed tomography for noninvasive quantification of fractional flow reserve: scientific basis. J Am Coll Cardiol. 2013; 61(22):2233-41. DOI: 10.1016/j.jacc.2012.11.083. View

13.

Rhodes J, Dave A, Pulling M, Geggel R, Marx G, Fulton D . Effect of pulmonary artery stenoses on the cardiopulmonary response to exercise following repair of tetralogy of Fallot. Am J Cardiol. 1998; 81(10):1217-9. DOI: 10.1016/s0002-9149(98)00095-2. View

14.

Kheyfets V, Rios L, Smith T, Schroeder T, Mueller J, Murali S . Patient-specific computational modeling of blood flow in the pulmonary arterial circulation. Comput Methods Programs Biomed. 2015; 120(2):88-101. PMC: 4441565. DOI: 10.1016/j.cmpb.2015.04.005. View

15.

Faber M, Dalinghaus M, Lankhuizen I, Steendijk P, Hop W, Schoemaker R . Right and left ventricular function after chronic pulmonary artery banding in rats assessed with biventricular pressure-volume loops. Am J Physiol Heart Circ Physiol. 2006; 291(4):H1580-6. DOI: 10.1152/ajpheart.00286.2006. View

16.

Yang W, Hanley F, Chan F, Marsden A, Vignon-Clementel I, Feinstein J . Computational simulation of postoperative pulmonary flow distribution in Alagille patients with peripheral pulmonary artery stenosis. Congenit Heart Dis. 2017; 13(2):241-250. DOI: 10.1111/chd.12556. View

17.

Mynard J, Valen-Sendstad K . A unified method for estimating pressure losses at vascular junctions. Int J Numer Method Biomed Eng. 2015; 31(7):e02717. DOI: 10.1002/cnm.2717. View

18.

Vida V, Lo Rito M, Zucchetta F, Biffanti R, Padalino M, Milanesi O . Pulmonary artery branch stenosis in patients with congenital heart disease. J Card Surg. 2013; 28(4):439-45. DOI: 10.1111/jocs.12121. View

19.

Mirramezani M, Shadden S . A Distributed Lumped Parameter Model of Blood Flow. Ann Biomed Eng. 2020; 48(12):2870-2886. PMC: 7725998. DOI: 10.1007/s10439-020-02545-6. View

20.

Gatzoulis M, Balaji S, Webber S, Siu S, Hokanson J, Poile C . Risk factors for arrhythmia and sudden cardiac death late after repair of tetralogy of Fallot: a multicentre study. Lancet. 2000; 356(9234):975-81. DOI: 10.1016/S0140-6736(00)02714-8. View