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200 results on '"Baek, Seungik"'

1. Rapid Estimation of Left Ventricular Contractility with a Physics-Informed Neural Network Inverse Modeling Approach

Author

Naghavi, Ehsan, Wang, Haifeng, Fan, Lei, Choy, Jenny S., Kassab, Ghassan, Baek, Seungik, and Lee, Lik-Chuan

Subjects
Computer Science - Computational Engineering, Finance, and Science
Abstract

Physics-based computer models based on numerical solution of the governing equations generally cannot make rapid predictions, which in turn, limits their applications in the clinic. To address this issue, we developed a physics-informed neural network (PINN) model that encodes the physics of a closed-loop blood circulation system embedding a left ventricle (LV). The PINN model is trained to satisfy a system of ordinary differential equations (ODEs) associated with a lumped parameter description of the circulatory system. The model predictions have a maximum error of less than 5% when compared to those obtained by solving the ODEs numerically. An inverse modeling approach using the PINN model is also developed to rapidly estimate model parameters (in $\sim$ 3 mins) from single-beat LV pressure and volume waveforms. Using synthetic LV pressure and volume waveforms generated by the PINN model with different model parameter values, we show that the inverse modeling approach can recover the corresponding ground truth values, which suggests that the model parameters are unique. The PINN inverse modeling approach is then applied to estimate LV contractility indexed by the end-systolic elastance $E_{es}$ using waveforms acquired from 11 swine models, including waveforms acquired before and after administration of dobutamine (an inotropic agent) in 3 animals. The estimated $E_{es}$ is about 58% to 284% higher for the data associated with dobutamine compared to those without, which implies that this approach can be used to estimate LV contractility using single-beat measurements. The PINN inverse modeling can potentially be used in the clinic to simultaneously estimate LV contractility and other physiological parameters from single-beat measurements.

Published
2024
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5. A Multiscale Framework for Defining Homeostasis in Distal Vascular Trees: Applications to the Pulmonary Circulation

Author

Filonova, Vasilina, Gharahi, Hamidreza, Nama, Nitesh, Baek, Seungik, and Figueroa, C. Alberto

Subjects
Physics - Biological Physics
Abstract

Coupling hemodynamics with vessel wall growth and remodeling (G&R) is crucial for understanding pathology at distal vasculature to study progression of incurable vascular diseases, such as pulmonary arterial hypertension. The present study is the first modeling attempt that focuses on defining homeostatic baseline values in distal pulmonary vascular bed via, a so-called, homeostatic optimization. To define the vascular homeostasis and total hemodynamics in the vascular tree, we consider two time-scales: a cardiac cycle and a longer period of vascular adaptations. An iterative homeostatic optimization is performed at the slow-time scale and incorporates: an extended Murray's law, wall metabolic cost function, stress equilibrium, and hemodynamics. The pulmonary arterial network of small vessels is represented by a fractal bifurcating tree. The pulsatile blood flow is described by a Womersley's deformable wall analytical solution. A vessel wall mechanical response is described by the constrained mixture theory for an orthotropic membrane and then linearized around mean pressure. Wall material parameters are characterized by using available porcine pulmonary artery experiments and human data from literature. Illustrative examples for symmetric and asymmetric fractal trees are presented to provide homeostatic values in normal subjects. We also outline the key ideas for the derivation of a temporal multiscale formalism to justify the proposed one-way coupled system of governing equations and identify the inherent assumptions. The developed framework demonstrates a potential for advanced parametric studies and future G&R and hemodynamics modeling in pulmonary arterial hypertension., Comment: 35 pages, 16 figures

Published
2020

21. Data-driven computational models of ventricular-arterial hemodynamics in pediatric pulmonary arterial hypertension

Author

Tossas-Betancourt, Christopher, primary, Li, Nathan Y., additional, Shavik, Sheikh M., additional, Afton, Katherine, additional, Beckman, Brian, additional, Whiteside, Wendy, additional, Olive, Mary K., additional, Lim, Heang M., additional, Lu, Jimmy C., additional, Phelps, Christina M., additional, Gajarski, Robert J., additional, Lee, Simon, additional, Nordsletten, David A., additional, Grifka, Ronald G., additional, Dorfman, Adam L., additional, Baek, Seungik, additional, Lee, Lik Chuan, additional, and Figueroa, C. Alberto, additional

Published
2022
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35. CRIMSON: An open-source software framework for cardiovascular integrated modelling and simulation

Author

Arthurs, Christopher J., primary, Khlebnikov, Rostislav, additional, Melville, Alex, additional, Marčan, Marija, additional, Gomez, Alberto, additional, Dillon-Murphy, Desmond, additional, Cuomo, Federica, additional, Silva Vieira, Miguel, additional, Schollenberger, Jonas, additional, Lynch, Sabrina R., additional, Tossas-Betancourt, Christopher, additional, Iyer, Kritika, additional, Hopper, Sara, additional, Livingston, Elizabeth, additional, Youssefi, Pouya, additional, Noorani, Alia, additional, Ben Ahmed, Sabrina, additional, Nauta, Foeke J. H., additional, van Bakel, Theodorus M. J., additional, Ahmed, Yunus, additional, van Bakel, Petrus A. J., additional, Mynard, Jonathan, additional, Di Achille, Paolo, additional, Gharahi, Hamid, additional, Lau, Kevin D., additional, Filonova, Vasilina, additional, Aguirre, Miquel, additional, Nama, Nitesh, additional, Xiao, Nan, additional, Baek, Seungik, additional, Garikipati, Krishna, additional, Sahni, Onkar, additional, Nordsletten, David, additional, and Figueroa, C. Alberto, additional

Published
2021
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44. Association of vortical structures and hemodynamic parameters for regional thrombus accumulation in abdominal aortic aneurysms.

Author

Zambrano, Byron A., Gharahi, Hamidreza, Lim, Chae Young, Lee, Whal, and Baek, Seungik

Subjects
ABDOMINAL aortic aneurysms, THROMBOSIS, HEMODYNAMICS, SHEARING force, INVERSE relationships (Mathematics), CLIMACTERIC
Abstract

The intraluminal thrombus (ILT) has been shown to negatively impact the progression of the abdominal aortic aneurysms (AAAs). The formation of this thrombus layer has been connected to the local flow environment within AAAs, but the specific mechanisms leading to thrombus formation are still not fully understood. Our study investigated the association between vortical structures, near‐wall hemodynamic metrics (e.g., time averaged wall shear stress (TAWSS) and oscillatory shear index (OSI)), and ILT accumulation in a longitudinal cohort of 14 AAAs (53 scans total). Vortices and hemodynamic parameters were estimated using hemodynamic simulations performed to each scan of each patient and compared to local 3D changes of ILT thickness between two consecutive scans (ΔILT). Results showed that vortices formed and remained strong and close to the lumen surface in AAAs without an ILT, while in AAAs with ILTs these detached from the lumen surface and dissipated nearby wall region where an increase in ILT thickness was observed. Although low TAWSS was observed in regions with and without ILT accumulation, an inverse correlation between ∆ILT and TAWSS was observed within the regions that experienced a thrombus growth. Our results support the idea that vortical structures might be playing a role modulating ILT accumulation into specific wall regions. Also, it submits the idea that the low TAWSS will be modulating the growth of thrombus within these preferred ILT accumulated regions. [ABSTRACT FROM AUTHOR]

Published
2022
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50. Potential damage in pulmonary arterial hypertension: An experimental study of pressure‐induced damage of pulmonary artery.

Author

Wang, Yuheng, Gharahi, Hamidreza, Grobbel, Marissa R., Rao, Akshay, Roccabianca, Sara, and Baek, Seungik

Abstract

Pulmonary arterial hypertension (PAH) is associated with elevated pulmonary arterial pressure. PAH prognosis remains poor with a 15% mortality rate within 1 year, even with modern clinical management. Previous clinical studies proposed wall shear stress (WSS) to be an important hemodynamic factor affecting cell mechanotransduction, growth and remodeling, and disease progress in PAH. However, WSS in vivo is typically at most 2.5 Pa and a doubt has been cast whether WSS alone can drive disease progress. Furthermore, our current understanding of PAH pathology largely comes from small animals' studies in which caliber enlargement, a hallmark of PAH in humans, is rarely reported. Therefore, a large‐animal experiment on pulmonary arteries (PAs) is needed to validate whether increased pressure can induce enlargement of PAs caliber. In this study, we use an inflation testing device to characterize the mechanical behavior, both nonlinear elastic behavior and irreversible damage of porcine arteries. The parameters of elastic behavior are estimated from the inflation test at a low‐pressure range before and after over‐pressurization. Then, histological images are qualitatively examined for medial and adventitial layers. This study sheds light on the relevance of pressure‐induced damage mechanism in human PAH. [ABSTRACT FROM AUTHOR]

Published
2021
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