Publications by authors named "Ricardo Gomez Bardon"
Article Synopsis
- The study highlights the limitations of treating blood as a single-phase fluid in simulations, noting that hematocrit heterogeneity is present during blood flow in fiber bundles of oxygenators.
- A two-phase blood model based on the Eulerian-Eulerian approach was developed to accurately predict RBC distribution and phase separation, utilizing data from previous microfluidic experiments.
- The model successfully demonstrated the ability to analyze hematocrit patterns linked to fiber bundle structures, providing insights for optimizing gas transfer in blood oxygenation processes.
Fibro-calcific aortic valve (AV) diseases are characterized by calcium growth or accumulation of fibrosis in the AV tissues. Fibrocalcific aortic stenosis (FAS) rises specifically in females, like calcification-induced aortic stenosis (CAS), may eventually necessitate valve replacement. Fluid-structure-interaction (FSI) computational models for severe CAS and FAS patients were developed using lattice Boltzmann method and multi-scale finite elements (FE).
View Article and Find Full Text PDFThe lattice Boltzmann method (LBM) has been increasingly used as a stand-alone CFD solver in various biomechanical applications. This study proposes a new fluid-structure interaction (FSI) co-modeling framework for the hemodynamic-structural analysis of compliant aortic valves. Toward that goal, two commercial software packages are integrated using the lattice Boltzmann (LBM) and finite element (FE) methods.
View Article and Find Full Text PDFClinical observation of condensation at the gas flow exit of blood oxygenators is a recurrent event during cardiopulmonary bypass. These devices consist of a bundle of hollow fibers made of a microporous membrane that allows the exchange of O and CO . The fibers carry a gas mixture inside (intraluminal flow), while blood flows externally around them (extraluminal flow).
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