Your search keyword '"Yap, Choon"' showing total 12 results

1. Fluid Mechanical Effects of Fetal Aortic Valvuloplasty for Cases of Critical Aortic Stenosis with Evolving Hypoplastic Left Heart Syndrome

Author

Wong, Hong Shen, Li, Binghuan, Tulzer, Andreas, Tulzer, Gerald, and Yap, Choon Hwai

Published

2023

2. Fluid Mechanics of Fetal Left Ventricle During Aortic Stenosis with Evolving Hypoplastic Left Heart Syndrome

Author

Wong, Hong Shen, Wiputra, Hadi, Tulzer, Andreas, Tulzer, Gerald, and Yap, Choon Hwai

Published

2022

3. Fluid mechanics of the left atrial ligation chick embryonic model of hypoplastic left heart syndrome

Author

Ho, Sheldon, Chan, Wei Xuan, and Yap, Choon Hwai

Published

2021

4. Peristaltic-Like Motion of the Human Fetal Right Ventricle and its Effects on Fluid Dynamics and Energy Dynamics

Author

Wiputra, Hadi, Lim, Guat Ling, Chua, Khong Chun, Nivetha, R., Soomar, Sanah Merchant, Biwas, Arijit, Mattar, Citra Nurfarah Zaini, Leo, Hwa Liang, and Yap, Choon Hwai

Published

2017

5. In Vitro Characterization of Bicuspid Aortic Valve Hemodynamics Using Particle Image Velocimetry

Author

Saikrishnan, Neelakantan, Yap, Choon-Hwai, Milligan, Nicole C., Vasilyev, Nikolay V., and Yoganathan, Ajit P.

Published

2012

6. Fluid mechanics of the zebrafish embryonic heart trabeculation.

Author

Cairelli, Adriana Gaia, Chow, Renee Wei-Yan, Vermot, Julien, and Yap, Choon Hwai

Subjects

FLUID mechanics, HIGH resolution imaging, COMPUTATIONAL fluid dynamics, BRACHYDANIO, HEART development

Abstract

Embryonic heart development is a mechanosensitive process, where specific fluid forces are needed for the correct development, and abnormal mechanical stimuli can lead to malformations. It is thus important to understand the nature of embryonic heart fluid forces. However, the fluid dynamical behaviour close to the embryonic endocardial surface is very sensitive to the geometry and motion dynamics of fine-scale cardiac trabecular surface structures. Here, we conducted image-based computational fluid dynamics (CFD) simulations to quantify the fluid mechanics associated with the zebrafish embryonic heart trabeculae. To capture trabecular geometric and motion details, we used a fish line that expresses fluorescence at the endocardial cell membrane, and high resolution 3D confocal microscopy. Our endocardial wall shear stress (WSS) results were found to exceed those reported in existing literature, which were estimated using myocardial rather than endocardial boundaries. By conducting simulations of single intra-trabecular spaces under varied scenarios, where the translational or deformational motions (caused by contraction) were removed, we found that a squeeze flow effect was responsible for most of the WSS magnitude in the intra-trabecular spaces, rather than the shear interaction with the flow in the main ventricular chamber. We found that trabecular structures were responsible for the high spatial variability of the magnitude and oscillatory nature of WSS, and for reducing the endocardial deformational burden. We further found cells attached to the endocardium within the intra-trabecular spaces, which were likely embryonic hemogenic cells, whose presence increased endocardial WSS. Overall, our results suggested that a complex multi-component consideration of both anatomic features and motion dynamics were needed to quantify the trabeculated embryonic heart fluid mechanics. Author summary: In the embryonic heart, the mechanical forces that blood fluid imposes on the cardiac tissues are known to be important biological stimuli that affect the proper heart development. We thus perform careful quantification of these forces, using the zebrafish embryo as a model. To do this, we perform high resolution imaging of zebrafish embryonic hearts and image-based flow simulations. We find that the use of a particular fish line that expresses fluorescence at the exact boundary between heart tissue and blood, that is the endocardial cell membrane boundary, is important to give high quality results. The heart's inner surface has uneven trabeculation structures. We find that they cause fluid forces to have spatial variability and an oscillatory nature. We also find that there is a squeezing motion of cardiac tissues on the trabeculation fluid spaces, which is the main mechanism that generated fluid forces. Fluid forces are also affected by a number of cardiac cells that were developing into blood cells, lodged in the trabeculation fluid spaces. Our investigations provide an understanding of the complexity of the fluid forces on the inner surface of the embryonic heart, and our quantifications will be useful to future studies on the biology elicited by these fluid forces. [ABSTRACT FROM AUTHOR]

Published

2022

7. A Review of Biomechanics Analysis of the Umbilical–Placenta System With Regards to Diseases.

Author

Saw, Shier Nee, Dai, Yichen, and Yap, Choon Hwai

Subjects

FETAL growth retardation, BIOMECHANICS, UMBILICAL cord, TISSUE mechanics, ULTRASONIC imaging

Abstract

Placenta is an important organ that is crucial for both fetal and maternal health. Abnormalities of the placenta, such as during intrauterine growth restriction (IUGR) and pre-eclampsia (PE) are common, and an improved understanding of these diseases is needed to improve medical care. Biomechanics analysis of the placenta is an under-explored area of investigation, which has demonstrated usefulness in contributing to our understanding of the placenta physiology. In this review, we introduce fundamental biomechanics concepts and discuss the findings of biomechanical analysis of the placenta and umbilical cord, including both tissue biomechanics and biofluid mechanics. The biomechanics of placenta ultrasound elastography and its potential in improving clinical detection of placenta diseases are also discussed. Finally, potential future work is listed. [ABSTRACT FROM AUTHOR]

Published

2021

8. 4D modelling of fluid mechanics in the zebrafish embryonic heart.

Author

Foo, Yoke Yin, Pant, Shilpa, Tay, Huiping Shermaine, Imangali, Nurgul, Chen, Nanguang, Winkler, Christoph, and Yap, Choon Hwai

Subjects

HEART ventricles, COMPUTATIONAL fluid dynamics, FLUID mechanics, SHEARING force, HEART, REYNOLDS number

Abstract

Abnormal blood flow mechanics can result in pathological heart malformation, underlining the importance of understanding embryonic cardiac fluid mechanics. In the current study, we performed image-based computational fluid dynamics simulation of the zebrafish embryonic heart ventricles and characterized flow mechanics, organ dynamics, and energy dynamics in detail. 4D scans of 5 days post-fertilization embryonic hearts with GFP-labelled myocardium were acquired using line-scan focal modulation microscopy. This revealed that the zebrafish hearts exhibited a wave-like contractile/relaxation motion from the inlet to the outlet during both systole and diastole, which we showed to be an energy efficient configuration. No impedance pumping effects of pressure and velocity waves were observed. Due to its tube-like configuration, inflow velocities were higher near the inlet and smaller at the outlet and vice versa for outflow velocities. This resulted in an interesting spatial wall shear stress (WSS) pattern where WSS waveforms near the inlet and those near the outlet were out of phase. There was large spatial variability in WSS magnitudes. Peak WSS was in the range of 47.5–130 dyne/cm2 at the inflow and outflow tracts, but were much smaller, in the range of 4–11 dyne/cm2, in the mid-ventricular segment. Due to very low Reynolds number and the highly viscous environment, intraventricular pressure gradients were high, suggesting substantial energy losses of flow through the heart. [ABSTRACT FROM AUTHOR]

Published

2020

9. Changes to the geometry and fluid mechanics of the carotid siphon in the pediatric Moyamoya disease.

Author

Jamil, Muhammad, Tan, Germaine Xin Yi, Huq, Mehnaz, Kang, Heidi, Lee, Zhi Rui, Tang, Phua Hwee, Hu, Xi Hong, and Yap, Choon Hwai

Subjects

MOYAMOYA disease, CEREBROVASCULAR disease, CAROTID artery, FLUID mechanics, PROGNOSIS, MAGNETIC resonance angiography

Abstract

Background:The Moyamoya disease is a cerebrovascular disease that causes occlusion of the distal end of the internal carotid artery, leading to the formation of multiple tiny collateral arteries. To date, the pathogenesis of Moyamoya is unknown. Improved understanding of the changes to vascular geometry and fluid mechanics of the carotid siphon during disease may improve understanding of the pathogenesis, prognosis techniques and disease management.Methods:A retrospective analysis of Magnetic Resonance Angiography (MRA) images was performed for Moyamoya pediatric patients (MMD) (n = 23) and control (Ctrl) pediatric patients (n = 20). The Ctrl group was composed of patients who complained of headache and had normal MRA. We performed segmentation of MRA images to quantify geometric parameters of the artery. Computational fluid dynamics (CFD) was performed to quantify the hemodynamic parameters.Results:MMD internal carotid and carotid siphons were smaller in cross-sectional areas, and shorter in curved vascular length. Vascular curvature remained constant over age and vascular size and did not change between Ctrl and MMD, but MMD carotid siphon had lower tortuosity in the posterior bend, and higher torsion in the anterior bend. Wall shear stress and secondary flows were significantly lower in MMD, but the ratio of secondary flow kinetic energy to primary flow kinetic energy were similar between MMD and Ctrl.Conclusion:There were alterations to both the geometry and the flow mechanics of the carotid siphons of Moyamoya patients but it is unclear whether hemodynamics is the cause or the effect of morphological changes observed. [ABSTRACT FROM PUBLISHER]

Published

2016

10. Fluid mechanics of blood flow in human fetal left ventricles based on patient-specific 4D ultrasound scans.

Author

Lai, Chang, Lim, Guat, Jamil, Muhammad, Mattar, Citra, Biswas, Arijit, and Yap, Choon

Subjects

FLUID mechanics, BLOOD flow, LEFT heart ventricle, FETAL echocardiography, CONGENITAL heart disease, CARDIAC arrest in children, SIMULATION methods & models, PROGNOSIS

Abstract

The mechanics of intracardiac blood flow and the epigenetic influence it exerts over the heart function have been the subjects of intense research lately. Fetal intracardiac flows are especially useful for gaining insights into the development of congenital heart diseases, but have not received due attention thus far, most likely because of technical difficulties in collecting sufficient intracardiac flow data in a safe manner. Here, we circumvent such obstacles by employing 4D STIC ultrasound scans to quantify the fetal heart motion in three normal 20-week fetuses, subsequently performing 3D computational fluid dynamics simulations on the left ventricles based on these patient-specific heart movements. Analysis of the simulation results shows that there are significant differences between fetal and adult ventricular blood flows which arise because of dissimilar heart morphology, E/A ratio, diastolic-systolic duration ratio, and heart rate. The formations of ventricular vortex rings were observed for both E- and A-wave in the flow simulations. These vortices had sufficient momentum to last until the end of diastole and were responsible for generating significant wall shear stresses on the myocardial endothelium, as well as helicity in systolic outflow. Based on findings from previous studies, we hypothesized that these vortex-induced flow properties play an important role in sustaining the efficiency of diastolic filling, systolic pumping, and cardiovascular flow in normal fetal hearts. [ABSTRACT FROM AUTHOR]

Published

2016

11. Characterizaton of the Vessel Geometry, Flow Mechanics and Wall Shear Stress in the Great Arteries of Wildtype Prenatal Mouse.

Author

Yap, Choon Hwai, Liu, Xiaoqin, and Pekkan, Kerem

Subjects

*SHEARING force, *FLUID mechanics, *ARTERIES, *CARDIOVASCULAR system physiology, *HEART diseases, *HEMODYNAMICS, *LABORATORY mice

Abstract

Introduction: Abnormal fluid mechanical environment in the pre-natal cardiovascular system is hypothesized to play a significant role in causing structural heart malformations. It is thus important to improve our understanding of the prenatal cardiovascular fluid mechanical environment at multiple developmental time-points and vascular morphologies. We present such a study on fetal great arteries on the wildtype mouse from embryonic day 14.5 (E14.5) to near-term (E18.5). Methods: Ultrasound bio-microscopy (UBM) was used to measure blood velocity of the great arteries. Subsequently, specimens were cryo-embedded and sectioned using episcopic fluorescent image capture (EFIC) to obtain high-resolution 2D serial image stacks, which were used for 3D reconstructions and quantitative measurement of great artery and aortic arch dimensions. EFIC and UBM data were input into subject-specific computational fluid dynamics (CFD) for modeling hemodynamics. Results: In normal mouse fetuses between E14.5–18.5, ultrasound imaging showed gradual but statistically significant increase in blood velocity in the aorta, pulmonary trunk (with the ductus arteriosus), and descending aorta. Measurement by EFIC imaging displayed a similar increase in cross sectional area of these vessels. However, CFD modeling showed great artery average wall shear stress and wall shear rate remain relatively constant with age and with vessel size, indicating that hemodynamic shear had a relative constancy over gestational period considered here. Conclusion: Our EFIC-UBM-CFD method allowed reasonably detailed characterization of fetal mouse vascular geometry and fluid mechanics. Our results suggest that a homeostatic mechanism for restoring vascular wall shear magnitudes may exist during normal embryonic development. We speculate that this mechanism regulates the growth of the great vessels. [ABSTRACT FROM AUTHOR]

Published

2014

12. Role of diastolic vortices in flow and energy dynamics during systolic ejection.

Author

Vasudevan, Vivek, Low, Adriel Jia Jun, Annamalai, Sarayu Parimal, Sampath, Smita, Chin, Chih-Liang, Ali, Asad Abu Bakar, and Yap, Choon Hwai

Subjects

*DIASTOLE (Cardiac cycle), *COMPUTATIONAL fluid dynamics, *KINETIC energy, *FLUID dynamics, *MITRAL valve, *FLUID mechanics

Abstract

MRI-based computational fluid dynamics simulations were performed in the left ventricles of two adult porcine subjects with varying physiological states (before and after an induced infarction). The hypothesis that diastolic vortices store kinetic energy and assist systolic ejection was tested, by performing systolic simulations in the presence and absence of diastolic vortices. The latter was achieved by reinitializing the entire velocity field to be zero at the beginning of systole. A rudimentary prescribed motion model of a mitral valve was included in the simulations to direct the incoming mitral jet towards the apex. Results showed that the presence or absence of diastolic vortex rings had insignificant impact on the energy expended by walls of the left ventricles for systolic ejection for both the porcine subjects, under all physiological conditions. Although substantial kinetic energy was stored in diastolic vortices by end diastole, it provided no appreciable savings during systolic ejection, and most likely continued to complete dissipation during systole. The role of diastolic vortices in apical washout was investigated by studying the cumulative mass fraction of passive dye that was ejected during systole in the presence and absence of vortices. Results indicated that the diastolic vortices play a crucial role in ensuring efficient washout of apical blood during systolic ejection. [ABSTRACT FROM AUTHOR]

Published

2019