Your search keyword '"Saw, Shier"' showing total 5 results

1. Differences in placental capillary shear stress in fetal growth restriction may affect endothelial cell function and vascular network formation.

Author

Tun WM, Yap CH, Saw SN, James JL, and Clark AR

Subjects

Female, Fetus blood supply, Fetus physiopathology, Humans, Neovascularization, Physiologic physiology, Pregnancy, Capillaries physiology, Endothelial Cells physiology, Fetal Growth Retardation physiopathology, Placenta blood supply, Shear Strength physiology

Abstract

Fetal growth restriction (FGR) affects 5-10% of pregnancies, leading to clinically significant fetal morbidity and mortality. FGR placentae frequently exhibit poor vascular branching, but the mechanisms driving this are poorly understood. We hypothesize that vascular structural malformation at the organ level alters microvascular shear stress, impairing angiogenesis. A computational model of placental vasculature predicted elevated placental micro-vascular shear stress in FGR placentae (0.2 Pa in severe FGR vs 0.05 Pa in normal placentae). Endothelial cells cultured under predicted FGR shear stresses migrated significantly slower and with greater persistence than in shear stresses predicted in normal placentae. These cell behaviors suggest a dominance of vessel elongation over branching. Taken together, these results suggest (1) poor vascular development increases vessel shear stress, (2) increased shear stress induces cell behaviors that impair capillary branching angiogenesis, and (3) impaired branching angiogenesis continues to drive elevated shear stress, jeopardizing further vascular formation. Inadequate vascular branching early in gestation could kick off this cyclic loop and continue to negatively impact placental angiogenesis throughout gestation.

Published

2019

2. Hyperelastic Mechanical Properties of Ex Vivo Normal and Intrauterine Growth Restricted Placenta.

Author

Saw SN, Low JYR, Ong MHH, Poh YW, Mattar CNZ, Biswas A, and Yap CH

Subjects

Adult, Female, Humans, Pregnancy, Elasticity Imaging Techniques, Fetal Growth Retardation diagnostic imaging, Fetal Growth Retardation physiopathology, Models, Biological, Placenta diagnostic imaging, Placenta physiopathology, Placental Insufficiency diagnostic imaging, Placental Insufficiency physiopathology

Abstract

Intrauterine Growth Restriction (IUGR) is a serious and prevalent pregnancy complication that is due to placental insufficiency and IUGR babies suffer significantly higher risks of mortality and morbidity. Current detection rate for IUGR is generally poor and thus an alternative diagnostic tool is needed to improve the IUGR detection. Elastography, a non-invasive method that measures the tissue stiffness, has been proposed as one such technique. However, to date, we have limited information on the mechanical properties of IUGR placenta. In this study, we investigated the mechanical properties of normal and IUGR placentae and prescribed a suitable hyperelastic model to describe their mechanical behaviors. A total of 46 normal and 43 IUGR placenta samples were investigated. Results showed that placenta samples were isotropic, but had a high spatial variability of stiffness. The samples also had significant viscoelasticity. IUGR placenta was observed to be slightly stiffer than normal placenta but the difference was significant only at compression rate of 0.25 Hz and with 20% compression depth. Three simple hyperelastic models-Yeoh, Ogden and Fung models, were found to be able to fit the experimentally measured mechanical behaviors, and Fung model performed slightly better. These results may be useful for optimizing placenta elastography for the detection of IUGR.

Published

2018

3. Mechanical testing and non-linear viscoelastic modelling of the human placenta in normal and growth restricted pregnancies.

Author

Lau JS, Saw SN, Buist ML, Biswas A, Zaini Mattar CN, and Yap CH

Subjects

Elasticity, Elasticity Imaging Techniques, Female, Humans, Models, Biological, Pregnancy, Viscosity, Fetal Growth Retardation physiopathology, Placenta physiology

Abstract

Background: Intrauterine Growth Restriction (IUGR) is a disease where the placenta is unable to transfer enough nutrients to the fetus, limiting its growth, and resulting in high mortality and life-long morbidities. Current detection rates of IUGR are poor, resulting in limited disease management. Elastography is a promising non-invasive tool for the detection of IUGR, and works by detecting changes in the mechanical properties of the placenta. To date, however, it is not known whether IUGR placentas have different mechanical properties from normal ones, and thus investigating this is the first focus of the current study. The second focus is to evaluate and model the viscoelastic properties of the normal and IUGR placenta, so that it may be possible to improve elastography in the future by incorporating viscoelasticity., Methods: Cyclic uniaxial mechanical compression testing was conducted on post-delivery human placenta samples. 18 samples from 5 normal placentae and 12 samples from 3 IUGR placentae were tested. Viscoelastic models were fitted to the resulting experimental data., Results: Mechanical testing showed that IUGR placentae have reduced stiffness and viscosity compared to normal placentae. Linear viscoelastic models were unable to provide a good fit to the data, but non-linear viscoelastic solid (NVS) models could do so. The best performing model was a five parameters bi-exponential NVS model. Two of the five parameters appear to capture the differences between normal and diseased samples., Discussion: Our results demonstrate that IUGR placentae have different mechanical properties from normal placentae, and a five parameter bi-exponential NVS model can effectively describe the mechanical properties of the placenta in health and disease., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2016

4. 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

5. Motorizing and Optimizing Ultrasound Strain Elastography for Detection of Intrauterine Growth Restriction Pregnancies.

Author

Saw, Shier Nee, Low, Jess Yi Ru, Yap, Choon Hwai, Mattar, Citra Nurfarah Zaini, Biswas, Arijit, and Chen, Lujie

Subjects

*ELASTOGRAPHY, *FETAL development, *ULTRASONIC imaging, *POLYVINYL alcohol, *REGRESSION analysis, *FETAL growth retardation, *COMPARATIVE studies, *RESEARCH methodology, *MEDICAL cooperation, *IMAGING phantoms, *PLACENTA, *PLACENTA diseases, *RESEARCH, *EVALUATION research, *DIAGNOSIS, RESEARCH evaluation

Abstract

Intrauterine growth restriction is a prevalent disease in pregnancy in which placental insufficiency leads to 5 to 10 times higher mortality and lifelong morbidities. The current detection rate is poor, and recently, ultrasound strain elastography (USEL) was proposed as a new diagnostic technique. Currently, placental USEL uses maternal subcutaneous fat as the reference layer, but this is not ideal as fat tissue stiffness can vary widely between subjects. Current USEL also uses manual palpation, and under different compression depths and rates, viscoelastic tissues such as placenta can yield different stiffness results. In the study described here, we strove to improve placental USEL by (i) using an external polymeric pad of known stiffness as the reference layer and (ii) adopting motorized control of the transducer during USEL to standardize palpation motion. Results indicated that motorized USEL reduced measurement variability by 67% compared with freehand USEL. Satisfactory and statistically significant correlations between USEL measurements and mechanical testing validation results were obtained for our new USEL protocol. Placental tissues were found to be non-linear and viscoelastic in nature and, thus, differed in stiffness at different compression rates and depths. Our study also revealed that there was a specific compression depth and rate during USEL that provided better correlation to mechanical testing, and should be considered in clinical placental USEL. [ABSTRACT FROM AUTHOR]

Published

2018