Your search keyword '"Alice C Pong"' showing total 5 results

1. Development of acute hydrocephalus does not change brain tissue mechanical properties in adult rats, but in juvenile rats.

Author

Alice C Pong, Lauriane Jugé, Lynne E Bilston, and Shaokoon Cheng

Subjects

Medicine, Science

Abstract

Regional changes in brain stiffness were previously demonstrated in an experimental obstructive hydrocephalus juvenile rat model. The open cranial sutures in the juvenile rats have influenced brain compression and mechanical properties during hydrocephalus development and the extent by which closed cranial sutures in adult hydrocephalic rat models affect brain stiffness in-vivo remains unclear. The aims of this study were to determine changes in brain tissue mechanical properties and brain structure size during hydrocephalus development in adult rat with fixed cranial volume and how these changes were related to brain tissue deformation.Hydrocephalus was induced in 9 female ten weeks old Sprague-Dawley rats by injecting 60 μL of a kaolin suspension (25%) into the cisterna magna under anaesthesia. 6 sham-injected age-matched female SD rats were used as controls. MR imaging (9.4T, Bruker) was performed 1 day before and then at 3 days post injection. T2-weighted anatomical MR images were collected to quantify ventricle and brain tissue cross-sectional areas. MR elastography (800 Hz) was used to measure the brain stiffness (G*, shear modulus).Brain tissue in the adult hydrocephalic rats was more compressed than the juvenile hydrocephalic rats because the skulls of the adult hydrocephalic rats were unable to expand like the juvenile rats. In the adult hydrocephalic rats, the cortical gray matter thickness and the caudate-putamen cross-sectional area decreased (Spearman, P < 0.001 for both) but there were no significant changes in cranial cross-sectional area (Spearman, P = 0.35), cortical gray matter stiffness (Spearman, P = 0.24) and caudate-putamen (Spearman, P = 0.11) stiffness. No significant changes in the size of brain structures were observed in the controls.This study showed that although brain tissue in the adult hydrocephalic rats was severely compressed, their brain tissue stiffness did not change significantly. These results are in contrast with our previous findings in juvenile hydrocephalic rats which had significantly less brain compression (as the brain circumference was able to stretch with the cranium due to the open skull sutures) and had a significant increase in caudate putamen stiffness. These results suggest that change in brain mechanical properties in hydrocephalus is complex and is not solely dependent on brain tissue deformation. Further studies on the interactions between brain tissue stiffness, deformation, tissue oedema and neural damage are necessary before MRE can be used as a tool to track changes in brain biomechanics in hydrocephalus.

Published

2017

2. Changes in Rat Brain Tissue Microstructure and Stiffness during the Development of Experimental Obstructive Hydrocephalus.

Author

Lauriane Jugé, Alice C Pong, Andre Bongers, Ralph Sinkus, Lynne E Bilston, and Shaokoon Cheng

Subjects

Medicine, Science

Abstract

Understanding neural injury in hydrocephalus and how the brain changes during the course of the disease in-vivo remain unclear. This study describes brain deformation, microstructural and mechanical properties changes during obstructive hydrocephalus development in a rat model using multimodal magnetic resonance (MR) imaging. Hydrocephalus was induced in eight Sprague-Dawley rats (4 weeks old) by injecting a kaolin suspension into the cisterna magna. Six sham-injected rats were used as controls. MR imaging (9.4T, Bruker) was performed 1 day before, and at 3, 7 and 16 days post injection. T2-weighted MR images were collected to quantify brain deformation. MR elastography was used to measure brain stiffness, and diffusion tensor imaging (DTI) was conducted to observe brain tissue microstructure. Results showed that the enlargement of the ventricular system was associated with a decrease in the cortical gray matter thickness and caudate-putamen cross-sectional area (P < 0.001, for both), an alteration of the corpus callosum and periventricular white matter microstructure (CC+PVWM) and rearrangement of the cortical gray matter microstructure (P < 0.001, for both), while compression without gross microstructural alteration was evident in the caudate-putamen and ventral internal capsule (P < 0.001, for both). During hydrocephalus development, increased space between the white matter tracts was observed in the CC+PVWM (P < 0.001), while a decrease in space was observed for the ventral internal capsule (P < 0.001). For the cortical gray matter, an increase in extracellular tissue water was significantly associated with a decrease in tissue stiffness (P = 0.001). To conclude, this study characterizes the temporal changes in tissue microstructure, water content and stiffness in different brain regions and their association with ventricular enlargement. In summary, whilst diffusion changes were larger and statistically significant for majority of the brain regions studied, the changes in mechanical properties were modest. Moreover, the effect of ventricular enlargement is not limited to the CC+PVWM and ventral internal capsule, the extent of microstructural changes vary between brain regions, and there is regional and temporal variation in brain tissue stiffness during hydrocephalus development.

Published

2016

3. Longitudinal measurements of postnatal rat brain mechanical properties in-vivo

Author

Lynne E. Bilston, Lauriane Jugé, Alice C. Pong, and Shaokoon Cheng

Subjects

Male, Aging, medicine.medical_specialty, Pathology, Rat model, Biomedical Engineering, Biophysics, Cell Count, Brain tissue, 030218 nuclear medicine & medical imaging, Rats, Sprague-Dawley, 03 medical and health sciences, 0302 clinical medicine, In vivo, Internal medicine, Cell density, Sprague dawley rats, Animals, Medicine, Orthopedics and Sports Medicine, medicine.diagnostic_test, Viscosity, business.industry, Rehabilitation, Brain, Magnetic resonance imaging, Rat brain, Magnetic Resonance Imaging, Elasticity, Rats, Magnetic resonance elastography, Endocrinology, Animals, Newborn, Linear Models, Elasticity Imaging Techniques, Female, business, 030217 neurology & neurosurgery

Abstract

Information on pediatric brain tissue mechanical properties and, more pertinently, how they change during postnatal development remains scarce despite its importance to investigate mechanisms of neural injury. The aim of this study is to determine whether brain mechanical properties change in-vivo during early postnatal development in a rat model. Rat brain viscoelastic properties were measured longitudinally in ten healthy Sprague Dawley rats at five different time points from postnatal week one to week six using magnetic resonance elastography at 800Hz. Myelination and cell density were assessed histologically at the same time points to understand how the underlying tissue microstructure may be associated with changes in mechanical properties at different brain regions. Longitudinal changes in each variable were assessed using a generalized linear model with pairwise comparisons of means between weeks. The brain shear modulus in the cortical gray matter at postnatal week one was 6.3±0.4kPa, and increased significantly from week one to week two (pairwise comparison, p

Published

2016

4. Development of acute hydrocephalus does not change brain tissue mechanical properties in adult rats, but in juvenile rats

Author

Lynne E. Bilston, Lauriane Jugé, Shaokoon Cheng, and Alice C. Pong

Subjects

Central Nervous System, Aging, lcsh:Medicine, Brain tissue, Cisterna magna, Nervous System, 030218 nuclear medicine & medical imaging, Stiffness, Diagnostic Radiology, Rats, Sprague-Dawley, 0302 clinical medicine, Medicine and Health Sciences, lcsh:Science, Mammals, Brain Diseases, Multidisciplinary, medicine.diagnostic_test, Physics, Radiology and Imaging, Biomechanics, Classical Mechanics, Brain, Anatomy, Animal Models, Magnetic Resonance Imaging, Deformation, medicine.anatomical_structure, Neurology, Experimental Organism Systems, Physical Sciences, Vertebrates, Acute Disease, Female, Elastography, Research Article, Hydrocephalus, Imaging Techniques, Materials Science, Material Properties, Research and Analysis Methods, Rodents, 03 medical and health sciences, Model Organisms, Diagnostic Medicine, medicine, Juvenile, Mechanical Properties, Animals, Damage Mechanics, business.industry, lcsh:R, Organisms, Biology and Life Sciences, Magnetic resonance imaging, medicine.disease, Rats, Ventricle, Amniotes, lcsh:Q, business, 030217 neurology & neurosurgery

Abstract

INTRODUCTION Regional changes in brain stiffness were previously demonstrated in an experimental obstructive hydrocephalus juvenile rat model. The open cranial sutures in the juvenile rats have influenced brain compression and mechanical properties during hydrocephalus development and the extent by which closed cranial sutures in adult hydrocephalic rat models affect brain stiffness in-vivo remains unclear. The aims of this study were to determine changes in brain tissue mechanical properties and brain structure size during hydrocephalus development in adult rat with fixed cranial volume and how these changes were related to brain tissue deformation. METHODS Hydrocephalus was induced in 9 female ten weeks old Sprague-Dawley rats by injecting 60 μL of a kaolin suspension (25%) into the cisterna magna under anaesthesia. 6 sham-injected age-matched female SD rats were used as controls. MR imaging (9.4T, Bruker) was performed 1 day before and then at 3 days post injection. T2-weighted anatomical MR images were collected to quantify ventricle and brain tissue cross-sectional areas. MR elastography (800 Hz) was used to measure the brain stiffness (G*, shear modulus). RESULTS Brain tissue in the adult hydrocephalic rats was more compressed than the juvenile hydrocephalic rats because the skulls of the adult hydrocephalic rats were unable to expand like the juvenile rats. In the adult hydrocephalic rats, the cortical gray matter thickness and the caudate-putamen cross-sectional area decreased (Spearman, P < 0.001 for both) but there were no significant changes in cranial cross-sectional area (Spearman, P = 0.35), cortical gray matter stiffness (Spearman, P = 0.24) and caudate-putamen (Spearman, P = 0.11) stiffness. No significant changes in the size of brain structures were observed in the controls. CONCLUSIONS This study showed that although brain tissue in the adult hydrocephalic rats was severely compressed, their brain tissue stiffness did not change significantly. These results are in contrast with our previous findings in juvenile hydrocephalic rats which had significantly less brain compression (as the brain circumference was able to stretch with the cranium due to the open skull sutures) and had a significant increase in caudate putamen stiffness. These results suggest that change in brain mechanical properties in hydrocephalus is complex and is not solely dependent on brain tissue deformation. Further studies on the interactions between brain tissue stiffness, deformation, tissue oedema and neural damage are necessary before MRE can be used as a tool to track changes in brain biomechanics in hydrocephalus.

Published

2017

5. Changes in Rat Brain Tissue Microstructure and Stiffness during the Development of Experimental Obstructive Hydrocephalus

Author

Lynne E. Bilston, Andre Bongers, Shaokoon Cheng, Ralph Sinkus, Alice C. Pong, and Lauriane Jugé

Subjects

Central Nervous System, Pathology, Internal capsule, lcsh:Medicine, Ventricular system, Cisterna magna, Corpus callosum, Nervous System, 030218 nuclear medicine & medical imaging, Stiffness, Diagnostic Radiology, Rats, Sprague-Dawley, 0302 clinical medicine, Materials Physics, Medicine and Health Sciences, Gray Matter, Kaolin, lcsh:Science, Microstructure, Multidisciplinary, medicine.diagnostic_test, Physics, Radiology and Imaging, Classical Mechanics, Brain, Anatomy, Condensed Matter Physics, Magnetic Resonance Imaging, White Matter, Deformation, medicine.anatomical_structure, Neurology, Physical Sciences, Elasticity Imaging Techniques, Female, Research Article, Hydrocephalus, medicine.medical_specialty, Imaging Techniques, Materials Science, Material Properties, Research and Analysis Methods, White matter, 03 medical and health sciences, Diagnostic Medicine, medicine, Mechanical Properties, Animals, Damage Mechanics, business.industry, lcsh:R, Biology and Life Sciences, Magnetic resonance imaging, medicine.disease, Anisotropy, lcsh:Q, business, 030217 neurology & neurosurgery, Diffusion MRI

Abstract

Understanding neural injury in hydrocephalus and how the brain changes during the course of the disease in-vivo remain unclear. This study describes brain deformation, microstructural and mechanical properties changes during obstructive hydrocephalus development in a rat model using multimodal magnetic resonance (MR) imaging. Hydrocephalus was induced in eight Sprague-Dawley rats (4 weeks old) by injecting a kaolin suspension into the cisterna magna. Six sham-injected rats were used as controls. MR imaging (9.4T, Bruker) was performed 1 day before, and at 3, 7 and 16 days post injection. T2-weighted MR images were collected to quantify brain deformation. MR elastography was used to measure brain stiffness, and diffusion tensor imaging (DTI) was conducted to observe brain tissue microstructure. Results showed that the enlargement of the ventricular system was associated with a decrease in the cortical gray matter thickness and caudate-putamen cross-sectional area (P < 0.001, for both), an alteration of the corpus callosum and periventricular white matter microstructure (CC+PVWM) and rearrangement of the cortical gray matter microstructure (P < 0.001, for both), while compression without gross microstructural alteration was evident in the caudate-putamen and ventral internal capsule (P < 0.001, for both). During hydrocephalus development, increased space between the white matter tracts was observed in the CC+PVWM (P < 0.001), while a decrease in space was observed for the ventral internal capsule (P < 0.001). For the cortical gray matter, an increase in extracellular tissue water was significantly associated with a decrease in tissue stiffness (P = 0.001). To conclude, this study characterizes the temporal changes in tissue microstructure, water content and stiffness in different brain regions and their association with ventricular enlargement. In summary, whilst diffusion changes were larger and statistically significant for majority of the brain regions studied, the changes in mechanical properties were modest. Moreover, the effect of ventricular enlargement is not limited to the CC+PVWM and ventral internal capsule, the extent of microstructural changes vary between brain regions, and there is regional and temporal variation in brain tissue stiffness during hydrocephalus development.

Published

2016