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Risk factors for stroke : a prospective population studyLi, Yangmei January 2012 (has links)
No description available.
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Is secondhand smoking related to stroke in old age in Hong Kong?Wong, Chun-yam, Fanny., 黃峻崟. January 2007 (has links)
published_or_final_version / Community Medicine / Master / Master of Public Health
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Risk of ischemic stroke and recurrent hemorrhagic stroke in Chinese populationChong, Boon Hor., 鍾文一. January 2011 (has links)
Stroke is a devastating, neurological dysfunction due to brain blood supply disturbance. It is responsible for increasingly high rate of mortality and disability worldwide. This thesis comprises two original studies involving 868 patients at risk of ischemic stroke and/or hemorrhagic stroke.
The first study investigated aspirin’s effect among patients with intracranial hemorrhage. Unlike Caucasians which hemorrhagic strokes account for 10-15% of all strokes; in Chinese, intracranial hemorrhages strike up to 35%. After such, anti-platelet agent like aspirin is often avoided for fear of recurrent intracranial hemorrhages, despite compelling indications. However, clinical data is limited. In this single-centered observational study, we included 440 consecutive Chinese patients with a first spontaneous intracranial hemorrhage surviving the first month performed during 1996-2010. 56 patients (12.7%) of these 440 patients were prescribed aspirin after intracranial hemorrhage (312 patient-aspirin years). After a mean follow-up of 62.2 ± 1.8 months, 47 patients had recurrent intracranial hemorrhage(10.7%, 20.6 per 1,000 patient years). Patients prescribed aspirin did not have higher risk of recurrent intracranial hemorrhage compared with those without (22.7 per 1,000 patient-aspirin years vs. 22.4 per 1,000 patient years, p=0.70). Multivariate analysis identified age > 60 years and hypertension as independent predictors for recurrent intracranial hemorrhage. In a subgroup analysis: the incidence of combined vascular events including recurrent intracranial hemorrhage, ischemic stroke, and acute coronary syndrome was statistically lower in patients prescribed aspirin than without (52.4 per 1,000 patient-aspirin years, vs. 112.8 per 1,000 patient-years, p=0.04). Implications of the results: despite having a substantial risk for recurrent intracranial hemorrhage, post-intracranial hemorrhage ones are at risk for thrombotic vascular events and management goal should thus focus on ameliorating overall cardiovascular risk instead of preventing recurrent intracranial hemorrhage. Hence, thrombo-prophylaxis should still be considered.
The second study investigated the relation between premature atrial complexes and new-onset atrial fibrillation together with other cardiovascular events. Premature atrial complexes though taken as benign phenomenon, are common in patients with underlying conditions such as coronary heart disease, chronic rheumatic heart disease. While prompt management of atrial fibrillation may prevent ischemic stroke, atrial fibrillation is often unfound until ischemic stroke occurs. In this study, 428 patients without atrial fibrillation but complained of palpitations, dizziness or syncope were recruited. 107 patients with >100 premature atrial complexes/day were defined to have frequent premature atrial complexes. After a mean follow-up of 6.1 ±1.3 years, 31 patients (29%) with frequent premature atrial complexes developed atrial fibrillation compared with 29 patients (9%) with premature atrial complexes?100/day (p<0.01). Cox regression analysis revealed: frequent premature atrial complexes, age>75 years and coronary artery disease were independent predictors. In secondary endpoint (ischemic stroke, congestive heart failure, and death), patients with frequent premature atrial complexes were more at risk than those without (34.5% vs. 19.3%) (Hazard ratio: 1.95, 95% confidence interval: 1.37-3.50, p=0.001). Cox regression analysis showed: age> 75 years, coronary artery disease and frequent premature atrial complexes were independent predictors. These permit early identification of high risks patients of new atrial fibrillation and other events, thus promoting appropriate preventive treatment. / published_or_final_version / Medicine / Master / Master of Philosophy
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High frame rate imaging of arterial wall mechanics and blood flow dynamics for atherosclerosis diagnosis and monitoringKarageorgos, Grigorios Marios January 2022 (has links)
Carotid artery wall stiffness has been widely considered as an index of vascular health, and has been associated with occurrence of cardiovascular events, such as stroke. In addition, the blood flow patterns in the carotid artery can yield crucial information on atherosclerosis progression and cerebrovascular impairment. Pulse wave imaging (PWI) is a non-invasive ultrasound imaging technique that tracks the propagation of the arterial pulse wave, providing thus regional arterial wall stiffness mapping. Moreover, towards enabling accurate visualization of blood flow patterns, ultrasound-based vector flow imaging (VFI) modalities have been developed.
Building upon PWI and VFI techniques, the overall goal of this dissertation is to develop ultrasound-based methodologies that can provide simultaneous imaging of the carotid artery wall mechanics and blood flow dynamics at high temporal and spatial resolutions. The developed techniques are validated through vessel phantom experiments and simulations. Furthermore, their potential to diagnose pre-clinical stages of carotid artery disease and provide additional insights in risk for stroke assessment, is demonstrated in an atherosclerotic swine study and human subjects in vivo. More specifically:
A method is presented that analyzes the pattern of arterial wall motion derived by PWI, in order to detect spatial mechanical inhomogeneity across an imaged artery, and provide piecewise arterial wall stiffness estimates. The proposed technique is validated in a phantom consisting of a soft and a stiff segment, while its feasibility is demonstrated to identify inhomogeneous wall properties in atherosclerotic human carotid arteries, as well as provide atherosclerotic plaque mechanical characterization in vivo.
Subsequently, PWI is integrated with VFI techniques in the same ultrasound acquisition sequence, in order to enable simultaneous and co-localized imaging of arterial wall stiffness and blood vector flow velocity. The performance of the technique is investigated through experiments and FSI simulations. Moreover, its feasibility was shown to investigate associations between carotid artery Pulse Wave Velocity and blood flow patterns, in vivo.
Based on the previously developed PWI and VFI modalities, a novel ultrasound-based technique is developed that combines high frame rate vector flow imaging with a data clustering approach, in order to enable direct and robust wall shear stress measurements. The performance of the proposed method is evaluated through vessel phantom experiments and simulations, while its feasibility is shown to detect pre-clinical stages of carotid artery disease in a swine model in vivo. In addition, a pilot clinical study is presented involving application of the developed modality in normal and atherosclerotic human carotid arteries in-vivo.
Moving forward, the developed imaging modalities are used to implement novel clinical biomarkers based on carotid artery arterial wall mechanics and blood flow dynamics, that can potentially assist in risk for stroke assessment. The patterns of those biomarkers are investigated in the common carotid arteries of subjects with low degree of stenosis and medical history of stroke, against subjects without history of stroke. The same biomarkers are also analyzed with respect to stroke symptomatology in atherosclerotic patients with moderate to high degree of stenosis. Moreover, the developed techniques are used to identify vulnerable plaque components in subjects with fully developed plaques, as compared with CTA scans.
Finally, a deep learning-based approach for motion tracking of the arterial wall throughout the cardiac cycle is proposed. A neural network is trained to learn the motion patterns of the carotid artery and potentially improve the quality of PWI. The performance of the technique is assessed in vessel phantom experiments and its feasibility is demonstrated in healthy human carotid arteries in-vivo.
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