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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

MR-Guided Assessment and Management of Ventricular Tachycardia

Oduneye, Samuel 13 January 2014 (has links)
This thesis describes the electrical and physiological characterization of cardiac tissue with myocardial infarction (MI) responsible for abnormal cardiac rhythms such as ventricular tachycardia (VT), using a newly-developed magnetic resonance imaging (MRI) electrophysiology system. In electrophysiology (EP), radiofrequency (RF) catheter ablation combined with cardioverter-defibrillator implantation is a first-line action to manage ventricular VT. Unfortunately, this therapy is known to have sub-optimal success rates in a large number of patients because of difficulties to accurately identifying the arrhythmic target regions. Currently, characterization of post-MI scars is performed by using catheters to measure electrical signals of the endocardial tissue (electroanatomical mapping), under x-ray fluoroscopy guidance. Prolonged radiation exposure to both the cardiologist and the patient have made the use of MRI extremely attractive; further, unlike x-ray imaging, MRI provides post-MI scars with direct visualization, characterization in three dimensions and the ability to visualize ablation lesions. Although recent research has focused on registration between pre-acquired MR images and electroanatomical maps, a potentially more useful approach is to use real-time MRI to directly locate and characterize potential arrhythmogenic regions during the EP procedure. A real-time MR-guided EP system was developed and validated to perform EP diagnostic procedures, such as mapping and pacing. In a series of animal studies, the system demonstrated the ability to use active catheter tracking and intra-procedural MR imaging to navigate to specific regions in the left ventricle and record intracardiac electrical signals. A study correlating myocardial fibrotic scar detected by multicontrast late enhancement (MCLE) MRI and electroanatomical voltage mapping demonstrated that MRI information (transmurality, tissue classification, and relaxation rate) can accurately predict areas of myocardial fibrosis identified with bipolar voltage mapping. Finally, MCLE-derived gray zone was shown to have a high correspondence to regions with a high proportion of abnormal intracardiac signals. The methods described in this thesis help advance the understanding of infarcted tissue responsible for ventricular tachycardia. Further studies are proposed to perform RF ablation lesions and correlate pre- and post-ablation tissue electrophysiological properties with MRI.
2

MR-Guided Assessment and Management of Ventricular Tachycardia

Oduneye, Samuel 13 January 2014 (has links)
This thesis describes the electrical and physiological characterization of cardiac tissue with myocardial infarction (MI) responsible for abnormal cardiac rhythms such as ventricular tachycardia (VT), using a newly-developed magnetic resonance imaging (MRI) electrophysiology system. In electrophysiology (EP), radiofrequency (RF) catheter ablation combined with cardioverter-defibrillator implantation is a first-line action to manage ventricular VT. Unfortunately, this therapy is known to have sub-optimal success rates in a large number of patients because of difficulties to accurately identifying the arrhythmic target regions. Currently, characterization of post-MI scars is performed by using catheters to measure electrical signals of the endocardial tissue (electroanatomical mapping), under x-ray fluoroscopy guidance. Prolonged radiation exposure to both the cardiologist and the patient have made the use of MRI extremely attractive; further, unlike x-ray imaging, MRI provides post-MI scars with direct visualization, characterization in three dimensions and the ability to visualize ablation lesions. Although recent research has focused on registration between pre-acquired MR images and electroanatomical maps, a potentially more useful approach is to use real-time MRI to directly locate and characterize potential arrhythmogenic regions during the EP procedure. A real-time MR-guided EP system was developed and validated to perform EP diagnostic procedures, such as mapping and pacing. In a series of animal studies, the system demonstrated the ability to use active catheter tracking and intra-procedural MR imaging to navigate to specific regions in the left ventricle and record intracardiac electrical signals. A study correlating myocardial fibrotic scar detected by multicontrast late enhancement (MCLE) MRI and electroanatomical voltage mapping demonstrated that MRI information (transmurality, tissue classification, and relaxation rate) can accurately predict areas of myocardial fibrosis identified with bipolar voltage mapping. Finally, MCLE-derived gray zone was shown to have a high correspondence to regions with a high proportion of abnormal intracardiac signals. The methods described in this thesis help advance the understanding of infarcted tissue responsible for ventricular tachycardia. Further studies are proposed to perform RF ablation lesions and correlate pre- and post-ablation tissue electrophysiological properties with MRI.
3

Meningeal Fibrosis in the Axolotl Spinal Cord: Extracellular Matrix and Cellular Responses

Deborah Anne Sarria (18405282) 03 June 2024 (has links)
<p dir="ltr">Though mammalian spinal cord injury (SCI) has long been a topic of study, effective therapies that promote functional recovery are not yet available. The axolotl, <i>Ambystoma mexicanum</i>, is a valuable animal model in the investigation of spinal cord regeneration, as this urodele is able to achieve functional recovery even after complete spinal cord transection. Understanding the similarities and differences between the mammalian SCI response and that of the axolotl provides insight into the process of successful regeneration, and bolsters the fundamental knowledge used in the development of future mammalian SCI treatments. This thesis provides a detailed analysis of the ultrastructure of the axolotl meninges, as this has not yet been presented in existing literature, and reveals that the axolotl meninges consist of 3 distinct layers as does mammalian meninges; the dura mater, arachnoid mater, and pia mater. The role of reactive meningeal and ependymal cells is also investigated in regard to the deposition and remodeling of the fibrotic ECM, which is found to be similar in composition to hydrogel scaffolds being studied in mammalian SCI. It is shown that meningeal fibroblasts are the primary source of the extensive fibrillar collagen deposition that fills the entire spinal canal, peaking at approximately 3 weeks post transection and remaining until approximately 5 weeks post transection, and that there is no deposition of type IV collagen within the lesion site. Mesenchymal ependymal cells are shown to contribute to the ECM deposition through the production of glycosaminoglycans that are used in sidechains of both unsulfated and sulfated proteoglycans, while simultaneously remodeling the ECM through the production of MMPs and phagocytosis of cellular debris. Further, this study shows that mesenchymal ependymal cells and a population of foamy macrophages contribute to the degradation of the fibrin clot that forms in the acute phase of injury, and that this fibrin clot provides a necessary and permissive substrate for early mesenchymal outgrowth.</p>

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