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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.
11

Magnetic Resonance Mapping of Cerebrovascular Reserve: Steal Phenomena in Normal and Abnormal Brain

Mandell, Daniel M. 13 January 2014 (has links)
Blood oxygen level-dependent (BOLD) magnetic resonance (MR) imaging enables non-invasive spatial mapping of changes in cerebral blood flow (CBF). By applying a vasodilatory stimulus (such as inhaled CO2) during BOLD MR imaging, one can measure cerebral vasodilatory capacity. "Cerebrovascular reactivity" (CVR) is defined as the change in CBF per unit of vasodilatory stimulus. Vasodilatory capacity is clinically important as vasodilatation is a mechanism by which the brain maintains constant CBF despite reductions in cerebral perfusion pressure.ii Patients with arterial narrowing commonly demonstrate a paradoxical response: vasodilatory stimulus-induced reduction of BOLD MR signal. BOLD MR depends on CBF but on other factors too. Does a reduction of BOLD MR signal indicate a decrease in flow? Does BOLD MR CVR correlate with CVR measured using arterial spin labeling (ASL) MR? I studied thirty-eight patients with stenosis of brain-supplying arteries and found that the BOLD CVR and ASL CVR results correlate strongly (R=0.83, P<0.0001 for cerebral hemispheric gray matter). The second study aimed to determine whether preoperative CVR predicts the hemodynamic effect of extracranial-intracranial bypass surgery. Whereas prior studies relied on right-left interhemispheric CVR asymmetry indices, this study used “absolute” CVR from each hemisphere. I studied twenty-five patients with intracranial arterial stenosis. I found that the group with normal pre-operative CVR showed no change in CVR following bypass surgery (0.22% ± 0.05% to 0.22% ± 0.01% (mean ± SD)(P=0.881)), the group with reduced pre-operative CVR demonstrated an improvement (0.08% ± 0.05% to 0.21 ± 0.08% (mean ± SD)(P<0.001)), and the group with paradoxical pre-operative CVR demonstrated the greatest improvement (-0.04% ± 0.03% to 0.27% ± 0.03% (P=0.028)). ii Patients with arterial narrowing commonly demonstrate a paradoxical response: vasodilatory stimulus-induced reduction of BOLD MR signal. BOLD MR depends on CBF but on other factors too. Does a reduction of BOLD MR signal indicate a decrease in flow? Does BOLD MR CVR correlate with CVR measured using arterial spin labeling (ASL) MR? I studied thirty-eight patients with stenosis of brain-supplying arteries and found that the BOLD CVR and ASL CVR results correlate strongly (R=0.83, P<0.0001 for cerebral hemispheric gray matter). The second study aimed to determine whether preoperative CVR predicts the hemodynamic effect of extracranial-intracranial bypass surgery. Whereas prior studies relied on right-left interhemispheric CVR asymmetry indices, this study used “absolute” CVR from each hemisphere. I studied twenty-five patients with intracranial arterial stenosis. I found that the group with normal pre-operative CVR showed no change in CVR following bypass surgery (0.22% ± 0.05% to 0.22% ± 0.01% (mean ± SD)(P=0.881)), the group with reduced pre-operative CVR demonstrated an improvement (0.08% ± 0.05% to 0.21 ± 0.08% (mean ± SD)(P<0.001)), and the group with paradoxical pre-operative CVR demonstrated the greatest improvement (-0.04% ± 0.03% to 0.27% ± 0.03% (P=0.028)). The third study arose from an unexpected observation: paradoxical reactivity in the white matter of young healthy subjects. I evaluated healthy subjects using BOLD CVR and ASL CVR, transformed all CVR maps into a common brain space, and generated composite maps of CVR. Composite maps confirmed regions of significant paradoxical iii reactivity in the white matter. These regions may represent the physiological correlate of previously anatomically defined border-zones (watershed zones). The regions match the locations where elderly patients develop white matter rarefaction, so-called leukoaraiosis.
12

Magnetic Resonance Mapping of Cerebrovascular Reserve: Steal Phenomena in Normal and Abnormal Brain

Mandell, Daniel M. 13 January 2014 (has links)
Blood oxygen level-dependent (BOLD) magnetic resonance (MR) imaging enables non-invasive spatial mapping of changes in cerebral blood flow (CBF). By applying a vasodilatory stimulus (such as inhaled CO2) during BOLD MR imaging, one can measure cerebral vasodilatory capacity. "Cerebrovascular reactivity" (CVR) is defined as the change in CBF per unit of vasodilatory stimulus. Vasodilatory capacity is clinically important as vasodilatation is a mechanism by which the brain maintains constant CBF despite reductions in cerebral perfusion pressure.ii Patients with arterial narrowing commonly demonstrate a paradoxical response: vasodilatory stimulus-induced reduction of BOLD MR signal. BOLD MR depends on CBF but on other factors too. Does a reduction of BOLD MR signal indicate a decrease in flow? Does BOLD MR CVR correlate with CVR measured using arterial spin labeling (ASL) MR? I studied thirty-eight patients with stenosis of brain-supplying arteries and found that the BOLD CVR and ASL CVR results correlate strongly (R=0.83, P<0.0001 for cerebral hemispheric gray matter). The second study aimed to determine whether preoperative CVR predicts the hemodynamic effect of extracranial-intracranial bypass surgery. Whereas prior studies relied on right-left interhemispheric CVR asymmetry indices, this study used “absolute” CVR from each hemisphere. I studied twenty-five patients with intracranial arterial stenosis. I found that the group with normal pre-operative CVR showed no change in CVR following bypass surgery (0.22% ± 0.05% to 0.22% ± 0.01% (mean ± SD)(P=0.881)), the group with reduced pre-operative CVR demonstrated an improvement (0.08% ± 0.05% to 0.21 ± 0.08% (mean ± SD)(P<0.001)), and the group with paradoxical pre-operative CVR demonstrated the greatest improvement (-0.04% ± 0.03% to 0.27% ± 0.03% (P=0.028)). ii Patients with arterial narrowing commonly demonstrate a paradoxical response: vasodilatory stimulus-induced reduction of BOLD MR signal. BOLD MR depends on CBF but on other factors too. Does a reduction of BOLD MR signal indicate a decrease in flow? Does BOLD MR CVR correlate with CVR measured using arterial spin labeling (ASL) MR? I studied thirty-eight patients with stenosis of brain-supplying arteries and found that the BOLD CVR and ASL CVR results correlate strongly (R=0.83, P<0.0001 for cerebral hemispheric gray matter). The second study aimed to determine whether preoperative CVR predicts the hemodynamic effect of extracranial-intracranial bypass surgery. Whereas prior studies relied on right-left interhemispheric CVR asymmetry indices, this study used “absolute” CVR from each hemisphere. I studied twenty-five patients with intracranial arterial stenosis. I found that the group with normal pre-operative CVR showed no change in CVR following bypass surgery (0.22% ± 0.05% to 0.22% ± 0.01% (mean ± SD)(P=0.881)), the group with reduced pre-operative CVR demonstrated an improvement (0.08% ± 0.05% to 0.21 ± 0.08% (mean ± SD)(P<0.001)), and the group with paradoxical pre-operative CVR demonstrated the greatest improvement (-0.04% ± 0.03% to 0.27% ± 0.03% (P=0.028)). The third study arose from an unexpected observation: paradoxical reactivity in the white matter of young healthy subjects. I evaluated healthy subjects using BOLD CVR and ASL CVR, transformed all CVR maps into a common brain space, and generated composite maps of CVR. Composite maps confirmed regions of significant paradoxical iii reactivity in the white matter. These regions may represent the physiological correlate of previously anatomically defined border-zones (watershed zones). The regions match the locations where elderly patients develop white matter rarefaction, so-called leukoaraiosis.
13

Avaliação da autorregulação cerebral dinâmica através da reatividade cerebrovascular em suíno com volume expansivo por balão simulando aumento de hematoma intracerebral / Evaluation of dynamic cerebral autoregulation through cerebrovascular reactivity in a swine model with expansive volume of a balloon simulating an increase of a intracerebral hematoma

Gustavo Cartaxo Patriota 15 September 2017 (has links)
INTRODUÇÃO: A autorregulação cerebral representa um dos mecanismos fisiopatológicos incertos na hemorragia intracerebral espontânea, cujo comprometimento pode influenciar no resultado prognóstico e terapêutico. O objetivo deste trabalho é avaliar a autorregulação cerebral dinâmica em modelo suíno de hemorragia intracerebral espontânea através do índice de reatividade pressórica cerebrovascular e determinar a eficácia das intervenções clínicas e cirúrgicas. MÉTODOS: Foram estudados 21 suínos híbridos machos com idade de 3 meses. O modelo experimental simulou o efeito expansivo de uma hemorragia intracerebral espontânea de grande volume quando comparado ao cérebro humano. Foram avaliados volumes de expansão diferentes, distribuídos em três grupos com sete suínos cada. O protocolo anestésico incluiu uma monitoração hemodinâmica invasiva associada a preservação da autorregulação cerebral. Os experimentos foram submetidos a monitoração neurológica multimodal e divididos em 5 fases. O índice de reatividade pressórica cerebrovascular estimou a autorregulacão cerebral durante todas as fases, sendo as três primeiras sem intervenções terapêuticas e as duas últimas para avaliar a eficácia das intervenções salina hipertônica e cirurgia. RESULTADOS: Os grupos avaliados foram homogêneos e sem diferença estatística quanto ao comprometimento da autorregulação cerebral comparando os diferentes volumes e tempos de compressão durante as duas primeiras horas da expansão do volume intracraniano. O comprometimento do índice de reatividade pressórica cerebrovascular ocorreu em alguns experimentos influenciando nas fases de tratamento subsequentes, salina hipertônica e cirurgia. CONCLUSÕES: Volumes expansivos elevados podem comprometer a autorregulação cerebral dinâmica e apresentar desfecho terapêutico desfavorável. A intervenção clínica e cirúrgica tem benefício nos experimentos com preservação do índice de reatividade pressórica cerebrovascular / INTRODUCTION: Cerebral autoregulation represents one of the uncertain pathophysiological mechanisms in spontaneous intracerebral hemorrhage, whose impairment may influence prognostic and therapeutic outcome. The aim of this study was to evaluate the dynamic cerebral autoregulation in the swine model of spontaneous intracerebral hemorrhage through the cerebrovascular reactivity index and to determine the efficacy of clinical and surgical interventions. METHODS: Twenty-one male hybrid pigs aged 3 months were studied. The experimental model simulated the expansive effect of a large intracerebral hemorrhage when compared to the human brain. Different volumes were evaluated, distributed in three groups with seven pigs each. Each experiment was divided in five phases. The anesthetic protocol included invasive hemodynamic monitoring associated with the preservation of cerebral autoregulation. Multimodallity monitoring was realised in all experiments. The cerebrovascular reactivity index estimated the cerebral autoregulation during all phases. The first three phases were without therapeutic interventions, and the last two phases were with therapeutic intervention of hypertonic saline solution and neurosurgery respectively. RESULTS: The evaluated groups were homogeneous and without statistical difference regarding the impairment of the cerebral autoregulation comparing different volumes and compression times during the first two hours of the intracranial volume expansion. CONCLUSIONS: Elevated expansive volumes may compromise dynamic cerebral autoregulation and have unfavorable therapeutic outcome. Clinical and surgical intervention had benefit in the experiments with preservation of cerebrovascular reactivity index
14

Arterial stiffness and brain health : investigating the impact of sex-related differences

Sabra, Dalia 08 1900 (has links)
Introduction: Il est bien établi que les maladies vasculaires, cérébrovasculaires et cardiovasculaires se manifestent différemment chez les hommes que chez les femmes. La rigidité artérielle (RA), un prédicteur indépendant de la maladie cardiovasculaire (MCV), a été associée à des changements de la réactivité cérébrovasculaire (RCV) et à un déclin cognitif lors du vieillissement. Plus précisément, les personnes âgées ayant une RA plus élevée présentent un déclin plus marqué au niveau des tâches exécutives. Une diminution des fonctions exécutives (FE) est également liée à une réduction de la RCV chez les personnes âgées. Cependant, il est important de noter que la relation entre la RA et la RCV est plus complexe. Certaines études montrent une diminution de la RCV associée avec une RA plus élevée, tandis que d’autres rapportent une RCV préservée avec une RA élevée. De plus, des travaux récents suggèrent que les différences de concentration en hématocrit (HCT) pourraient avoir une incidence sur les mesures de RA. Ici, nous avons étudié le rôle possible du sexe et de l'HCT sur ces relations hémodynamiques. Méthodes: Des acquisitions ont été effectuées chez 48 adultes âgés en bonne santé (31 femmes, 63 ± 5 ans) dans un scanneur d’imagerie par résonance magnétique (IRM) 3T. Des données de marquage de spin artériel pseudo-continu utilisant des lectures à double écho ont été collectées pendant un défi d'hypercapnie (changement de CO2 de 5mmHg, pendant deux blocs de 2 minutes). La RCV a été calculée comme étant le % de changement du signal de débit sanguin cérébral (% ∆CBF) par changement de mmHg dans le CO2 à la fin de l’expiration. Les données de vitesse d’onde de pouls (VOP) aortique ont été acquises à l’aide d’une série de contraste de phase cine encodée par la vitesse durant 60 phases cardiaques avec un encodage en vélocité de 180cm/s dans le plan. La VOP dans l'arcade aortique a été calculée entre l'aorte ascendante et descendante. Les analyses statistiques ont été effectuées à l'aide de SPSS. Résultats: Un test de modération contrôlant pour l’âge et le volume des hyperintensités de la matière blanche a révélé un effet direct significatif de la VOP sur la RCV (β = 1,630, IC à 95% [.654, 2,607), ainsi que de la VOP sur la FE (β = -. 998, IC 95% [-1,697, -,299]). Le sexe a modéré la relation entre VOP et RCV (β = -1,013, IC 95% [-1,610, -,4169]), et VOP et FE (β = .447, IC 95% [.020, .875]). En outre, il existait un effet significatif de l’HCT sur les différences de sexe observées dans l’effet de modération (VOP * SEXE) sur la FE (β = -0,7680, SE = 0,3639, IC 95% [-1,5047, -0,0314], p = 0,0414). Conclusion: Nos résultats indiquent que les relations entre la VOP, la RCV et la FE sont complexes et que le sexe et l’HCT modulentces relations. L’influence des variations hormonales (p. ex. la ménopause) sur ces relations devrait être étudiée dans le futur et pourrait permettre de personnaliser les stratégies de prévention des MCV. / Introduction: It is well established that sex differences exist in the manifestation of vascular, cerebrovascular and cardiovascular disease. Arterial stiffness (AS), an independent predictor of cardiovascular disease (CVD), has been associated with changes in cerebrovascular reactivity (CVR) and cognitive decline in aging. Specifically, older adults with increased AS show a steeper decline on executive function (EF) tasks. Decreased EF is also linked with reduction in CVR among older adults. Interestingly, the relationship between AS and CVR is more complex, where some works show decreased CVR with increased AS, and others demonstrate preserved CVR with higher AS. In addition, recent work suggests that measurements of AS may be affected by differences in the concentration of hematocrit (HCT). Here, we investigated the possible role of sex and HCT on these hemodynamic relationships. Methods: Acquisitions were completed in 48 healthy older adults (31 females, 63 ± 5 years) on a 3T MRI. Pseudo-continuous arterial spin labeling using dual-echo readouts were collected during a hypercapnia challenge (5mmHg CO2 change, during two, 2 min blocks). CVR was calculated as the %∆CBF signal per mmHg change in end-tidal CO2. Aortic PWV data was acquired using a cine phase contrast velocity encoded series during 60 cardiac phases with a velocity encoding of 180cm/s through plane. PWV in the aortic arch was computed between ascending and descending aorta. Statistical analyses were done using SPSS. Results: A moderation model test controlling for age and white matter hyperintensity volume revealed a significant direct effect of PWV on CVR (β=1.630, 95% CI [.654, 2.607), as well as PWV on EF (β=-.998, 95% CI [-1.697, -.299]). Sex moderated the relationship between PWV and CVR (β=-1.013, 95% CI [-1.610, -.4169]), and PWV and EF (β=.447, 95% CI [.020, .875]). In addition, there was a significant effect of HCT on the sex differences observed in the moderation effect (PWV*SEX) on EF (β=-0.7680, SE = 0.3639 ,95% CI [-1.5047, -0.0314], p=0.0414). Conclusion: Together, our results indicate that the relationships between PWV, CVR and EF is complex and in part mediated by sex and HCT. Future work should investigate the role of hormone variations (e.g., menopause) on these relationships to better personalize CVD prevention strategies.
15

An investigation of fMRI-based perfusion biomarkers in resting state and physiological stimuli

Jinxia Yao (13925085) 10 October 2022 (has links)
<p>    </p> <p>Cerebrovascular diseases, such as stroke, constitute the most common life-threatening neurological disease in the United States. To support normal brain function, maintaining adequate brain perfusion (i.e., cerebral blood flow (CBF)) is important. Therefore, it is crucial to assess the brain perfusion so that early intervention in cerebrovascular diseases can be applied if abnormal perfusion is observed. The goal of my study is to develop metrics to measure the brain perfusion through modeling brain physiology using resting-state and task-based blood-oxygenation-level- dependent (BOLD) functional MRI (fMRI). My first and second chapters focused on deriving the blood arrival time using the resting-state BOLD signal. In the first chapters, we extracted the systemic low-frequency oscillations (sLFOs) in the fMRI signal from the internal carotid arteries (ICA) and the superior sagittal sinus (SSS). Consistent and robust results were obtained across 400 scans showing the ICA signals leading the SSS signals by about 5 seconds. This delay time could be considered as an effective perfusion biomarker that is associate with the cerebral circulation time (CCT). To further explore sLFOs in assessing dynamic blood flow changes during the scan, in my second chapter, a “carpet plot” (a 2-dimensional plot time vs. voxel) of scaled fMRI signal intensity was reconstructed and paired with a developed slope-detection algorithm. Tilted vertical edges across which a sudden signal intensity change took place were successfully detected by the algorithm and the averaged propagation time derived from the carpet plot matches the cerebral circulation time. Given that CO<sub>2</sub> is a vasodilator, controlling of inhaled CO<sub>2</sub> is able to modulate the BOLD signal, therefore, as a follow-up study, we focused on investigating the feasibility of using a CO<sub>2</sub> modulated sLFO signal as a “natural” bolus to track CBF with the tool developed from the second chapter. Meaningful transit times were derived from the CO<sub>2</sub>-MRI carpet plots. Not only the timing, the BOLD signal deformation (the waveform change) under CO<sub>2</sub> challenge also reveals very useful perfusion information, representing how the brain react to stimulus. Therefore, my fourth chapter focused on characterizing the brain reaction to the CO<sub>2</sub> stimulus to better measure the brain health using BOLD fMRI. Overall, these studies deepen our understanding of fMRI signal and the derived perfusion parameters can potentially be used to assess some cerebrovascular diseases, such as stroke, ischemic brain damage, and steno-occlusive arterial disease in addition to functional activations. </p>

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