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251	The Effect of Cognitive Limb Embodiment on Vascular Physiological Response Osman, Hala Elsir Mustafa 13 June 2018 (has links) No description available. Biomedical Engineering rubber hand illusion physiological correlates of embodiment cognitive limb embodiment skin surface temperature Doppler blood flow tissue blood flow vascular physiological response
252	Neurovaskuläre Kopplung im somatosensorischen Kortex der Ratte / Untersuchungen zur zeitlichen Kinetik mittels optischer Verfahren und funktioneller Magnetresonanztomographie Royl, Georg Andreas 09 December 2002 (has links) Die Grundlage der modernen funktionellen Bildgebung des Gehirns mit der BOLD-fMRT ist die neurovaskuläre Kopplung. Sie ist in ihren Mechanismen wenig verstanden und führt zu einem komplexen Zusammenspiel von Blutfluß, Blutvolumen und Oxygenierung. Die Aufklärung der Blutflußantwort mit ihren Auswirkungen auf die Meßsignale ist für eine genaue Interpretation des BOLD-Signals kritisch. Zudem stellt sich seit einigen Jahren die Frage, ob es bei funktioneller Aktivierung aufgrund eines vermehrten neuronalen Sauerstoffverbrauchs zu einer frühen Deoxygenierung kommt. Diese könnte sich als initialer BOLD-Abfall für eine hochauflösende Bildgebung eignen. Ein Vergleich von optischen Methoden und funktioneller Magnetresonanztomographie am gleichen Stimulationsmodell kann diesen Fragen nachgehen. Wir haben die kortikale Blutflußantwort auf somatosensorische Stimulation der Ratte mit den optischen Methoden Optical Imaging und Imaging Spectroscopy sowie mit BOLD-fMRT und blutvolumengewichteter MION-fMRT gemessen. Bei der Stimulation eines einzelnen Whisker-Haares grenzte sich die entsprechende kortikale Kolumne über eine optische Abschwächung ab. Spektroskopisch zeigte sich, daß diesem Signal eine initiale Blutvolumenzunahme zugrundeliegt. Eine Lambert-Beer-Analyse, die die differentiellen Pfadlängen des Lichtes im streuenden Gewebe vernachlässigt, konnte die gemessenen Spektren nicht linear anpassen. Mit einer Annäherung errechnete sie einen artifiziellen Anstieg des Deoxy-Hb in der frühen Antwort. Die quantifizierte Lambert-Beer-Analyse unter Einschluß der differentiellen Pfadlängen konnte die gemessenen Spektren linear anpassen. Im berechneten Konzentrationsverlauf stieg Oxy-Hb zum Stimulationsbeginn an, Deoxy-Hb blieb zunächst auf dem Ruhewert und fiel dann ab. Diese Verzögerung lag im Bereich der kapillären Transitzeit. Die spektroskopisch gemessene frühe Antwort fand sich auch in der Messung der Antwort auf Vorderpfotenstimulation. Zum Vergleich wurden fMRT-Messungen an diesem Stimulationsmodell herangezogen. Die MION-fMRT erfaßte einen initialen Anstieg des plasmatischen Blutvolumens (pCBV), das BOLD-Signal delta-R2* eine verzögerte Hyperoxygenierung. Die Hyperoxygenierung im weiteren Verlauf der Blutflußantwort zeigte in Imaging Spectroscopy und fMRT einen linearen Zusammenhang mit der Dauer der Stimulation. Dabei korrelierte die delta-R2* stark mit der spektroskopisch gemessenen Deoxy-Hb-Konzentration. Auch die Antwort auf das Stimulationsende stellte sich als von der Stimulationsdauer abhängig heraus und wurde als vaskuläres Speicherphänomen interpretiert. BOLD und Deoxy-Hb zeigten beide eine Hypooxygenierung nach dem Stimulationsende. pCBV und das spektroskopisch gemessene korpuskuläre Blutvolumen, cCBV, verhielten sich nach dem Stimulationsende spiegelbildlich. Die pCBV-Zunahme bildete sich nur allmählich zurück, während das cCBV steil unter seinen Ruhewert abfiel. Im Laufe der Messung nahm das cCBV wieder zu und erreichte seinen Ruhewert zeitgleich mit dem pCBV. Eine vermehrte Volumenspeicherung als Folge venöser Streßrelaxation und eine Verschiebung des Hämatokrits aufgrund des Fahraeus-Lindquist-Effekts werden als Grund für diese Veränderungen in Betracht gezogen. Die experimentellen Daten belegen, daß optische und magnetresonanztomographische Methoden korrespondierende Signale von Oxygenierung und Blutvolumen messen. Eine frühe Deoxygenierung wurde nicht gemessen. Allerdings zeigte sich die frühe Komponente der Blutvolumenzunahme an die initiale Kapillarnetzfüllung einer kortikalen Kolumne gebunden. Ihre Detektion mit der fMRT bietet eine Perspektive auf dem Weg zu einer hochauflösenden funktionellen Bildgebung des Gehirns. / Neurovascular coupling forms the basis of modern functional brain imaging with BOLD-fMRI. Its mechanisms are poorly understood as it leads to a complex interaction of blood flow, blood volume and oxygenation. The investigation of the blood flow response with its influences on measured signals is critical for the exact interpretation of the BOLD-Signal. In addition to that, the question on whether or not an increase in oxygen consumption during functional activation leads to an early deoxygenation is not resolved yet. This early deoxygenation could cause an initial BOLD decrease suitable for high resolution imaging. A comparison of optical methods and functional magnetic resonance imaging on the same stimulation model can help to answer these questions. We have measured the cortical blood flow response on somatosensory stimulation of the rat with the optical methods Optical Imaging and Imaging Spectroscopy and with BOLD-fMRI and blood volume weighted MION-fMRI. During stimulation of a single whisker vibrissa the corresponding cortical column delineated itself as an area of increased optical attenuation. A spectroscopical analysis showed an initial blood volume increase responsible for this signal. A Lambert-Beer-Analysis that ignored the differential pathlength of light in scattering tissue could not fit the measured spectra. The result of its closest approximation showed an artificial increase of deoxy-Hb during the early response. The quantified Lambert-Beer-Analysis with inclusion of differential pathlengths succeeded in fitting the measured spectra. The calculated concentration time course showed an increase of oxy-Hb at stimulus onset with deoxy-Hb staying at baseline values and then decreasing. This delay was as long as the capillary mean transit time. The spectroscopically measured early response was also found when measuring the response to forepaw stimulation. For comparison, fMRI measurements on this stimulation model were done. MION-fMRI detected an early increase of plasmatic blood volume (pCBV), the BOLD-Signal delta-R2* a delayed hyperoxygenation. The time course of the hyperoxygenation during the blood flow response showed a linear relationship with the stimulus duration in Imaging Spectroscopy and fMRI. The delta-R2* correlated strongly with spectroscopically measured concentration changes of deoxy-Hb. In addition to that, the response on the stimulus offset was dependent on the stimulus duration. It was interpreted as a vascular storage phenomenon. Both BOLD and deoxy-Hb showed a hypooxygenation after stimulus offset. pCBV and the spectroscopically measured corpuscular blood volume, cCBV, showed mirroring signals after stimulus offset. While pCBV returned to baseline values gradually, cCBV fell below baseline values immediately. During the further measurement cCBV increased and returned to baseline values at the same time as pCBV. To explain this, an increased volume storage due to venous stress relaxation and a hematocrit shift due to the Fahraeus-Lindquist effect are taken into consideration. The experimental data proves that optical and fMRI methods measure corresponding signals of oxygenation and blood volume. An early deoxygenation was not seen. However, the early component of the blood volume increase seems to be restricted to the initial filling of the capillary net supplying a cortical column. Its detection with fMRI offers a perspective on the way to high resolution functional imaging of the brain. Optical Imaging fMRT Cerebral Blood Flow Somatosensorische Stimulation Optical Imaging fMRT Cerebral Blood Flow Somatosensory Stimulation 610 Medizin und Gesundheit 33 Medizin YR 2500 ddc:610
253	The effects of ascorbic acid on skeletal muscle blood flow in aged rats Schwagerl, Peter J. January 1900 (has links) Master of Science / Department of Kinesiology / Timothy I. Musch / During exercise aged individuals exhibit endothelial dysfunction and decreased levels of whole-limb blood flow (BF), both of which may be linked mechanistically to age-related increases in reactive oxygen species (ROS). Ascorbic acid (AA) reduces levels of ROS and has been shown to alleviate vascular and hyperemic dysfunction at rest (Jablonski et al., 2007) and during small muscle mass exercise in humans (Kirby et al., 2009). However, the effect of AA on vascular function and BF to individual muscles during whole-body exercise is not known. PURPOSE: To test the hypothesis that a single high-dose infusion of AA would increase BF to the hindlimb musculature of old rats at rest and during treadmill running. METHODS: 18 old (~28 months) Fischer 344 x Brown Norway rats were randomized into rest (n=9) and exercise (n=9) groups. BF to the total hindlimb and individual muscles (28 individual muscles and muscle parts) was evaluated via radiolabeled microspheres before and after intra-arterial AA administration (76 mg/kg in 3 ml heparinized saline, 30 minute infusion) at rest and during submaximal treadmill running (20m/min, 5% grade). Total antioxidant capacity (TAC) and thiobarbituric acid reactive species (TBARS) were measured before and after AA to determine the ability of this specific dose of AA to increase levels of plasma antioxidants and decrease levels of ROS, respectively. RESULTS: At rest: AA increased TAC (~37%, P<0.05) but did not change TBARS (Pre: 6.8±0.7 vs Post: 7.0±1.0 µM, P>0.05). AA decreased total hindlimb BF (Pre: 25±3 vs Post: 16±2 ml/min/100g, P<0.05) and BF to 8 of the 28 muscles that were evaluated. During exercise: TAC was increased (~35%, P<0.05) and TBARS were decreased (Pre: 9.8±2.0 vs Post: 7.0±1.0 µM, P<0.05). However, there was no effect on either total hindlimb BF (Pre: 154±14 vs Post: 162±13, P>0.05) or BF to any of the individual muscles evaluated. CONCLUSIONS: Increased TAC via AA infusion reduces hindlimb muscle BF at rest but had no effect on BF during whole-body dynamic exercise. Thus, even though TBARS decreased, there was no evidence that AA supplementation increases blood flow to the locomotor muscles of old rats during whole-body exercise. Aging Blood flow Reactive oxygen species Ascorbic acid Exercise Nitric Oxide Biology, Animal Physiology (0433)
254	Limb tissue haemodynamic responses and regulation in the heat-stressed human : role of local vs. central thermosensitive mechanisms at rest and during small muscle mass exercise Chiesa, Scott Thomas January 2014 (has links) Limb haemodynamic responses during heat-stress and the importance of local vs. central temperature-sensitive mechanisms towards their regulation remain poorly understood, both at a whole-limb level and within individual tissues (i.e. skeletal muscle and skin). The aims of this thesis were to 1) investigate the haemodynamic responses at rest to direct thermal challenges both at a local level and during progressive elevations in systemic heat stress, 2) to ascertain the contribution of local vs. systemic mechanisms towards this regulation, and 3) to investigate the same responses during single-legged small-muscle mass exercise to near maximal levels. Results from Chapters 4 and 5 characterised the haemodynamic responses during isolated cooling and heating of the arm and leg, and provided evidence of alterations in both skin and skeletal muscle blood flow controlled solely through local temperature-sensitive mechanisms. While local cooling led to modest decreases in limb blood flow due to decreases in mean blood velocity alone, increases during heating occurred as a result of an increased antegrade flow, a diminished retrograde flow, and a reduction in the potentially pro-atherogenic oscillatory shear index. In Chapter 6, whole-body heating with isolated single leg cooling displayed the continued control of limb blood flow via local thermosensitive mechanisms alone, as cooled leg blood flow remained unchanged despite significant elevations in core temperature, cardiac output, and opposing heated leg blood flow. Furthermore, elevations in heated leg V̇O2 suggested a possible metabolic contribution to the observed skeletal muscle hyperaemic response. During incremental single-legged knee-extensor exercise to near maximal levels, blood flow was determined by a combination of metabolic workload and local tissue temperatures, regardless of whether systemic heat stress was present. Chapter 7 revealed that whilst skin and muscle blood flow in the leg continued to increase in line with local temperatures to levels of severe heat stress, rapid cooling of the leg when hyperthermic resulted in a similar reverse response in muscle tissues only, as skin blood flow remained elevated despite the abolition of high skin and subcutaneous temperatures. In addition, evidence was provided that moderate levels of whole-body heat stress provided little additional benefit to anti-atherogenic shear profiles than that experienced during isolated limb heating alone. Taken together, these findings suggest that local thermosensitive mechanisms dominate limb blood flow control during direct rapid heating in humans both at rest and during small muscle mass exercise, but that underlying central mechanisms may act to maintain flow when local temperatures are reduced in the face of high core temperatures. 612
255	The impact of blood flow restricted exercise on the peripheral vasculature Hunt, Julie January 2014 (has links) Distortion to hemodynamic, ischemic and metabolic stimuli during low load resistance exercise with blood flow restriction (BFR) may influence regional vascular adaptation. This thesis investigated the acute response and chronic adaptations of the peripheral vasculature to low load resistance exercise with BFR. The methodology utilised Doppler ultrasound, strain gauge plethysmography and muscle biopsy for insightful measures of the vasculature at different regions of the arterial tree. Short term (4-6 weeks) localised low load (30-40% 1RM) resistance exercise with BFR increased brachial (3.1%) and popliteal (3.3%) artery maximal diameter (in response to ischemic exercise), forearm (29%) and calf (24%) post-occlusive blood flow, and calf filtration capacity (14%). These findings indicate potential vascular remodelling at the conduit (chapters 3, 4) resistance (chapter 4) and capillary (chapter 4) level of the vascular tree. Regional, rather than systemic, factors are responsible for these adaptations as evidenced by an absent response in the contralateral control limb. Transient improvements in popliteal artery FMD% occurred at week 2 before increased maximal diameter at week 6, suggesting functional changes precede structural remodelling (chapter 4). Maximal brachial artery diameter and forearm post-occlusive blood flow returned to baseline values after a 2 week detraining period, signifying rapid structural normalisation after stimulus removal (chapter 3). Enhanced capillarity, despite low training loads, could be explained by augmentation of VEGF (~7 fold), PGC-1α (~6 fold) and eNOS (~5 fold) mRNA, and upregulation VEGFR-2 (~5 fold) and HIF-1α (~2.5 fold) mRNA with BFR (chapter 5). This indicates a targeted angiogenic response potentially mediated through enhanced metabolic, ischemic and shear stress stimuli. Large between subject variability in the level of BFR was observed during upper and lower limb cuff inflation protocols. Adipose tissue thickness and mean arterial pressure were the largest independent determinants of upper and lower limb BFR, respectively (Chapter 6). In conclusion, this thesis demonstrates that low load resistance exercise with BFR induces adaptation in the conduit, resistance and capillary vessels. The mediators of this response are likely to be the hemodynamic and chemical signals elicited by repeated bouts of BFR resistance exercise, although confirmation of these mechanisms is required. The functional significance of these adaptations is unknown and warrants further investigation. 613.7
256	IDENTIFICATION AND CHARACTERIZATION OF THE GLUCAGON-LIKE PEPTIDE-2 HORMONAL SYSTEM IN RUMINANTS Edwards, Christina C. Taylor 01 January 2009 (has links) The hormone glucagon-like peptide-2 (GLP-2) is important in the regulation of intestinal growth and blood flow in nonruminant animals. However, no research reports the existence of GLP-2 in ruminants. Therefore, this dissertation examined the existence of GLP-2 and its receptor, their response to physiological stimuli, and its ability to induce gastrointestinal growth and intestinal blood flow in ruminants. Experiments 1 and 2 established the gastrointestinal distribution of mRNA for proglucagon (the GLP-2 precursor) and the GLP-2 receptor. Furthermore, these experiments determined the effects of changing dietary energy intake on plasma GLP-2 concentrations and proglucagon and GLP-2 receptor mRNA expression. Experiment 3 examined the effect of exogenous bovine GLP-2 on splanchnic blood flow, splanchnic nutrient flux, and gastrointestinal growth. This research shows that ruminants possess a functional GLP-2 signaling system that responds to nutrient ingestion. Based on observed receptor distribution and growth changes with GLP-2 treatment, GLP-2 targets the small intestine and does not affect forestomach or large intestinal growth. Increases in ileal proglucagon mRNA expression and plasma GLP-2 with increasing energy intake demonstrate that GLP-2 responds to physiologic changes in nutrient intake and can be relevant to feeding practices. Furthermore, observed increases in small intestinal growth and blood flow with GLP-2 suggest that it could substantially affect the capacity of the gastrointestinal tract for nutrient absorption. Modification of GLP-2 through diet could allow for improvements in nutrient utilization and animal productivity. This research also has important implications for use of GLP-2 for human disease therapy as the observed downregulation in the blood flow response to 10-d GLP-2 administration has never been reported in any species prior to this dissertation. This research systematically characterized and evaluated the potential role of GLP-2 in the control of gastrointestinal growth and splanchnic blood flow in ruminants. While it extends the knowledge of hormonal control of the gastrointestinal tract in ruminants, it also adds crucial information to the larger body of work investigating the actions of GLP- 2. This dissertation research has contributed to the groundwork necessary to enable the use of GLP-2 in improving the health and productivity of a diverse group of mammalian species. Animal Sciences
257	EFFECT OF ERGOT ALKALOIDS ON BOVINE FOREGUT VASCULATURE, NUTRIENT ABSORPTION, AND EPITHELIAL BARRIER FUNCTION Foote, Andrew P 01 January 2013 (has links) Ergot alkaloids present in endophyte-infected (E+) tall fescue are thought to be the causative agent of fescue toxicosis, a syndrome affecting cattle in the eastern United States. Many of the observed signs of fescue toxicosis are thought to be attributed to peripheral vasoconstriction; however, there are data indicating that ergot alkaloids can alter blood flow to the gut. An experiment was conducted using right ruminal artery and vein collected from heifers shortly after slaughter. Vessels were mounted in a multi-myograph to determine the vasoconstrictive potentials of ergot alkaloids present in E+ tall fescue. Results indicated ergot alkaloids have the potential to induce vasoconstriction of foregut vasculature. A second experiment was conducted to determine if the additional ergot alkaloids present in E+ tall fescue increase the vasoconstrictive response above that of ergovaline. Results indicated that ergovaline is the main alkaloid responsible for vasoconstriction in bovine vessels. A third study was performed to determine the effect of ergot alkaloids on ruminal epithelial blood flow in the washed rumen of steers exposed to E+ or endophyte-free (E-) tall fescue seed. Steers were dosed with seed followed by a washed rumen experiment with differing levels of ergovaline incubated in the rumen. Results indicated that E+ tall fescue seed treatment reduced ruminal epithelial blood flow. Additionally, incubating ergovaline in the rumen during the washed rumen further decreased epithelial blood flow and volatile fatty acid (VFA) absorption. A final study was conducted to determine the acute effects of ergot alkaloids on isolated rumen epithelial absorptive and barrier functions and the potential for ruminal ergovaline absorption. Results indicate that acute exposure to ergot alkaloids does not alter the absorptive or barrier function of rumen epithelium and ergovaline is absorbed from the rumen. Data from this series of experiments have shown that ergot alkaloids from E+ tall fescue can induce vasoconstriction of blood vessels in the foregut of cattle, reduce blood flow to the rumen epithelium, and decrease VFA absorption. The decrease in nutrient absorption could contribute to the observed symptoms of fescue toxicosis, including depressed growth rates and general unthriftiness. tall fescue fescue toxicosis vasoconstriction epithelial blood flow VFA absorption Animal Sciences
258	Development of Particle Image Velocimetry for In-Vitro Studies of Arterial Haemodynamics Buchmann, Nicolas January 2010 (has links) Atherosclerosis and related cardiovascular diseases (CVDs) are amongst the largest causes of morbidity and mortality in the developed world, causing considerable monetary pressure on public health systems worldwide. Atherosclerosis is characterised by the build up of vascular plaque in medium and large arteries and is a direct precursor to acute vascular syndromes such a myocardial infarction, stroke or peripheral arterial diseases. The causative factors leading to CVD still remain relatively poorly understood, but are becoming increasingly identifiable as a dysfunction of the endothelial cells that line the arterial wall. It is well known that the endothelium responds to the prevailing fluid mechanic (i.e. haemodynamic) environment, which plays a crucial role in the localised occurrence of atherosclerosis near vessel bends and bifurcations. In these areas, disturbed haemodynamics lead to flow separation and very low wall shear stress (WSS), which directly affects the functionality of the endothelium and impedes the transport of important blood borne agonists and antagonists. Detailed full field measurements assessing complex haemodynamics are sparse and consequently this thesis aims to address some of the important questions related to arterial haemodynamics and CVD by performing in-vitro flow measurements in physiologically relevant conditions. In particular, this research develops and uses state-of-the-art Particle Image Velocimetry (PIV) techniques to measure three-dimensional velocity and WSS fields in scaled models of the human carotid artery. For this purpose, the necessary theoretical and experimental concepts are developed and in-depth analyses of the underlying factors affecting the local haemodynamics and their relation to CVD are carried out. In the first part, a methodology for the construct of transparent hydraulic flow phantoms from medical imaging data is developed. The arterial geometries are reproduced in optically clear silicone and the flowing blood is modelled with a refractive index matched blood analogue. Subsequently, planar and Stereo-PIV techniques are developed and verified. A novel interfacial PIV (iPIV) technique is introduced to directly measure WSS by inferring the velocity gradient from the recorded particle images. The new technique offers a maximal achievable resolution of 1 pixel and therefore removes the resolution limit near the wall usually associated with PIV. Furthermore, the iPIV performance is assessed on a number of numerical and experimental test cases and iPIV offers a significantly improved measurement accuracy compared to more traditional techniques. Subsequently, the developed methodologies are applied in three studies to characterise the velocity and WSS fields in the human carotid artery under a number of physiological and experimental conditions. The first study focuses on idealised vessel geometries with and without disease and establishes a general understanding of the haemodynamic environment. Secondly, a physiological accurate vessel geometry under pulsatile flow conditions is investigated to provide a more realistic representation of the true in-vivo flow conditions. The prevailing flow structure in both cases is characterised by flow separation, strong secondary flows and large spatial and temporal variations in WSS. Large spatial and temporal differences exist between the different geometries and flow conditions; spatial variations appear to be more significant than transient events. Thirdly, the three-dimensional flow structure in the physiological carotid artery model is investigated by means of stereoscopic and tomographic PIV, permitting for the first time the measurement of the full 3D-3C velocity field and shear stress tensor in such geometries. The flow field within the model is complex and three-dimensional and inherently determined by the vessel geometry and the build up of an adverse pressure gradient. The main features include strong heliocoidal flow motions and large spatial variations in WSS. Lastly, the physiological implications of the current results are discussed in detail and reference to previous work is given. In summary, the present research develops a novel and versatile PIV methodology for haemodynamic in vitro studies and the functionality and accuracy is demonstrated through a number of physiological relevant flow measurements. Experimental Fluid Mechanics Particle Image Velocimetry Blood Flow In-Vitro Measurements Wall Shear Stress Carotid Artery
259	Novel Immersed Interface Method for Solving the Incompressible Navier-Stokes Equations Brehm, Christoph January 2011 (has links) For simulations of highly complex geometries, frequently encountered in many fields of science and engineering, the process of generating a high-quality, body-fitted grid is very complicated and time-intensive. Thus, one of the principal goals of contemporary CFD is the development of numerical algorithms, which are able to deliver computationally efficient, and highly accurate solutions for a wide range of applications involving multi-physics problems, e.g. Fluid Structure Interaction (FSI). Immersed interface/boundary methods provide considerable advantages over conventional approaches, especially for flow problems containing moving boundaries.In the present work, a novel, robust, highly-accurate, Immersed Interface Method (IIM) is developed, which is based on a local Taylor-series expansion at irregular grid points enforcing numerical stability through a local stability condition. Various immersed methods have been developed in the past; however, these methods only considered the order of the local truncation error. The numerical stability of these schemes was demonstrated (in a global sense) by considering a number of different test-problems. None of these schemes used a concrete local stability condition to derive the irregular stencil coefficients. This work will demonstrate that the local stability constraint is valid as long as the DFL-number does not reach a limiting value. The IIM integrated into a newly developed Incompressible Navier-Stokes (INS) solver is used herein to simulate fully coupled FSI problems. The extension of the novel IIM to a higher-order method, the compressible Navier-Stokes equations and the Maxwell's equations demonstrate the great potential of the novel IIM.In the second part of this dissertation, the newly developed INS solver is employed to study the flow of a stalled airfoil and steady/unsteady stenotic flows. In this context, a new biglobal stability analysis approach based on solving an Initial Value Problem (IVP), instead of the traditionally used EigenValue Problem (EVP), is presented. It is demonstrated that this approach based on an IVP is computationally less expensive compared to EVP approaches while still capturing the relevant physics. Floquet immersed moving boundary Navier-Stokes Equations Aerospace Engineering biglobal blood flow
260	Enhanced Vasculature Imaging of the Retina Using Optical Coherence Tomography Hendargo, Hansford January 2013 (has links) <p>Optical coherence tomography (OCT) is a non-invasive imaging modality that uses low coherence interferometry to generate three-dimensional datasets of a sample's structure. OCT has found tremendous clinical applications in imaging the retina and has demonstrated great utility in the diagnosis of various retinal diseases. However, such diagnoses rely upon the ability to observe abnormalities in the structure of the retina caused by pathology. By the time an ocular disease has progressed to the point of affecting the morphology of the retina, irreversible vision loss in the eye may already occur. Changes in the functionality of the tissue often precede changes to the structure. Thus, if imaging methods are developed to provide additional functional information about the behavior and response of the retinal tissue and vasculature, earlier treatment for disease may be prescribed, thus preserving vision for the patient. </p><p>Within the last decade, significant technological advances in OCT systems have enabled high-speed and high sensitivity image acquisition using either spectral domain OCT (SDOCT) or swept-source OCT (SSOCT) configurations. Such systems use Fourier processing to extract structural information of a sample from interferometric principles. But such systems also have access to the optical phase information, which allows for functional analysis of sample dynamics. This dissertation details the development and application of methods using both intensity and phase information as a tool for studying interesting biological phenomena. The goal of this work is an extension of techniques to image the vasculature in the retina and enhance the clinical utility of OCT.</p><p>I first outline basic theory necessary for understanding the principles of OCT. I then describe OCT phase imaging in cellular applications as a demonstration of the ability of OCT to provide functional information on biological dynamics. Phase imaging methods suffer from an artifact known as phase wrapping, and I have developed a software technique to overcome this problem in OCT, thus extending its usefulness in providing quantitative information. I characterize the limitations in measuring moving scatterers with Doppler OCT in both SDOCT and SSOCT system. I also show the ability to image the vasculature in the retina using variance imaging with a high-speed retinal imaging system and software based methods to correct for patient motion and create a widefield mosaic in an automated manner. Finally, future directions for this work are discussed.</p> / Dissertation Biomedical engineering Medical imaging and radiology Ophthalmology Blood flow Medical instrumentation Optical coherence tomography Phase Imaging Retina

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