Global ETD Search

11	Mantle flow through a tear in the Nazca slab inferred from shear wave splitting Lynner, Colton, Anderson, Megan L., Portner, Daniel E., Beck, Susan L., Gilbert, Hersh 16 July 2017 (has links) A tear in the subducting Nazca slab is located between the end of the Pampean flat slab and normally subducting oceanic lithosphere. Tomographic studies suggest mantle material flows through this opening. The best way to probe this hypothesis is through observations of seismic anisotropy, such as shear wave splitting. We examine patterns of shear wave splitting using data from two seismic deployments in Argentina that lay updip of the slab tear. We observe a simple pattern of plate-motion-parallel fast splitting directions, indicative of plate-motion-parallel mantle flow, beneath the majority of the stations. Our observed splitting contrasts previous observations to the north and south of the flat slab region. Since plate-motion-parallel splitting occurs only coincidentally with the slab tear, we propose mantle material flows through the opening resulting in Nazca plate-motion-parallel flow in both the subslab mantle and mantle wedge. shear wave splitting flat slab slab tear mantle dynamics
12	Dual-Probe Shear Wave Elastography in a Transversely Isotropic Phantom Bassan, Gioia January 2015 (has links) Shear Wave Elastography (SWE) is an ultrasound based technique which is able to measure tissue stiffness through the speed of induced shear waves. Tissue stiffness is often related to pathological conditions and detecting mechanical changes can help the recognition of potential diseases. The clinical use of SWE is limited to isotropic tissue due to the difficulty in assessing a theoretical model for more complex tissue and this project therefore aimed to evaluate the possibility of obtaining a full mechanical characterization of a transversely isotropic (TI) phantom with dual-probe SWE. A TI hydrogel phantom was developed and mechanical tests were performed to verify its anisotropy and determine the elastic moduli in both the perpendicular and longitudinal directions. Shear moduli were estimated using conventional and dual-probe SWE comparing the results to theoretical pure-transverse (PT) and quasi-transverse (QT) wave propagation modes. Both mechanical and SWE tests showed that the phantoms were transversely isotropic ET/EL=0.81. Moreover, multiple wave propagation modes calculated with dual-probe SWE showed a good agreement with the theoretical curves and indicated the possibility of measuring all the elasticity constants needed to fully characterize an incompressible, TI tissue with dual-probe SWE. Shear Wave Elastography Transversely isotropic phantom Medical Engineering Medicinteknik
13	VERIFICATION OF SHEAR WAVE VELOCITY BASED LIQUEFACTION CRITERIA USING CENTRIFUGE MODEL Gang, Liu 03 December 2008 (has links) No description available. LIQUEFACTION Earthquake CENTRIFUGE Soils SHEAR WAVE Vs1 SHEAR
14	Novel muscle imaging in inflammatory rheumatic diseases — a focus on ultrasound shear wave elastography and quantitative MRI 27 April 2021 (has links) Yes / In recent years, imaging has played an increasing role in the clinical management of patients with rheumatic diseases with respect to aiding diagnosis, guiding therapy and monitoring disease progression. These roles have been underpinned by research which has enhanced our understanding of disease pathogenesis and pathophysiology of rheumatology conditions, in addition to their key role in outcome measurement in clinical trials. However, compared to joints, imaging research of muscles is less established, despite the fact that muscle symptoms are very common and debilitating in many rheumatic diseases. Recently, it has been shown that even though patients with rheumatoid arthritis may achieve clinical remission, defined by asymptomatic joints, many remain affected by lingering constitutional systemic symptoms like fatigue, tiredness, weakness and myalgia, which may be attributed to changes in the muscles. Recent improvements in imaging technology, coupled with an increasing clinical interest, has started to ignite new interest in the area. This perspective discusses the rationale for using imaging, particularly ultrasound and MRI, for investigating muscle pathology involved in common inflammatory rheumatic diseases. The muscles associated with rheumatic diseases can be affected in many ways, including myositis—an inflammatory muscle condition, and myopathy secondary to medications, such as glucocorticoids. In addition to non-invasive visual assessment of muscles in these conditions, novel imaging techniques like shear wave elastography and quantitative MRI can provide further useful information regarding the physiological and biomechanical status of the muscle. / This research is funded by the NIHR infrastructure at Leeds. Muscle Myositis Myopathy MRI Ultrasound Shear wave elastography Imaging Rheumatic
15	Study on the Application of Shear-wave Elastography to Thin-layered Media and Tubular Structure: Finite-element Analysis and Experiment Verification / Shear-wave Elastography法の薄板状と円筒状の媒質への適用に関する研究：有限要素解析と実験的検証 Jang, Jun-keun 23 September 2016 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(人間健康科学) / 甲第19970号 / 人健博第38号 / 新制\|\|人健\|\|3(附属図書館) / 33066 / 京都大学大学院医学研究科人間健康科学系専攻 / (主査)教授杉本直三, 教授精山明敏, 教授黒田知宏 / 学位規則第4条第1項該当 / Doctor of Human Health Sciences / Kyoto University / DFAM Arterial Wall Stiffness Shear Wave Elastography Shear Wave Velocity Estimation Dispersion Effect Guided Waves Leaky Lamb Waves 498
16	Analyse des facteurs pronostics d’efficacité du traitement de la spasticité par injection de toxine botulinique. De l’analyse du muscle spastique en imagerie ultrasonore à l’immunisation post injection de toxine botulinique / Analysis of prognostic efficacy factors for the treatment of limb spasticity with botulinum toxin injection. From spastic muscle ultrasound analysis to immunization post botulinum toxin injections Mathevon, Laure 05 June 2018 (has links) Notre objectif était de rechercher une méthode d’évaluation musculaire afin de déterminer des facteurs de non réponse tissulaire à une injection de toxine botulique (TB) dans un muscle spastique, chez l’adulte post AVC et chez l’enfant paralysé cérébral (PC). Une étude de reproductibilité et 3 revues systématiques de la littérature ont été réalisées. Les mesures échographiques de l’épaisseur et de l’angle des pennation des fibres du muscle gastrocnémien médial en 2D sont reproductibles. La mesure du module d’élasticité par Shear Wave Ultrasound Elastography délivre une information fiable sur la rigidité du muscle gastrocnémien médial spastique au repos.L’analyse du devenir du muscle post-injection rapporte que la TB participe au remodelage du muscle spastique avec une atrophie persistante, répétition d’injections dépendante.L’étude de l’impact des traitements adjuvants à la TB chez l’enfant PC montre que le renforcement musculaire intensif, y compris des muscles injectés, permet de lutter contre l’atrophie sans renforcer la spasticité. Les plâtres d’allongement permettent d’optimiser le fonctionnement articulaire mais les preuves sur la diminution de la raideur musculaire restent faibles. Dans la description des facteurs pronostics d’efficacité, plus de la moitié des patients identifiés comme secondairement non-répondeurs à la TB dans la spasticité des membres ne sont pas immunisés contre la TB. Les anticorps neutralisants ne sont donc pas la principale cause de non-réponse secondaire. Une évaluation de la qualité musculaire échographique comme facteur pronostic de réponse à la TB et pour mesurer l’impact des traitements adjuvants devrait être réalisée régulièrement afin de déterminer à quel moment ces traitements ne sont plus favorables au système musculaire. / The aim was to investigate a muscle evaluation method to determine tissue factors leading to non-responsiveness to an injection of botulinum toxin (BTX) into a spastic muscle in adult post stroke and children with cerebral palsy (CP). A reproducibility study and 3 systematic literature reviews were carried out. 2D ultrasound measurements of thickness and pennation angle of medialis gastrocnemius muscle fibers are reproducible. Measurement of the modulus of elasticity by shear wave ultrasound elastography provides a reliable information about the rigidity of the spastic medial gastrocnemius muscle at rest.Analysis of the post-injection muscle fate found that BTX participates in the remodeling of the spastic muscle with persistent atrophy that is dependent on the repetition of the injections.Analysis of the impact of BTX adjuvant therapies in CP children showed that intensive muscle strengthening, including of the injected muscles, may help combat atrophy without increasing spasticity. Stretching casts are used to optimize joint function, but there is little evidence for a reduction in muscle stiffness. In the description of prognostic efficacy factors, more than half of patients identified as secondariy non-responders to BTX in limb spasticity tests were not immunized against BTX. Neutralizing antibodies were therefore not the main cause for secondary non-responsiveness. An ultrasound evaluation of muscle quality as a prognostic factor for BTX response and to measure the impact of adjuvant treatments must be regularly performed to determine when these treatments are no longer favourable for the muscle system. Muscle spastique Toxine botulique Structure Élasticité 2D ultrasound Par Shear Wave Elastography Spastic muscle Botulinum toxin Structure Elasticity 2D ultrasound Shear Wave Elastography
17	Anisotropic Muscle Phantoms for Shear Wave Elastography Assessment of the Levator Ani Muscle Properties / Anisotropiska muskelfantomer för utvärdering av levator ani-muskeln med skjuvvågselastografi Koxha, Bleona, Jova Martinez, Melissa January 2023 (has links) Pelvic floor disorder is an emerging research area and is highlighted in many pelvic floor studies. Assessment methods for this type of injury are lacking and new methods for prevention and diagnosis are needed. Pelvic floor disorders are common among women and can lead to suffering for the patient. Levator ani muscle injuries are the main cause for pelvic floor disorders. This muscle group is an anisotropic skeletal muscle that helps support the pelvic viscera. Assessment of this muscle is difficult due to its complex geometry and location. Therefore, two muscle phantoms were constructed to mimic different properties of the levator ani muscle. The muscle phantoms provided more availability and a more controlled setting. The muscle phantoms were examined using ultrasound-based shear wave elastography which is an elastography method that can help determine the elasticity of tissue. A PVA-graphite phantom and a water-based gelatine-graphite phantom, both with fishing lines network as fibers for anisotropy, were constructed in this project. Shear wave elastography results of the PVA phantom indicated no anisotropy but visually resembled a muscle. Although not achieving anisotropy, the shear modulus of the PVA did match the shear modulus of skeletal muscle tissue. Shear wave elastography results of the gelatine phantom indicated anisotropy but visually did not resemble a muscle due to the low shear modulus of the gelatine. A 3D model of the female bony pelvis, that was provided for this project, was measured, and compared with reference value of previous study for future construction and 3D printing of the model. Results of measurements showed similarities between the 3D model and the female pelvis except for the sagittal outlet which had a deviant value. For future work, the muscle phantom can be developed by applying the complex geometry of the levator ani muscle, assembly of the muscle phantom, and the 3D rendering of the pelvis. The combination of these two parts provides a more complete phantom where shear wave elastography can be applied in the same way as in female patients. / Bäckenbottenbesvär är ett framväxande forskningsområde och lyfts fram i många bäckenbottenstudier. Bedömningsmetoder för denna typ av skador saknas och det behövs nya metoder för förebyggande och diagnostik. Bäckenbottenbesvär är vanliga bland kvinnor och kan leda till lidande för patienten. Levator ani muskelskador är den främsta orsaken till bäckenbottensjukdomar. Denna muskelgrupp är en anisotrop skelettmuskel som hjälper till att stödja inälvorna i bäckenet. Bedömning av denna muskel är svår på grund av dess komplexa geometri och läge. Därför konstruerades två muskelfantomer för att efterlikna olika egenskaper hos levator ani-muskeln. Muskelfantomerna gav mer tillgänglighet och en mer kontrollerad inställning. Muskelfantomerna undersöktes med hjälp av ultraljudsbaserad skjuvvågselastografi som är en metod som kan hjälpa till att bestämma vävnadens elasticitet. En PVA-grafitfantom och en vattenbaserad gelatin-grafitfantom, båda med fiskelinsnätverk som fibrer för anisotropi, konstruerades i detta projekt. Resultat från skjuvvågselastografi på PVA-fantomen indikerade ingen anisotropi, men liknade visuellt en muskel. Även då anisotropi inte uppnåddes, så matchade skjuvmodulen för PVA skjuvmodulen för skelettmuskelvävnad. Resultat från skjuvvågselastografi på gelatinfantomen indikerade anisotropi dock visade resultatet ingen visuell liknelse av en skelettmuskel på grund av gelatinets låga skjuvmodul. En 3D modell av bäckenbenet, som förseddes det här projektet, mättes och jämfördes med referensvärde av tidigare studie för framtid 3D friformsframställning av modellen. Resultat av mätningar visade på liknelser mellan 3D modellen och det kvinnliga bäckenbenet förutom sagittal outlet som hade ett avvikande värde. Inför fortsättning av det här projektet kan en utveckling av muskel fantomen ske genom applicering av den komplexa geometrin hos levator ani muskeln samt sammansättning av muskel fantomen och 3D framställningen av bäckenbenet. Sammansättningen av dessa två delar ger en mer komplett fantom där skjuvvågselastografi kan appliceras på samma sätt som hos kvinnliga patienter. / Ja pelvic floor disorder levator ani muscle shear wave elastography phantom anisotropy polyvinyl alcohol bäckenbottenbesvär levator ani muskel shear wave elastografi fantom anisotropi polyvinylalkohol Medical Engineering Medicinteknik
18	SHEAR-WAVE IMAGING AND BIREFRINGENCE IN A COMPLEX NEAR-SURFACE GEOLOGICAL ENVIRONMENT Almayahi, Ali Z. 01 January 2013 (has links) Multiple geophysical and geological data sets were compiled, reprocessed, and interpreted using state-of-the-art signal processing and modeling algorithms to characterize the complex post-Paleozoic geology that overlies the southwestern projection of the Fluorspar Area Fault Complex (FAFC) in western Kentucky. Specific data included 21.5 km of SH-wave seismic reflection, 1.5 km of P-wave seismic reflection, 2 km of electrical resistivity, vertical seismic profiles, Vp and Vs sonic-suspension logs, and 930 lithologic borehole logs. The resultant model indicates three general northeast–southwest-oriented fault zones pass through the study area as southwestern extensions of parts of the FAFC. These fault zones form two significant subparallel grabens with ancillary substructures. The geometry of the interpreted fault zones indicates that they have undergone episodic tectonic deformation since their first formation. Evidence of thickening and steeply dipping reflectors within Tertiary and Quaternary sediment in the downthrown blocks indicate syndepositional movement. Subtle thickening and lack of steeply dipping intraformational reflectors in the Cretaceous suggest a more quiescent period, with sediment deposition unconformably draping and filling the earlier Paleozoic structural surface. There is also evidence that the Tertiary and early Quaternary reactivation was associated with an extensional to compressional regional stress reversal, as manifested by the antiformal folds seen in the hanging wall reflectors and the potential small-amplitude force folds in the Quaternary alluvium, as well as a clear displacement inversion along the Metropolis-loess seismic horizon in two high-resolution reflection images. A surface shear-wave splitting experiment proved to be an efficient and effective tool for characterizing shallow subsurface azimuthally anisotropic geologic inclusions in low-impedance water-saturated sediment environments. The measured azimuthal anisotropy across a well-constrained N60ºE-striking fault exhibited a natural coordinate system that had a fast direction coincident with the fault strike and an orthogonal slow direction. This is also one indicator that faults inactive during significant geologic intervals (i.e., Holocene) do not "heal". Integrated shear-wave velocity models and electrical resistivity tomography profiles across the fault zones exhibit lower shear-wave velocities and resistivities within the deformation zones compared with values outside the boundaries. This is additional evidence that the deformed sediment does not reconsolidate or heal, but that the sediment particle configuration remains more loosely packed, providing an increase in the overall porosity (i.e., hydraulic conductivity). This can wholly or in large part explain the anomalous contaminant plume migration path that is coincident with the deformed zones of the regional gravel groundwater aquifer. Geophysics and Seismology
19	Mapping Myocardial Elasticity with Intracardiac Acoustic Radiation Force Impulse Methods Hollender, Peter J. January 2014 (has links) <p>Implemented on an intracardiac echocardiography transducer, acoustic radiation force methods may provide a useful means of characterizing the heart's elastic properties. Elasticity imaging may be of benefit for diagnosis and characterization of infarction and heart failure, as well as for guidance of ablation therapy for the treatment of arrhythmias. This thesis tests the hypothesis that with appropriately designed imaging sequences, intracardiac acoustic radiation force impulse (ARFI) imaging and shear wave elasticity imaging (SWEI) are viable tools for quantification of myocardial elasticity, both temporally and spatially. Multiple track location SWEI (MTL-SWEI) is used to show that, in healthy in vivo porcine ventricles, shear wave speeds follow the elasticity changes with contraction and relaxation of the myocardium, varying between 0.9 and 2.2 m/s in diastole and 2.6 and 5.1 m/s in systole. Infarcted tissue is less contractile following infarction, though not unilaterally stiffer. Single-track-location SWEI (STL-SWEI) is proven to provide suppression of speckle noise and enable improved resolution of structures smaller than 2 mm in diameter compared to ARFI and MTL-SWEI. Contrast to noise ratio and lateral edge resolution are shown to vary with selection of time step for ARFI and arrival time regression filter size for STL-SWEI and MTL-SWEI. </p><p>In 1.5 mm targets, STL-SWEI achieves alternately the tightest resolution (0.3 mm at CNR = 3.5 for a 0.17 mm filter) and highest CNR (8.5 with edge width = 0.7 mm for a 0.66 mm filter) of the modalities, followed by ARFI and then MTL-SWEI.</p><p>In larger, 6 mm targets, the CNR-resolution tradeoff curves for ARFI and STL-SWEI overlap for ARFI time steps up to 0.5 ms and kernels $\leq$1 mm for STL-SWEI. STL-SWEI can operate either with a 25 dB improvement over MTL-SWEI in CNR at the same resolution, or with edge widths 5$\times$ as narrow at equivalent CNR values, depending on the selection of regression filter size. Ex vivo ablations are used to demonstrate that ARFI, STL-SWEI and MTL-SWEI each resolve ablation lesions between 0.5 and 1 cm in diameter and gaps between lesions smaller than 5 mm in 3-D scans. Differences in contrast, noise, and resolution between the modalities are discussed. All three modalities are also shown to resolve ``x''-shaped ablations up to 22 mm in depth with good visual fidelity and correspondence to surface photographs, with STL-SWEI providing the highest quality images. Series of each type of image, registered using 3-D data from an electroanatomical mapping system, are used to build volumes that show ablations in in vivo canine atria. In vivo images are shown to be subject to increased noise due to tissue and transducer motion, and the challenges facing the proposed system are discussed. Ultimately, intracardiac acoustic radiation force methods are demonstrated to be promising tools for characterizing dynamic myocardial elasticity and imaging radiofrequency ablation lesions.</p> / Dissertation Biomedical engineering Acoustic Radiation Force Elasticity Intracardiac Echocardiography Shear Wave Elasticity Imaging Ultrasound
20	Imaging and modeling the cardiovascular system Maksuti, Elira January 2016 (has links) Understanding cardiac pumping function is crucial to guiding diagnosis, predicting outcomes of interventions, and designing medical devices that interact with the cardiovascular system. Computer simulations of hemodynamics can show how the complex cardiovascular system is influenced by changes in single or multiple parameters and can be used to test clinical hypotheses. In addition, methods for the quantification of important markers such as elevated arterial stiffness would help reduce the morbidity and mortality related to cardiovascular disease. The general aim of this thesis work was to improve understanding of cardiovascular physiology and develop new methods for assisting clinicians during diagnosis and follow-up of treatment in cardiovascular disease. Both computer simulations and medical imaging were used to reach this goal. In the first study, a cardiac model based on piston-like motions of the atrioventricular plane was developed. In the second study, the presence of the anatomical basis needed to generate hydraulic forces during diastole was assessed in heathy volunteers. In the third study, a previously validated lumped-parameter model was used to quantify the contribution of arterial and cardiac changes to blood pressure during aging. In the fourth study, in-house software that measures arterial stiffness by ultrasound shear wave elastography (SWE) was developed and validated against mechanical testing. The studies showed that longitudinal movements of the atrioventricular plane can well explain cardiac pumping and that the macroscopic geometry of the heart enables the generation of hydraulic forces that aid ventricular filling. Additionally, simulations showed that structural changes in both the heart and the arterial system contribute to the progression of blood pressure with age. Finally, the SWE technique was validated to accurately measure stiffness in arterial phantoms. / <p>QC 20161115</p> Cardiac pumping diastolic function hemodynamics modeling simulation arterial stiffness ultrasound shear wave elastography.

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