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Imaging Reactive Oxygen Species-Induced Modifications in Living Systems.Modeling the envelope statistics of three-dimensional high-frequency ultrasound echo signals from dissected human lymph nodes.Encapsulated contrast microbubble radial oscillation associated with postexcitation pressure peaksUltrasonic contrast agent shell rupture detected by inertial cavitation and rebound signalsEcho-power estimation from log-compressed video data in dynamic contrast-enhanced ultrasound imaging.US backscatter and attenuation 30 to 50 MHz and MR T2 at 3 Tesla for differentiation of atherosclerotic artery constituents in vitro.High resolution ultrasound elastomicroscopy imaging of soft tissues: system development and feasibility.Clinical relevance of contrast-enhanced ultrasound in monitoring anti-angiogenic therapy of cancer: current status and perspectives.VEGFR2-Targeted Contrast-Enhanced Ultrasound to Distinguish between Two Anti-Angiogenic Treatments.Local Transverse-Slice-Based Level-Set Method for Segmentation of 3-D High-Frequency Ultrasonic Backscatter From Dissected Human Lymph Nodes.Noninvasive contrast-enhanced US quantitative assessment of tumor microcirculation in a murine model: effect of discontinuing anti-VEGF therapy.Real-time chirp-coded imaging with a programmable ultrasound biomicroscope.High-frequency ultrasound detection and follow-up of Wilms' tumor in the mouse.Automatic motion estimation using flow parameters for dynamic contrast-enhanced ultrasound.The performance of PEGylated nanocapsules of perfluorooctyl bromide as an ultrasound contrast agent.Fast in vivo imaging of amyloid plaques using μ-MRI Gd-staining combined with ultrasound-induced blood-brain barrier opening.Ultrasound biomicroscopy: a powerful tool probing murine lymph node size in vivo.Characterization of atherosclerotic plaque components by high resolution quantitative MR and US imaging.Quantification of tumor perfusion using dynamic contrast-enhanced ultrasound: impact of mathematical modeling.In Vivo Multiparametric Ultrasound Imaging of Structural and Functional Tumor Modifications during Therapy.Blood flow quantification with contrast-enhanced US: "entrance in the section" phenomenon--phantom and rabbit study.Correlation of ultrasonic attenuation (30 to 50 MHz and constituents of atherosclerotic plaque.Correlation and agreement between contrast-enhanced ultrasonography and perfusion computed tomography for assessment of liver metastases from endocrine tumors: normalization enhances correlation.Reproducibility of Contrast-Enhanced Ultrasound in Mice with Controlled Injection.A multiplicative model for improving microvascular flow estimation in dynamic contrast-enhanced ultrasound (DCE-US): theory and experimental validation.Impact of Recirculation in Dynamic Contrast-Enhanced Ultrasound: A Simulation StudyRANKL Induces Organized Lymph Node Growth by Stromal Cell ProliferationNoncontact Evaluation of Articular Cartilage Degeneration Using a Novel Ultrasound Water Jet Indentation SystemParametric (integrated backscatter and attenuation) images constructed using backscattered radio frequency signals (25-56 MHz) from human aortae in vitroReproducibility of skin characterization with backscattered spectra (12--25 MHz) in healthy subjectsOptimizing an ultrasound contrast agent's stability using in vitro attenuation measurementsParametric analysis of carotid plaque using a clinical ultrasound imaging systemHigh-frequency (20 to 40 MHz) acoustic response of liquid-filled nanocapsulesDual-mode registration of dynamic contrast-enhanced ultrasound combining tissue and contrast sequencesContrast-enhanced ultrasound after devascularisation of neuroendocrine liver metastases: functional and morphological evaluation
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Q30381432-1064BCC5-D4D1-493F-95F4-832D2CF5610BQ30427783-933F635D-2220-4E0B-9799-7BF99D97B3B8Q30477284-CCEC8043-4B2A-4561-9F17-629D325A2D75Q30500618-395B49C9-DE18-4BBB-89D7-53D8BBD4FAECQ30656883-16A2405A-CAC1-49F4-82AB-99CBED022A4CQ30840746-B69646AD-F814-430E-B7DD-B793A95F59EDQ33207731-D4B85E64-28EC-4BE2-8558-895E0C33415DQ37527337-80ADFDA7-CBFE-47E4-AB9F-5085D18BC03EQ38874224-4491179F-94F3-4E55-AF52-545759A296DAQ39005233-CF1ABA42-A89A-46D8-80C8-5D7CA86A3A84Q39749217-117DAC30-F866-4C04-B90C-2B4611264764Q39902289-82A46943-E097-41D8-B1E2-386EBAED02BEQ40319519-5B7E6CA1-3D22-4B59-9344-CF08B23DC8F9Q41434250-6B7EDE37-89E9-4B86-97ED-FF7B4578AD7AQ43233535-F8A8BF56-BDA6-4A13-AF1E-3CF83AA90CF6Q45327900-E86049B4-397A-4668-A9FF-B5C7B262DD9AQ47184886-2014E42D-1348-46D4-B15E-1C5181482B76Q47974060-35488A1C-2C90-4434-B46A-6A52DAD03446Q50531296-C1C59AB0-50F7-406F-971E-E9BE003BC07CQ50859963-19453B1D-3773-4B2E-B0AE-D334B6EAEFEFQ52014466-E40465CC-124B-4FBA-B49F-1D841F4E6951Q52283062-F218AA75-9EC0-44B9-846E-7B14D0A5A491Q53097975-921395DD-4639-4AB3-8BEA-12ECB48DA5EAQ53122944-60F4EC31-4C15-484A-8621-EC7E321F38D8Q54698800-BDE42C52-82E6-465E-A2F2-F19A05D374A9Q57866990-A78BD2C3-DB68-4D02-ACB7-F5969B2EF728Q61051808-07FB19D7-344C-4080-83F7-55B3F38FB9A2Q62711039-DBF8CA05-D589-43CA-A977-B59E9820FEF1Q73317282-D4DE39B7-1F22-4412-9C55-833AC80546C3Q73990618-C57D8A83-BD8A-49F3-857A-D978E98A89A6Q78558316-D99EDD2C-426F-4932-B595-87C026D99CBFQ79342073-08A83E0D-347E-4ACF-8B16-10DE896D1950Q87056787-F9537028-0629-4D69-85A6-6B112D18D02FQ87295156-4EF6945C-F4FA-4366-B71E-E1FFB3705500Q87354841-8B196C92-9D11-46A1-89D3-6F721D9FCD1B
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
S. Lori Bridal
@ast
S. Lori Bridal
@en
S. Lori Bridal
@es
S. Lori Bridal
@nl
S. Lori Bridal
@sl
type
label
S. Lori Bridal
@ast
S. Lori Bridal
@en
S. Lori Bridal
@es
S. Lori Bridal
@nl
S. Lori Bridal
@sl
prefLabel
S. Lori Bridal
@ast
S. Lori Bridal
@en
S. Lori Bridal
@es
S. Lori Bridal
@nl
S. Lori Bridal
@sl
P106
P31
P496
0000-0001-5053-5423