Mapping microvasculature with acoustic angiography yields quantifiable differences between healthy and tumor-bearing tissue volumes in a rodent model.
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Towards Dynamic Contrast Specific Ultrasound Tomography.The "Fingerprint" of Cancer Extends Beyond Solid Tumor Boundaries: Assessment With a Novel Ultrasound Imaging Approach.3-D Ultrasound Localization Microscopy for Identifying Microvascular Morphology Features of Tumor Angiogenesis at a Resolution Beyond the Diffraction Limit of Conventional UltrasoundUltrasound imaging of breast tumor perfusion and neovascular morphology.Quantification of Microvascular Tortuosity during Tumor Evolution Using Acoustic AngiographyOptimization of Contrast-to-Tissue Ratio Through Pulse Windowing in Dual-Frequency "Acoustic Angiography" ImagingOn the relationship between microbubble fragmentation, deflation and broadband superharmonic signal production.Design factors of intravascular dual frequency transducers for super-harmonic contrast imaging and acoustic angiography.Quantitative analysis of vascular heterogeneity in breast lesions using contrast-enhanced 3-D harmonic and subharmonic ultrasound imagingFunctional ultrasound imaging for assessment of extracellular matrix scaffolds used for liver organoid formationA preliminary engineering design of intravascular dual-frequency transducers for contrast-enhanced acoustic angiography and molecular imagingVascular channels formed by subpopulations of PECAM1+ melanoma cells.Recent developments in dynamic contrast-enhanced ultrasound imaging of tumor angiogenesis.Dual-frequency piezoelectric transducers for contrast enhanced ultrasound imagingVolumetric contrast-enhanced ultrasound imaging of renal perfusionCurrent status and prospects for microbubbles in ultrasound theranostics.Dual-frequency acoustic droplet vaporization detection for medical imagingMolecular Acoustic Angiography: A New Technique for High-resolution Superharmonic Ultrasound Molecular ImagingAdaptive windowing in contrast-enhanced intravascular ultrasound imaging.Diagnostic accuracy of contrast-enhanced ultrasound for characterization of kidney lesions in patients with and without chronic kidney disease.High Resolution Ultrasound Superharmonic Perfusion Imaging: In Vivo Feasibility and Quantification of Dynamic Contrast-Enhanced Acoustic Angiography.Real-time ultrasound angiography using superharmonic dual-frequency (2.25MHz/30MHz) cylindrical array: In vitro study.Early Assessment of Tumor Response to Radiation Therapy using High-Resolution Quantitative Microvascular Ultrasound Imaging.Toward optimization of in vivo super-resolution ultrasound imaging using size-selected microbubble contrast agents.Contrast Enhanced Superharmonic Imaging for Acoustic Angiography Using Reduced Form-Factor Lateral Mode Transmitters for Intravascular and Intracavity Applications.Dual-Frequency Piezoelectric Endoscopic Transducer for Imaging Vascular Invasion in Pancreatic Cancer.Contrast-enhanced ultrasound tractography for 3D vascular imaging of the prostateMonitoring of tumor vascular normalization: the key points from basic research to clinical applicationImproved Sensitivity in Ultrasound Molecular Imaging With Coherence-Based Beamforming
P2860
Q28597984-FEDA824B-09CC-4014-A91D-25B4FEBCEDE6Q30357641-43A31D8B-BCF3-46E9-8D80-A9909D04BCDEQ30367056-85CCBA9C-BFF4-4D33-B282-95312F4A06F6Q30375552-CF609CFA-C304-40C5-9680-80C659E084FFQ30380570-D31D0115-339B-4205-B94E-DFFF4B1309F0Q30380572-E12123AC-E87B-4A2B-8A9B-61F3CC0EF42AQ30382620-9B168CC6-D8AC-49F0-9DE9-D9CB6C7CBA82Q30383977-AD2D0AF1-858B-4C9A-8000-C0A316A120F5Q30389658-34AE03A3-6267-4A12-981C-CCA693D4DC47Q30401300-F8BF2875-1C8A-4A8A-8B76-5762A0EDDB11Q30411969-C19B692E-4576-41C8-B175-4033B27F0B3BQ30413784-88B51D06-C474-4D02-8685-42FF59209EE9Q30419728-6DAB88D3-2D81-4952-A77E-3E645E3FA0D6Q30420852-39D0F510-B604-4542-B4A4-56219038AB9CQ30432873-ED0574B0-DF6F-4147-A18E-00C4E1F8CA99Q30435874-4FC7C645-6FB9-419B-85FA-4139397C69DEQ33898022-DEFCC2B6-C8E8-42E8-AC53-2AB9747FD3A1Q38810997-D10F4BFA-A67A-479E-829B-8173CF8ABC76Q39781650-DEE8DB39-CCDC-4BF9-96F2-5138CC44FDADQ41337070-21D42382-2224-44C7-A666-2E0E1159E4B7Q44868107-82410B97-F4E8-426C-BDF7-45E243CD9D11Q44875620-8141634C-BCE5-4EB8-9124-F89C20EDD0DCQ47135426-A6146CE9-2296-46EA-9C93-92973CDFCB76Q47184117-8192F199-1022-464F-B04E-71D886996273Q50323425-224113DE-AC30-46A4-82F9-6F6F34C5B57BQ50881296-1D492621-6894-49E1-9BBE-32E241207CAFQ57050270-E79146BA-1691-4C12-83F6-3A7A9FD7D2A1Q57484416-A5944EBF-B83F-458A-9F49-6A76FCE19C52Q57575147-A86A5255-8E16-4451-BF17-6308C4A9A636
P2860
Mapping microvasculature with acoustic angiography yields quantifiable differences between healthy and tumor-bearing tissue volumes in a rodent model.
description
2012 nî lūn-bûn
@nan
2012 թուականի Յուլիսին հրատարակուած գիտական յօդուած
@hyw
2012 թվականի հուլիսին հրատարակված գիտական հոդված
@hy
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
name
Mapping microvasculature with ...... sue volumes in a rodent model.
@ast
Mapping microvasculature with ...... sue volumes in a rodent model.
@en
type
label
Mapping microvasculature with ...... sue volumes in a rodent model.
@ast
Mapping microvasculature with ...... sue volumes in a rodent model.
@en
prefLabel
Mapping microvasculature with ...... sue volumes in a rodent model.
@ast
Mapping microvasculature with ...... sue volumes in a rodent model.
@en
P2093
P2860
P356
P1433
P1476
Mapping microvasculature with ...... sue volumes in a rodent model.
@en
P2093
Paul A Dayton
Ryan C Gessner
Stephen R Aylward
P2860
P304
P356
10.1148/RADIOL.12112000
P407
P577
2012-07-06T00:00:00Z