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1 mor proliferation status), Photoacoustic and Ultrasound imaging.
2 h fine-needle aspiration and staging through ultrasound imaging.
3 es of the brachial artery by high-resolution ultrasound imaging.
4 provide a means to assess inflammation with ultrasound imaging.
5 ery disease (CAD) using serial intravascular ultrasound imaging.
6 neurogenesis, using a retroviral vector and ultrasound imaging.
7 were not clearly visible during conventional ultrasound imaging.
8 combined hyperlipidemia, using intravascular ultrasound imaging.
9 ity, and plaque assessed via repeated B-mode ultrasound imaging.
10 Aortic dilatation was monitored by ultrasound imaging.
11 ent all-optical rotational B-mode pulse-echo ultrasound imaging.
12 ency-domain diffuse optical spectroscopy and ultrasound imaging.
13 ventional method for performing high-quality ultrasound imaging.
14 ing as an electronic reporter during medical ultrasound imaging.
15 toring acoustic object manipulation via live ultrasound imaging.
16 perior colliculus, as measured by functional ultrasound imaging.
17 NAFLD was confirmed to use ultrasound imaging.
18 on-culprit segments using NIRS-intravascular ultrasound imaging.
19 xamination and tactile sensation) as well as ultrasound imaging.
20 ng elements can be read out by point-of-need ultrasound imaging.
21 calise anatomical regions of interest during ultrasound imaging.
22 rom limitations associated with transcranial ultrasound imaging.
23 natomically representative environment using ultrasound imaging.
24 ical probe is viable for clinical rotational ultrasound imaging.
25 estinal tissues ex vivo, tracked by x-ray or ultrasound imaging.
26 rofacial movements in marmoset monkeys using ultrasound imaging.
27 treatment, and tumor burden was monitored by ultrasound imaging.
28 Work-up includes thyroid function tests and ultrasound imaging.
29 ubble-DNA mix and in vivo sonoporation under ultrasound imaging.
30 patic fibrosis in patients was examined with ultrasound imaging.
31 ere monitored by bioluminescence imaging and ultrasound imaging.
32 One of such techniques is ultrasound imaging.
33 st of optical methods with the resolution of ultrasound imaging.
34 shed as highly effective contrast agents for ultrasound imaging.
35 uation of atheroma burden with intravascular ultrasound imaging.
36 classification of burn depth based on B-mode ultrasound imaging.
37 h an adrenal lesion discovered on diagnostic ultrasound imaging.
38 al trials that employed serial intravascular ultrasound imaging.
39 cedure was guided and monitored by real-time ultrasound imaging.
40 he immediacy and accuracy of intra-operative ultrasound imaging.
43 freedom is critical for applications such as ultrasound imaging, acoustic manipulation, and stimulati
44 d in 3,392 participants using carotid artery ultrasound imaging acquired over a mean of 9 y (1.7 y).
46 with that produced by conventional harmonic ultrasound imaging after injections of low doses (0.0025
47 bles could therefore be used for noninvasive ultrasound imaging after laser activation without induci
48 near-infrared spectroscopy and intravascular ultrasound imaging after successful percutaneous coronar
49 ere useful for learning basic concepts about ultrasound imaging, allowing students to significantly i
50 , after thrombolysis with urokinase, LIBS-MB ultrasound imaging allows monitoring of the reduction of
52 ransducer elements to provide both 2D B-mode ultrasound imaging and 3D ultrasonic needle tracking.
55 cus on developing standardized protocols for ultrasound imaging and consider further research into th
56 chart review, preintervention intravascular ultrasound imaging and coronary angiography were used to
57 at was measured using computed tomography or ultrasound imaging and DNA methylation was assessed at >
59 he left coronary artery with high-resolution ultrasound imaging and echocardiographic definition of t
64 rse applications such as loudspeaker design, ultrasound imaging and therapy or acoustic particle mani
65 The former was borrowed from developments in ultrasound imaging and was proven suitable with either t
66 sing endobronchial ultrasound and endoscopic ultrasound imaging, and curative-intent lung resection w
69 onse imaging than with conventional harmonic ultrasound imaging (anterior: 37 +/- 20 U transient resp
70 n tomography, X-ray computed tomography, and ultrasound imaging) are described as well as the possibi
75 between LRPs detected by NIRS-intravascular ultrasound imaging at unstented sites and subsequent cor
79 in this are the MyotonPRO and rehabilitative ultrasound imaging, both have shown to be reliable in pr
81 ecretion profile, supporting the notion that ultrasound imaging can be used for nondestructive macrop
83 r-infrared spectroscopy (NIRS) intravascular ultrasound imaging can detect lipid-rich plaques (LRPs).
84 The proliferation of portable and low-cost ultrasound imaging can improve global health and also en
85 ssues with light or sound, photoacoustic and ultrasound imaging can provide anatomical, functional, a
86 Subsequently, we demonstrate that nonlinear ultrasound imaging can selectively monitor macrophage ac
87 ry to measure coronary flow velocity, and an ultrasound imaging catheter was introduced over the Dopp
88 t utilizing in vivo whole animal imaging and ultrasound imaging combined with ex vivo approaches incl
93 ased on the follow-up coronary intravascular ultrasound imaging data, we performed patient-specific m
97 aortic root diameters using high-resolution ultrasound imaging display significantly decreased aorti
98 male mice in resting state using functional ultrasound imaging during plantar exposure to constant a
100 steering and visibility in optoacoustic and ultrasound imaging, enabling the development of the next
101 hieves the resolution of 0.24 wavelengths in ultrasound imaging experiments and 0.2 wavelengths in si
103 0.9 for peripheral artery disease (PAD), and ultrasound imaging for carotid artery stenosis (CAS) >50
105 indings highlight the potential of ultrafast ultrasound imaging for intra-operative CAR monitoring, p
107 r algorithms employing biomarkers to trigger ultrasound imaging for screening also show promise.
115 Utilizing the first in-human functional ultrasound imaging (fUSI) of the spinal cord, we demonst
124 ageal electrical impedance and intra-luminal ultrasound imaging - have improved our understanding of
128 oronary artery with the use of intracoronary ultrasound imaging in 22 heart-lung transplant recipient
129 artery with high resolution two-dimensional ultrasound imaging in 48 patients with chronic heart fai
130 % apparently symptomatic carotid stenosis on ultrasound imaging in consecutive patients with carotid
132 ta were available with respect to the use of ultrasound imaging in patients with spondyloarthropathy.
134 deep learning may facilitate the adoption of ultrasound imaging in screening mammography workflows.
135 oundwork for the implementation of molecular ultrasound imaging in vessels with high shear stress and
138 ssessment is recommended for MR when routine ultrasound imaging information is insufficient or discor
139 Catheter-based high-frequency intraluminal ultrasound imaging is a powerful tool to study esophagea
140 ated to sympathetic nerve function with WISW ultrasound imaging is a valuable adjunct to the visual a
142 minal aortic aneurysm (AAA) rupture is poor, ultrasound imaging is an accurate and reliable test for
159 cles used as contrast agents for noninvasive ultrasound imaging must be formulated to be stable, and
160 erwent angioscopy (n = 40) and intravascular ultrasound imaging (n = 46) during interventional proced
163 through progress in the areas of endoluminal ultrasound imaging of esophageal varices and noninvasive
169 ve assessment of inflammation is possible by ultrasound imaging of microbubbles targeted to activated
170 combination of blood flow and permeability, ultrasound imaging of microvascular flow rate is sensiti
171 herapy was performed by serial power Doppler ultrasound imaging of murine tumors treated with recombi
172 ific membrane antigen (PSMA-targeted NBs) in ultrasound imaging of prostate cancer (PCa) in vivo usin
173 ry somatosensory cortex (S1) with functional ultrasound imaging of S1 and caudal insular (INS) cortic
179 umin microbubbles with intermittent harmonic ultrasound imaging of the forearm deep flexor muscles.
180 scientific basis for the clinical use of 3D ultrasound imaging of the heart and discuss its potentia
183 ssue was assessed by contrast-enhanced renal ultrasound imaging of the kidneys of mice undergoing isc
184 bined hyperlipidemia underwent intravascular ultrasound imaging of the left anterior descending coron
186 eting ligands for targeted contrast-enhanced ultrasound imaging of tumor angiogenesis with small, con
189 ovasculature using conventional line-by-line ultrasound imaging on a preclinical and commercially ava
190 udent or technician with prior experience in ultrasound imaging or in performing in vivo procedures.
191 current data on remodeling, based on in vivo ultrasound imaging or postmortem histologic analysis of
192 riables present on angioscopy, intravascular ultrasound imaging or quantitative coronary arteriograph
193 cal ultrasound (OpUS) imaging is an emerging ultrasound imaging paradigm that uses an array of fibre-
196 t is difficult to accurately correlate micro-ultrasound imaging planes with ground truth whole-mount
201 t of 47 patients with baseline intracoronary ultrasound imaging recordings, were analyzed (mean 3.8 y
207 mor-specific targeting of the nanoworms, and ultrasound imaging showed reduced blood flow in tumor ve
209 er biopsy specimens were detected (2/8), and ultrasound imaging showed the development of splenomegal
210 ic mouse model of cancer, the B7-H3-targeted ultrasound imaging signal was increased significantly in
211 cificity studies (n = 26 tumors) showed that ultrasound imaging signal was significantly higher (P <
213 n-flight experimental technologies (handheld ultrasound imaging, smartwatch wearables and immune prof
214 acoustic subwavelength imaging in biomedical ultrasound imaging, sonar, and nondestructive testing.
215 imaging (OAI), a combination of optical and ultrasound imaging, specifically raster-scanning optoaco
219 d microbubbles were passively detected by an ultrasound imaging system and processed offline using a
220 and Drug Administration (FDA) to approve one ultrasound imaging system for use in making breast biops
221 We report the first use of a novel 40-MHz ultrasound imaging system in the study of mouse cardiac
224 A composite catheter system (phased-array ultrasound imaging system mounted on a catheter with ext
225 esent a real-time clinical photoacoustic and ultrasound imaging system which consists of an FDA-appro
226 murine models of FNAIT and a high-frequency ultrasound imaging system, we found that ICH only occurr
228 e development of automated three-dimensional ultrasound imaging systems that promise to revolutionize
229 ed microbubbles may thus offer a noninvasive ultrasound imaging technique for the detection of acute
230 y thus offer a noninvasive contrast-enhanced ultrasound imaging technique for the functional imaging
231 ture cardiovascular events, but conventional ultrasound imaging techniques cannot distinguish between
232 sound has also led to the development of new ultrasound imaging techniques that result in excellent m
235 advances in microbubble contrast agents and ultrasound imaging technology have allowed new clinical
239 microscopy (ULM) is a recent advancement in ultrasound imaging that uses microbubble contrast agents
241 beams have potential applications in medical ultrasound imaging, therapeutic ultrasound, as well as a
242 scopy systems are inherently compatible with ultrasound imaging, thereby enabling multimodality imagi
243 l-contrast agents for both photoacoustic and ultrasound imaging through optically triggered vaporizat
244 ine, free thyroxine, thyroid autoantibodies, ultrasound imaging, thyroid scintigraphy, and fine-needl
245 er-frame motion artifacts in high-frame-rate ultrasound imaging to achieve a more accurate visualizat
247 xperiments include PET and contrast-enhanced ultrasound imaging to assess morphology, vascularization
256 In this study, we used contrast-enhanced ultrasound imaging to quantify intraspinal vascular disr
258 herapy for HCC that is typically paired with ultrasound imaging to visualize tumors and enable precis
259 dy were to determine whether a new method of ultrasound imaging (transient response imaging) could im
260 one session, participants (n = 13) underwent ultrasound imaging (US), followed by knee extension maxi
262 sibility of intraoperative contrast-enhanced ultrasound imaging was further tested in a cohort of 27
272 ostintervention and follow-up) intravascular ultrasound imaging was used to study 212 native coronary
273 focal microscopy, protein assays, and B-mode ultrasound imaging, we demonstrate that drug release fro
274 marrow transplantation and super-resolution ultrasound imaging, we demonstrated that SCD mice overex
277 raft tumors measured by microbubble-enhanced ultrasound imaging were substantially increased after tr
278 to the use of magnetic resonance imaging or ultrasound imaging when diagnostic uncertainty remains,
279 e in ferret auditory cortex using functional ultrasound imaging, which enables large-scale, high-reso
280 ed noninvasive microbubble contrast-enhanced ultrasound imaging, which revealed that sunitinib reduce
281 the regionalized perfusion deficits seen on ultrasound imaging, which were co-localized with amyloid
285 s achieved simultaneous 3D photoacoustic and ultrasound imaging with optimal imaging performance in d
286 This review examines the current state of ultrasound imaging with respect to spondyloarthritis and
287 condition, we propose to perform a follow-up ultrasound imaging within 1-2 days, and not to extend di
288 e fibre-optic ultrasound detector to perform ultrasound imaging without the need for electrical compo
289 primate (NHP) skull fragments using harmonic ultrasound imaging without using ionizing radiation.