ライフサイエンスコーパス: vascular image

1 nd vessel length were calculated for retinal vascular images.

2 nt recently used for magnetic resonance (MR) vascular imaging.

3 research, and positron emission tomographic vascular imaging.

4 hy and FCA among those subjects who received vascular imaging.

5 blood perfusion was reduced as documented by vascular imaging.

6 d specific educational components of CMR and vascular imaging.

7 use formal educational curricula for CMR and vascular imaging.

8 cell arteritis is most commonly diagnosed by vascular imaging.

9 ed the diagnostic and therapeutic aspects of vascular imaging.

10 ve the quality, workflow, and reliability of vascular imaging.

11 significant improvements in many aspects of vascular imaging.

12 nical developments in cardiac, thoracic, and vascular imaging.

13 Most favorably for vascular imaging, [(18)F]5j exhibited low uptake in meta

14 Of 1368 eligible patients with intracranial vascular imaging, 241 (17.6%) had 385 50-99% symptomatic

15 ith tumors in host animals injected with the vascular imaging agent gadolinium also being enhanced le

16 Applying image registration to vascular image allows multiple images to be strengthened

17 Emerging evidence based on ultrasonographic vascular imaging and angiogenic biomarkers implicates an

18 management strategies were evaluated: (a) no vascular imaging and best medical management, (b) CT ang

19 d registry of patients with FMD confirmed by vascular imaging and currently enrolling at 14 participa

20 isplays favorable pharmacokinetics for early vascular imaging and enables specific detection of infla

21 a, Europe, and the USA, with early brain and vascular imaging and follow up.

22 has routinely involved punch skin biopsies, vascular imaging and graft appearance.

23 With ongoing advancements in noninvasive vascular imaging and high-throughput genomics, we have t

24 us contrast enhancement dramatically improve vascular imaging and resolution within the prostate.

25 the current training environment in CMR and vascular imaging and the recommendations of COCATS-2.

26 cardiovascular magnetic resonance (CMR) and vascular imaging and to quantify the magnitude of any ga

27 timodality imaging technology, molecular and vascular imaging, and clinical guidelines with appropria

28 hy, EF5 immunostaining, Hoechst fluorescence vascular imaging, and hematoxylin-and-eosin histology-we

29 ates some predictive value for hypertension, vascular imaging, and polymorphisms affecting components

30 This in vivo vascular imaging approach is valuable in monitoring norm

31 selection criteria, use of optimal brain and vascular imaging, appropriate devices for recanalization

32 ve imaging and clinical education, including vascular imaging as well as cardiac.

33 care networks, the question of the need for vascular imaging at the RHs remains unsolved, resulting

34 fits in reduction of delay before treatment, vascular imaging-based triage of patients with large-ves

35 CTA) is widely used for non-invasive retinal vascular imaging, but the OCTA methods used to assess re

36 Use of iodinated contrast for vascular imaging can be associated with nephrotoxicity a

37 Vascular imaging can be challenging because of the wide

38 delta(max) and lambda--readily obtained from vascular images, capture these differences and link vasc

39 Despite frequently observed vascular imaging changes in individuals with TBI, the re

40 Retinal layer segmentation and resultant vascular image compared with vessels as seen in histolog

41 hagic manifestations were also observed, but vascular imaging did not demonstrate overt abnormalities

42 atheter manipulation, as well as specialized vascular imaging equipment.

43 We focused on four main vascular imaging features and risk factors: microbleeds;

44 e (>1200 nm) enables high-resolution in vivo vascular imaging, further enhanced by AI-driven imaging

45 No vascular imaging had the highest cost and lowest health

46 The advancements that have been made in vascular imaging have enabled improvement in diagnosis a

47 ained renal ECM scaffolds were processed for vascular imaging, histology, and cell seeding to investi

48 and largely externalized phosphatidylserine; vascular images illustrate MP biogenesis and their manif

49 hy followed by immediate thrombectomy and no vascular imaging in 55-year-old patients compared with $

50 iew explores the current uses of noninvasive vascular imaging in LVV.

51 otential use for CO2 as a contrast agent for vascular imaging in patients with suboptimal renal funct

52 Emergency vascular imaging, including arteriography and venography

53 r findings suggest that in certain subgroups vascular imaging, including collateral assessment, can p

54 hod, we were able to visualize the PA ocular vascular image intuitively and demonstrate layer-by-laye

55 In addition, vascular imaging is also crucial for longitudinal survei

56 es when more detailed three-dimensional (3D) vascular imaging is required, or when ultrasound windows

57 In retinal vascular images, local thresholds tended to incorrectly

58 Vascular imaging makes it possible to quantify the numbe

59 isk plaque in vivo; however, these important vascular imaging methods additionally promise great scie

60 Non-invasive vascular imaging methods that could be used to identify

61 Therefore, different vascular imaging modalities are used in management of su

62 of molecular probes for alternative in vivo vascular imaging modalities, but few options for genetic

63 ence tomography angiography is a noninvasive vascular imaging modality that clearly depicts the loopi

64 Here, we provide the first vascular images obtained with laser-polarized 3He.

65 M revealed high contrast and high resolution vascular imaging of the retina and choroid with amplifie

66 a prospective cohort evaluating the role of vascular imaging on cardiovascular risk prediction.

67 ptimal renal function who require definitive vascular imaging or therapy.

68 eld MSOT was found to be capable of clinical vascular imaging, providing visualization of major blood

69 Two neuroradiologists evaluated vascular image quality and arterial stenoses.

70 Vascular image quality was sufficient for diagnosis or e

71 The proposed vascular image registration method based on network stru

72 In this work, providing vascular imaging results did not improve diet but did im

73 ted large-vessel occlusion in the absence of vascular imaging results in worse health outcomes and hi

74 Provision of non-invasive vascular imaging results to individuals has been shown t

75 Of 667 subjects, 525 had known vascular imaging results, and 53% of those (n=277) had a

76 label-free, high resolution, and wide-field vascular imaging, revealed the absence of both capillary

77 Vascular imaging should be mandated in future endovascul

78 troke-specialist assessment, urgent MRI, and vascular imaging should now be considered, with monitori

79 Across contrast changes, retinal vascular images showed the lowest repeatability and CC i

80 Early CT Score (ASPECTS) greater than 4, and vascular imaging showing moderate-to-good collateral fil

81 Superb micro-vascular imaging (SMI) was used as an MVUS technique in

82 al animal studies, human biomarker data, and vascular imaging studies provide support for proceeding

83 Whether carotid ultrasound and other vascular imaging studies should be performed routinely f

84 Vascular imaging studies were performed at least yearly

85 e. punch skin biopsies, DSA and conventional vascular imaging studies) are inadequate for detecting t

86 utcome was receipt of a vascular assessment (vascular imaging study or revascularization procedure) i

87 isk factor assessment, as well as a complete vascular imaging study that was performed blinded to the

88 Electrophysiological studies and vascular imaging suggest an ON-limited infarct with subs

89 ing whole brain CT perfusion and concomitant vascular imaging, suggest that age has a differential ef

90 essible alternatives to expensive commercial vascular imaging systems by providing comprehensive tool

91 disease activity is challenging, progress in vascular imaging techniques and the measurement of labor

92 Conventional vascular imaging techniques for analysis of intracranial

93 to the widespread use of noninvasive in vivo vascular imaging techniques is the current lack of suita

94 Magnetic resonance imaging and vascular imaging techniques play a critical role in iden

95 at uses microbubble contrast agents to yield vascular images that break the classical diffraction lim

96 Real-time vascular imaging that provides both anatomic and hemodyn

97 After a review of basic considerations in vascular imaging, the established methods for nonenhance

98 /MRI, cardiac MRI, congenital heart disease, vascular imaging, thoracic imaging, artificial intellige

99 /MRI, Cardiac MRI, Congenital Heart Disease, Vascular Imaging, Thoracic Imaging, Artificial Intellige

100 imaging platforms are available for targeted vascular imaging to acquire information on both anatomy

101 vity DNA sequencing in blood and noninvasive vascular imaging to investigate the interplay between cl

102 gy applications, including material science, vascular imaging, vaccine development, and targeted drug

103 Vascular imaging was not a requirement in the trials.

104 By fluorescent vascular imaging, we provide evidence that the vasculatu

105 In addition to connectivity images, vascular images were simultaneously acquired.

106 ithout stenting, and those with intracranial vascular imaging were analysed in our study, which asses

107 Histological, immunofluorescent, and 3D vascular imaging were used to evaluate glomerular, tubul

108 ed breast MRI, and it may increase access to vascular imaging while reducing examination cost.

109 Vascular imaging with color and power Doppler is a usefu

110 multimodality pipeline that enables ex vivo vascular imaging with magnetic resonance imaging, comput

111 Retinal vascular imaging with pvOCT provides accurate measuremen

112 ultaneous electrophysiological recording and vascular imaging with transcriptomic analysis in rats, a