ライフサイエンスコーパス: angiogram

1 ization (ie, abnormal postoperative coronary angiogram).

2 h (LURIC) study (2579 patients with coronary angiograms).

3 essels on either color images or fluorescein angiograms).

4 SSADA scans that would match the fluorescein angiogram.

5 tenoses requiring PCI were identified on the angiogram.

6 patients, and 70% of patients had at least 1 angiogram.

7 MAA deposition and compared with the mapping angiogram.

8 e fovea in the early and later phases of the angiogram.

9 ow velocity reserve assessment, and coronary angiogram.

10 d not help in the decision of early coronary angiogram.

11 o the anatomic information obtained from the angiogram.

12 ing, and (b) a high-spatial-resolution renal angiogram.

13 overlapped the hyperfluorescent spots in the angiogram.

14 ted to the LAD and had an evaluable coronary angiogram.

15 vascular risk factor assessment and coronary angiogram.

16 d, therefore, benefit from emergent coronary angiogram.

17 ge, and nonperfusion detected by fluorescein angiogram.

18 ar density (CCVD) was quantified from the CC angiogram.

19 g 1986-2015 with at least 1 post-HT coronary angiogram.

20 erization laboratory and the patient's final angiogram.

21 uter retinal angiogram, and choriocapillaris angiogram.

22 791 HF patients undergoing elective coronary angiogram.

23 obstructive coronary artery disease found on angiogram.

24 ained eligible after central review of their angiograms.

25 translation of said non-contrast-enhanced MR angiograms.

26 r radiologists for precise interpretation of angiograms.

27 spicuity on phase-contrast three-dimensional angiograms.

28 g of table motion, and compared well with CT angiograms.

29 ients had normal postoperative graft-related angiograms.

30 remaining 91 patients (35.7%) with abnormal angiograms.

31 gnetic resonance imaging and/or conventional angiograms.

32 (IR) photographs and indocyanine green (ICG) angiograms.

33 ed on both color photographs and fluorescein angiograms.

34 by angiography; 15 patients (30%) had normal angiograms.

35 st material-enhanced magnetic resonance (MR) angiograms.

36 SSFP images but not on contrast-enhanced MR angiograms.

37 3D SSFP images than for contrast-enhanced MR angiograms.

38 sed on the full retina vasculature using OCT angiograms.

39 nhanced dipolar fields were observed on IRON angiograms.

40 ulated from conventional digital subtraction angiograms.

41 ime for quantitative analysis of fluorescein angiograms.

42 mments regarding indeterminate reading of CT angiograms.

43 sor testing (CPT) in 71 patients with normal angiograms.

44 images that are indistinguishable from real angiograms.

45 agnostic LHC procedures; 97.3% were coronary angiograms.

46 thm removed flow projection artifacts in OCT angiograms.

47 d with that shown in intravenous fluorescein angiograms.

48 iograms and clinically indicated fluorescein angiograms.

49 than 1% of all selective bronchial arterial angiograms.

50 FE MR angiography were compared with pelvic angiograms.

51 phy (OCT), automated visual field (AVF), and angiograms.

52 of RetCam fundus photographs and fluorescein angiograms.

53 paticoenteric arterial anatomy recognized on angiograms (16%).

54 mm isotropic voxels) breath-hold 3D renal MR angiogram (18 mL) over the full abdominal field of view.

55 We included 492 pulmonary CT angiograms (342 (69.9%) in patients with COVID-19 and 14

56 s identified incidentally in 8 of 16 femoral angiograms (50%) undertaken before closure device placem

57 compared with 2 control groups without prior angiogram, 72 LT recipients matched for cardiovascular r

58 ntly better than those with PMI and abnormal angiograms (74.9 +/- 2.9%; P<0.001 log-rank).

59 nce of choroidal spots on infracyanine green angiograms (80.0% vs 53.3%, P = .08) seemed associated w

60 giograms than on conventional T1-weighted MR angiograms (9.0 +/- 2.5, P < .001 vs IRON MR angiography

61 The value of a routine completion angiogram after CABG and 1-stop hybrid CABG/PCI remains

62 ort our experience with a routine completion angiogram after coronary artery bypass surgery (CABG) an

63 umen was signal attenuated on T1-weighted MR angiograms after MION-47 injection, while IRON supported

64 Catheter tracking within dynamic left atrial angiograms allowed nearly nonfluoroscopic creation of Na

65 FFR(angio) measured from the coronary angiogram alone has a high sensitivity, specificity, and

66 The en face angiograms also showed areas of reduced choroidal flow a

67 atterns than were visible on the fluorescein angiograms although within a more posterior field of vie

68 all of 10 human cardiac computed tomographic angiograms analyzed.

69 efect size) but who did not have a left-side angiogram and could have undiagnosed significant coronar

70 eement between the vascular areas in the OCT angiogram and FA had a kappa value of 0.45 (95% CI, 0.21

71 eement of the avascular area between the OCT angiogram and FA.

72 g within 5 days, with one positive pulmonary angiogram and four positive lower-limb US scans.

73 se patients have generally a normal coronary angiogram and left ventricular dysfunction, which extend

74 MRI included coronary magnetic resonance angiogram and LGE vessel wall imaging with 1.5 T (n=12)

75 ist regarding the benefit of urgent coronary angiogram and percutaneous coronary intervention (PCI) a

76 purely anatomic score based on the coronary angiogram and predicts outcome after PCI in patients wit

77 comes, DCI, 3-month outcomes or quantitative angiogram and TCD analyses were seen in this small safet

78 d acquisition of a perfectly coregistered CT angiogram and venous phase-enhanced CT scan simultaneous

79 on with immediate hospital monitoring led to angiogram and/or intravascular ultrasonography, which co

80 Side-by-side comparison of research MIOCT angiograms and clinically indicated fluorescein angiogra

81 The MR angiograms and CT angiograms did not differ significantl

82 Quantitative analyses of angiograms and daily transcranial Doppler (TCD) were per

83 , SD-OCT images were compared to fluorescein angiograms and histologic sections with immunostaining a

84 Their angiograms and magnetic resonance images were evaluated,

85 Baseline fundus fluorescein angiograms and OCT images were graded for choroidal neov

86 transfemoral access for diagnostic coronary angiograms and percutaneous coronary interventions (PCI)

87 al branches was observed on time-resolved MR angiograms and that up to fifth-order branches was obser

88 ured on transverse computed tomographic (CT) angiograms and virtual angioscopic views, with the manuf

89 gistry (n=600, n=231 with available coronary angiogram) and compared with the frequency of CAE in the

90 ence calculated from computerized tomography angiograms) and their matching recipients.

91 ress test, computerized tomographic coronary angiogram, and cardiovascular magnetic resonance imaging

92 g the inner retinal angiogram, outer retinal angiogram, and choriocapillaris angiogram.

93 stress test result (n=67) underwent coronary angiogram, and significant coronary artery disease (>/=7

94 nfluoroscopic chamber mapping within dynamic angiograms, and for 4-dimensional tagging of anatomical

95 fluoroscopy time, contrast volume, number of angiograms, and radiation dose).

96 t for obstructive CAD with invasive coronary angiogram as a reference standard.

97 ence of coronary culprit lesions on coronary angiograms as analyzed by independent interventional car

98 -slice coronary computed tomography coronary angiogram at the time of phlebotomy, on average 4 hours

99 erwent preoperative and 1-year postoperative angiograms at 2 centers had each of their coronary steno

100 Digital color photographs and fluorescein angiograms at baseline and 1 and 2 years were evaluated

101 Fewer angiograms at diagnostic only centers showed obstructive

102 was present in 17 (46.0%) reference coronary angiograms, at a median of 1.9 years before CCTA.

103 icipants according to the experience in FFR, angiogram-based decisions were less frequent with increa

104 applied prospectively to digital fluorescein angiograms (baseline and day 71) obtained on 12 patients

105 erotic stenosis for 3-dimensional rotational angiograms before and after intensive medical therapy fo

106 tively whether patients with normal coronary angiograms but with impaired myocardial blood flow (MBF)

107 ence interval, 1.18-1.35), as did having the angiogram by an interventional cardiologist (odds ratio,

108 iphery that were obscured in the fluorescein angiograms by fluorescein staining from underlying, pree

109 Noncontact ultra-wide-field oral fluorescein angiograms captured using the Optos Panoramic 200MA fluo

110 ere used to obtain 3 x 3-mm and 6 x 6-mm OCT angiograms centered at the macula.

111 Fluorescein angiogram characteristics included staining without leak

112 surprisingly well preserved or intact by OCT angiogram compared with that shown in intravenous fluore

113 ve image quality of low-voltage half-dose CT angiograms compared with standard-dose FBP CT images for

114 , nonfatal myocardial infarction, CHD death, angiogram-confirmed angina pectoris, coronary artery byp

115 Cerebral angiogram, craniotomy, and gastrostomy were independentl

116 all structure of the aortic aneurysm from CT angiograms (CTA) was compared against a generic 3-D U-Ne

117 physiology derived from conventional biplane angiogram data may be useful in guiding percutaneous cor

118 y-seven LT recipients with history of pre-LT angiogram (December 2005 to December 2012) were compared

119 Magnetic resonance angiogram demonstrated cerebrovascular lesions resemblin

120 the technical quality of the upper extremity angiograms demonstrated mean attenuation values of 244 H

121 Review of angiograms demonstrated NV in 30.0% and 37.5% in the IVB

122 The MR angiograms and CT angiograms did not differ significantly in any scoring c

123 new technique that produces cine projection angiograms directly analogous to those of x-ray angiogra

124 ce (coronal, C-scan) OCT image and of an ICG angiogram, displayed side by side and superimposed, perm

125 eived a donor with a negative preprocurement angiogram, donor age only had a borderline association w

126 rom images of a C-arm rotational aortic root angiogram during breath-hold, rapid ventricular pacing,

127 e recruited and classified based on coronary angiogram examination as control (n = 105) and CAD (n =

128 g, fundus photography (FP), OCT, fluorescein angiogram (FA), and fundus autofluorescence (FAF).

129 %, P = .04), vascular leakage on fluorescein angiograms (FA) (44.4% vs 12.5%, P = .03), absence of ma

130 Fluorescein angiograms (FA) and OCT were evaluated by an independent

131 nter measured the area of RNP on fluorescein angiograms (FAs) in 2 phase III trials investigating the

132 ital color photographs (CPs) and fluorescein angiograms (FAs) taken at baseline and years 1, 2, and 5

133 olor fundus photography (CF) and fluorescein angiograms (FAs).

134 ctural data were combined in composite color angiograms for both en face and cross-sectional views.

135 scans to generate 3-dimensional en-face OCT angiograms for each eye.

136 onsensus retrospectively reviewed all the CT angiograms for evidence of arterial injury.

137 raders examined 3-layer PR-OCTA and combined angiograms for nonperfusion and abnormal capillaries.

138 retrospective review of a representative OCT angiogram from 1 patient and an evaluation of the vascul

139 ne this, we obtained posttransplant coronary angiograms from a group of patients bridged with VAD and

140 ading methods in the analysis of fluorescein angiograms from patients with choroidal neovascularizati

141 alysis (QFA) software was used to analyze 62 angiograms from patients with CNV for whom distance visu

142 diac Surgery (SYNTAX) score (bSS) from 2,686 angiograms from patients with moderate- and high-risk ac

143 projection was used to obtain 2-dimensional angiograms from the 3 layers.

144 e revascularized CAD group was comparable to angiogram group without obstructive CAD, and both contro

145 or SCAD extension, and all 79 who had repeat angiogram >/=26 days later had spontaneous healing.

146 Six weeks later, LV angiograms, hemodynamics, and regional myocardial blood

147 assessment of leakage in retinal fluorescein angiogram images is important for the management of a wi

148 Twenty-eight ultra-widefield angiogram images of eyes with central retinal vein occlu

149 intravascular filling defects in fluorescein angiogram images.

150 ection propagation with an invasive coronary angiogram, improved CT scanner parameters, and predomina

151 by abdominal ultrasonography before coronary angiogram in 612 consecutive patients.

152 y bypass grafting within 7 days of the index angiogram in all patients with non-ST-segment-elevation

153 esults of computerized tomographic pulmonary angiogram in most cases (n = 1,654 [88%]).

154 to what is usually expected from a coronary angiogram in the present cohort.

155 tical volume were measured on renal donor CT angiograms in 111 patients.

156 ct layers were compared with the fluorescein angiograms in 12 healthy eyes from patients at a private

157 Follow-up angiograms in 1371 patients who underwent 4093 grafts re

158 , electrocardiographically gated coronary CT angiograms in 264 patients (159 men, 105 women; mean age

159 s), and coronary 64-section multidetector CT angiograms in 317 patients were reviewed (healthy group,

160 ings were consistent with correlative pelvic angiograms in all 16 patients for whom the latter were a

161 noncontact ultra-wide-field oral fluorescein angiograms in premature infants with retinopathy of prem

162 We reviewed the angiograms in the 2 groups for neovascularization (NV) a

163 Bleeding avoidance strategies before angiogram, including early angiography, may negate the n

164 judge when the cost and risk of an invasive angiogram may safely be avoided.

165 udy period, 1078 underwent emergent coronary angiogram (median age: 59.6 years, 78.3% males): 463 (42

166 iers) was observed in angiogram positive and angiogram negative groups compared to controls in a domi

167 gnificantly higher in angiogram positive and angiogram negative groups compared to the control group

168 Of the 1806 patients with CT angiograms negative for PE, 520 (28.79%) had no risk fac

169 uch as aneurysmal SAH (aSAH) or cryptogenic "angiogram-negative" SAH (cSAH) owing to overlapping clin

170 etrospectively reviewed all the extremity CT angiograms, noting the presence of vascular injury, and

171 who had no atherosclerosis on a coronary CT angiogram obtained concurrently during the PET/CT sessio

172 A total of 153 CT angiograms obtained from 45 retrospectively identified p

173 The 2 en face CC angiograms obtained from each scan pattern were compensa

174 ive study, the authors evaluated coronary CT angiograms obtained in 65 patients with normal sinus rhy

175 nter measured the area of RNP on fluorescein angiograms obtained in the phase 3 RISE and RIDE trials.

176 Coronary CT angiograms obtained with 64-detector row CT were retrosp

177 Upper extremity CT angiograms obtained with 64-section CT demonstrated adeq

178 ent with suspected stroke who underwent a CT-angiogram of the carotid arteries.

179 low index were computed from the en face OCT angiogram of the outer retinal layer.

180 We retrospectively studied the coronary angiograms of 882 siblings with CAD from 401 families.

181 nd compared them to post transplant coronary angiograms of a non-VAD cohort.

182 reviewed the medical histories and coronary angiograms of all adults <40 years of age who underwent

183 urately identify true and false lumina on CT angiograms of aortic dissection.

184 En face OCT angiograms of CNV showed sizes and locations that were c

185 sel density were calculated from the en face angiograms of each of the 3 plexuses, as well as from th

186 Fluorescein angiograms of the affected and fellow eyes were reviewed

187 MR angiograms of the chest, abdomen, or both, were assessed

188 st material-enhanced magnetic resonance (MR) angiograms of the peripheral vasculature.

189 This retrospective study analyzed all CT angiograms of the pulmonary arteries done in patients wi

190 Based on angiograms of the respective arteries acquired in >=2 di

191 tude-decorrelation angiography generated OCT angiograms of the retinal superficial and deep capillary

192 s and compared with conventional fluorescein angiograms of the same eyes.

193 mm region centered on the macula and en face angiograms of the superficial and deep vascular networks

194 artery segments were visible on conventional angiograms, of which 560 (93.3%) were seen by using sing

195 then performed five serial simulated carotid angiograms on the Vascular Interventional System Trainer

196 Hospitals were categorized into diagnostic angiogram only centers, stand-alone percutaneous coronar

197 was not higher in patients who underwent CT angiogram or those who received endovascular treatment.

198 erwent major amputation without a diagnostic angiogram or trial of revascularization in the preceding

199 al fluid at final evaluation, dye leakage on angiogram, or change in choroidal neovascular area.

200 atinine values, no or an incomplete coronary angiogram, or previous dialysis.

201 te en face views including the inner retinal angiogram, outer retinal angiogram, and choriocapillaris

202 A three-vessel diagnostic angiogram performed prior to MT led to a significant inc

203 onary artery bypass graft surgery and had an angiogram performed up to 18 months after surgery.

204 The characteristics of angiograms performed at the discretion of the treating p

205 Angiograms performed by invasive physicians had a lower

206 or 3-vessel disease) obtained from coronary angiograms performed no more than 1 day after the MI.

207 The number of angiograms performed to visualize proximal and distal la

208 e HSP70-2 G was also significantly higher in angiogram positive and angiogram negative groups compare

209 enotypes (G allele carriers) was observed in angiogram positive and angiogram negative groups compare

210 inarily unlikely (0.95% chance) to have a CT angiogram positive for PE.

211 Angiogram positive patients were subdivided into three g

212 Of the 197 patients with CT angiograms positive for PE, 192 (97.46%) had one or more

213 DA for eligible patients undergoing coronary angiogram procedures reduces decisional conflict and imp

214 ructures from a computerized tomography (CT) angiogram rely on contrast injection to enhance the radi

215 ned as limb amputation or revascularization, angiogram reporting vascular obstruction of 50% or great

216 duces perioperative errors and the number of angiograms required to deploy the stent graft, thereby r

217 ients with abnormal and normal postoperative angiograms, respectively (P=0.03).

218 51.0%) and 34 (13.3%) patients with abnormal angiograms, respectively.

219 At eight weeks, LV angiograms (rest and dobutamine stress) and histologic a

220 Up to 20% of all coronary angiograms reveal coronary chronic total occlusions (CTO

221 A fluorescence angiogram revealed fluorescence leakage at a turn near t

222 ICG angiograms revealed choriocapillaris loss in large lesio

223 Multimodal fundus pictures and angiograms revealed distinct clinical features of the di

224 or more individual plexuses, but on combined angiogram, sensitivity was 25.0% (95% CI, 12.7%-42.5%) f

225 ry perfusion territory was scored from x-ray angiograms separately.

226 s with angina-like chest pain whose coronary angiograms show no evidence of obstructive coronary arte

227 Diagnostic cerebral angiogram showed a small indirect Barrow type D right ca

228 g was also demonstrated in that the renal MR angiogram showed adequate or excellent portrayal of the

229 Retrospective review of digital subtraction angiogram showed an anastomosis between the left ophthal

230 Fundus flourescein angiogram showed hyperfluorescence due to window defect,

231 Masked retrospective grading of fluorescein angiograms showed an 11% decrease in AUC for fluorescenc

232 rison of fundus photographs with fluorescein angiograms showed that in 13/18 eyes (72%), atrophy deve

233 High-speed, high-magnification ICG angiograms showing individual cell movement were recorde

234 oral and popliteal veins; follow-up chest CT angiogram shows no evidence of pulmonary emboli.

235 duration of study drug administration before angiogram, smoking, ST-segment deviation>or=1 mm, and di

236 aded in blind fashion on 287 of 569 baseline angiograms (stenoses of 50-99% and adequate collateral v

237 ts without diabetes had 15,887 postoperative angiograms; stenosis was quantified for 7,903 internal t

238 sites were chosen according to the pulmonary angiogram still frames that were mounted in the operatin

239 OCT angiograms suggest that foveal hypoplasia is a phenocopy

240 n coronary venograms and computed tomography angiograms suggested that most have suitable venous anat

241 etrospectively analyzing digital fluorescein angiograms taken before and 3 months after photodynamic

242 ontrast-to-noise ratio was higher on IRON MR angiograms than on conventional T1-weighted MR angiogram

243 ients with clinical indications for coronary angiogram, the presence of NAFLD is associated with coro

244 With unsegmented retinal angiograms, the sensitivity and specificity were 78.7% (

245 iteal veins.Onchest computed tomography (CT) angiogram, there is a large right hilar mass and enlarge

246 s the patient's hemodynamic data and routine angiograms to generate a complete 3-dimensional coronary

247 The DJS was calculated from the coronary angiograms to quantify the myocardium at risk.

248 The en-face angiograms underwent additional automated quantitative a

249 from pretransplantation computed tomography angiograms using a three-dimensional computerized volume

250 Using a volume-rendered angiogram, vertebral arteries were measured along the cu

251 mount of retinal nonperfusion on fluorescein angiogram was calculated.

252 En face nerve fiber layer (NFL) plexus angiogram was generated.

253 A spinal angiogram was performed in our center demonstrating righ

254 The 3D angiogram was segmented into separate en face views incl

255 A conventional cerebral angiogram was unremarkable.

256 of vasospasm, as assessed on the most severe angiogram, was lowered with statin.

257 in fluoroscopy time for diagnostic coronary angiograms (weighted mean difference [WMD], fixed effect

258 gh November 2010 with pretransplant coronary angiogram were included in our study.

259 Patients undergoing emergent coronary angiogram were included.

260 Angiograms were analyzed (blinded to treatment) for Fitz

261 Angiograms were analyzed at a blinded core laboratory, a

262 cine, myocardial delayed enhancement, and MR angiograms were assessed for overall image quality and m

263 Angiograms were assessed manually.

264 rial phase and portal venous phase pelvic CT angiograms were evaluated for evidence of vascular injur

265 Angiograms were evaluated for lumen narrowing.

266 Angiograms were evaluated for the degree of pre- and pos

267 MR angiograms were evaluated for vascular definition.

268 Fluorescein angiograms were examined by 2 experts to document retina

269 Peripheral MR angiograms were generated in a group of 13 volunteers (e

270 Fluorescein angiograms were graded by masked observers.

271 Coronary angiograms were independently read by 3 reviewers blinde

272 Angiograms were independently reviewed for the presence,

273 PV angiograms were made before ablation, immediately after

274 The fluorescein angiograms were matched, with a mean proportion of the i

275 Overall, CT angiograms were negative for PE in 1806 (90.16%) of 2003

276 ted tomography scans and computed tomography angiograms were obtained at admission of all adult patie

277 SD OCT raster scans/fluorescein angiograms were obtained from 284 treatment-naive eyes o

278 In the study, 8,122 angiograms were performed in 3,120 patients, and 70% of

279 CT angiograms were positive for PE in 197 (9.84%) of 2003 p

280 Second, 5 complete angiograms were provided, presenting only focal intermed

281 Preoperative angiograms were read in consensus by two radiologists.

282 All coronary angiograms were reevaluated blinded for postresuscitatio

283 014) with baseline computed tomographic (CT) angiograms were retrospectively included.

284 Coronary angiograms were retrospectively reviewed and severity of

285 Angiograms were reviewed for coronary tortuosity and ass

286 Unenhanced CT scans and CT angiograms were reviewed for the presence of cervical in

287 ide-angle retina photographs and fluorescein angiograms were reviewed.

288 coronary risk factors) with normal coronary angiograms were studied.

289 High-resolution oral fluorescein angiograms were successfully obtained in 3 consecutive p

290 arteries, and overall image quality of TI CT angiograms were superior to those of standard CT angiogr

291 Cross-sectional angiograms were used to visualize CNV location relative

292 47 appeared signal attenuated on T1-weighted angiograms, while characteristic signal-enhanced dipolar

293 Vessels were extracted from MR angiograms with a computer program.

294 s was observed on high-spatial-resolution MR angiograms, with diagnostic-quality blood vessel definit

295 proposed GAN produces anatomically accurate angiograms, with similar fidelity to FA images, and sign

296 Patients undergoing coronary angiogram within 4 mo after SPECT myocardial perfusion i

297 l index >/=1.4 who underwent lower extremity angiograms within 1 year were included.

298 mal exercise treadmill test, normal coronary angiogram without other causes of microvascular dysfunct

299 r kerma-area product for diagnostic coronary angiograms (WMD, fixed effect: 1.72 Gy.cm(2), 95% CI -0.

300 FLD screening in patients requiring coronary angiogram would identify high-risk patients and predict