ライフサイエンスコーパス: perfusion imaging

1 as an alternative radiotracer for myocardial perfusion imaging.

2 rmacologic stress or exercise for myocardial perfusion imaging.

3 phy and single-photon emission CT myocardial perfusion imaging.

4 and with the use of (99m)TC-tetrofosmin for perfusion imaging.

5 phy, but no data exist on magnetic resonance perfusion imaging.

6 stroke who were selected on the basis of CT perfusion imaging.

7 s as PET radiopharmaceuticals for myocardial perfusion imaging.

8 ssion tomography (PET) tracer for myocardial perfusion imaging.

9 strain-rate echocardiography, and myocardial perfusion imaging.

10 gs at combined cardiac CT angiography and CT perfusion imaging.

11 struction of the AIF during multidetector CT perfusion imaging.

12 lled for evaluation of the feasibility of CT perfusion imaging.

13 graphically gated (axial) rest myocardial CT perfusion imaging.

14 ue detection and is being applied for stress perfusion imaging.

15 cardiac magnetic resonance (CMR) myocardial perfusion imaging.

16 ecline in myocardial perfusion at first-pass perfusion imaging.

17 for patients with colorectal cancer than CT perfusion imaging.

18 with and without ischemia on PET myocardial perfusion imaging.

19 with and without ischemia on PET myocardial perfusion imaging.

20 may modify the results of stress myocardial perfusion imaging.

21 single photon emission CT (SPECT) myocardial perfusion imaging.

22 aging and 24 datasets (1,516 patients) using perfusion imaging.

23 imb blood flow was measured by laser Doppler perfusion imaging.

24 denosine stress on the results of myocardial perfusion imaging.

25 k stratification with vasodilator myocardial perfusion imaging.

26 basis constitutes the primary goal of liver perfusion imaging.

27 l may also translate favorably to myocardial perfusion imaging.

28 e patients undergoing gated SPECT myocardial perfusion imaging.

29 tiveness of vasodilator stress in myocardial perfusion imaging.

30 s may benefit from screening with myocardial perfusion imaging.

31 extent of hypoperfusion observed with SPECT perfusion imaging.

32 easing the diagnostic accuracy of myocardial perfusion imaging.

33 of electrocardiographic gating in myocardial perfusion imaging.

34 reversible stress defect, and negative rest perfusion imaging.

35 ll scores (> or =5) who underwent myocardial perfusion imaging.

36 less than 70 ml on computed tomographic (CT) perfusion imaging.

37 s evaluated by low-power contrast ultrasound perfusion imaging.

38 fusion by direct comparison with (15)O-water perfusion imaging.

39 tress echocardiography, or stress myocardial perfusion imaging.

40 ress positron emission tomography myocardial perfusion imaging.

41 n to reduce dark-rim artifacts in first-pass perfusion imaging.

42 flow recovery was followed by laser Doppler perfusion imaging.

43 y is monitored over 28 days by laser Doppler perfusion imaging.

44 osine stress conditions underwent dynamic CT perfusion imaging (14 consecutive data sets) performed b

45 e (rCBV) were measured with gadolinium-based perfusion imaging (3 Tesla magnetic resonance image (MRI

46 For perfusion imaging, 3 short-axis images were acquired dur

47 s; this proportion was higher for myocardial perfusion imaging (74.8%) and cardiac computed tomograph

48 Myocardial perfusion imaging accounted for 74% of the cumulative ef

49 r 2004 and September 2011 who had myocardial perfusion imaging after negative troponin T tests and no

50 evaluation as a high-resolution PET cardiac perfusion imaging agent.

51 pass cardiovascular magnetic resonance (CMR) perfusion imaging allows absolute quantification of MBF.

52 Quantitative perfusion imaging allows to noninvasively calculate frac

53 xploited arterial spin-labeling quantitative perfusion imaging and a newly developed procedure to ide

54 bidium 82 positron emission tomography (PET) perfusion imaging and CAC scoring on a hybrid PET-comput

55 erwent prospectively simultaneous myocardial perfusion imaging and CAC scoring on a hybrid, 64-sectio

56 essible technical overview of first-pass CMR perfusion imaging and contrast it with other conventiona

57 three-dimensional echocardiographic (RT3DE) perfusion imaging and developed and validated an algorit

58 ies and new applications, such as myocardial perfusion imaging and dual-energy CT, are being explored

59 nts who underwent exercise stress myocardial perfusion imaging and echo (5.5+/-7.9 days), among whom

60 bstruction (MVO) detected by rest and stress perfusion imaging and gadolinium enhancement obtained 2

61 image interpretation specific to myocardial perfusion imaging and implications of use of cardiac med

62 Ventilation-perfusion imaging and lower extremity Doppler ultrasonog

63 Contrast ultrasound perfusion imaging and molecular imaging with microbubble

64 l shift imaging, diffusion-weighted imaging, perfusion imaging and MR spectroscopy, additional quanti

65 common in both sexes, despite normal stress perfusion imaging and no coronary artery calcification (

66 oximal adductor muscles were measured by CEU perfusion imaging and phosphor quenching, respectively.

67 uboptimal images and/or underwent myocardial perfusion imaging and received contrast agents; 18,749 o

68 m signal intensity and upslope at first-pass perfusion imaging and reduced infarct size at perfusion

69 xpansive evidence base for stress myocardial perfusion imaging and reveals a decided advantage for hi

70 The diagnostic accuracy of myocardial perfusion imaging and wall motion imaging were lower tha

71 on 4-h delayed planar images) and myocardial perfusion imaging and were then followed up for up to 2

72 scored for severity and reversibility at CT perfusion imaging, and (c)coronary stenosis severity was

73 rwent contrast material-enhanced neck CT, CT perfusion imaging, and endoscopic biopsy of the primary

74 ssion computed tomography (SPECT) myocardial perfusion imaging, and magnetic resonance imaging.

75 More wide use of cardiac MR perfusion imaging, and novel applications thereof, are a

76 pabilities for multispectral imaging, tissue perfusion imaging, and radiation dose reduction through

77 CT-FFR, CT myocardial perfusion imaging, and transluminal attenuation gradient

78 on of CAD, with 2 main techniques in use: 1) perfusion imaging; and 2) stress-induced wall motion abn

79 cardiac medications to results of myocardial perfusion imaging are discussed.

80 rs, beta-blockers, and statins on myocardial perfusion imaging are likely attributable to changes in

81 al fibrosis imaging, and absolute myocardial perfusion imaging, are poised to further advance our kno

82 cise treadmill testing with RNA-EF and SPECT perfusion imaging as a single test.

83 oton emission computed tomography myocardial perfusion imaging as a tool for risk stratification in s

84 e-photon emission computed tomography stress perfusion imaging at 2 Seattle hospitals were assessed f

85 he infarct core on computed tomographic (CT) perfusion imaging at baseline and an associated vessel o

86 ent stress echocardiography and radionuclide perfusion imaging at one stress session.

87 o gastrointestinal, intravascular and tumour perfusion imaging at subpicomolar concentrations are pre

88 rwent quantitative (13)N-ammonia PET and CMR perfusion imaging before coronary angiography.

89 CRT recipients with radionuclide myocardial perfusion imaging before CRT between January 2002 and De

90 an patients who underwent nuclear myocardial perfusion imaging between December 2010 and July 2011 wi

91 ears), patients were referred for myocardial perfusion imaging between May 2008 and January 2011 (PRE

92 or metoprolol underwent adenosine myocardial perfusion imaging both on and off beta-blockade in a ran

93 Myocardial perfusion imaging by MDCT may have significant implicati

94 omographic angiography and stress myocardial perfusion imaging by single photon emission computed tom

95 ermine the diagnostic accuracy of myocardial perfusion imaging by single-photon emission computed tom

96 Contrast material-enhanced myocardial perfusion imaging by using cardiac magnetic resonance (M

97 enges, and mathematic modeling related to CT perfusion imaging; (c) note recent advances in CT scanne

98 ine stress cardiovascular magnetic resonance perfusion imaging can be limited by motion-induced dark-

99 low-grade glioma, susceptibility-weighted MR perfusion imaging can demonstrate significant increases

100 aphy, stress echocardiography, or myocardial perfusion imaging can reveal findings associated with in

101 ) with cardiac magnetic resonance myocardial perfusion imaging (CMR-Perf) for detection of functional

102 ssessed the incidence of abnormal myocardial perfusion imaging, coronary angiography, revascularizati

103 the accuracy of 320-row computed tomography perfusion imaging (CTP) to detect atherosclerosis causin

104 ed distal limb reperfusion (by laser Doppler perfusion imaging), decreased foot use, and impaired dis

105 Perfusion imaging demonstrated a sensitivity of 0.91 (95

106 xcision of the femoral artery, laser Doppler perfusion imaging demonstrated reduced blood flow recove

107 CMR perfusion imaging detects impaired resting MBF in hibern

108 n such as vascular permeability measurement, perfusion imaging, diffusion imaging, and new PET tracer

109 ents undergoing dobutamine stress myocardial perfusion imaging (DSMPI).

110 CMR perfusion imaging during the first pass of gadolinium-ba

111 erial occlusion and salvageable tissue on CT perfusion imaging, early thrombectomy with the Solitaire

112 oint for infarct volume in the Diffusion and Perfusion Imaging Evaluation for Understanding Stroke Ev

113 Myocardial perfusion imaging facilitates management of CAD in elect

114 functional imaging, myocardial viability and perfusion imaging, flow quantification, and coronary art

115 METHODS AND We performed CMR myocardial perfusion imaging followed by LGE imaging on 254 patient

116 phically gated (helical) adenosine stress CT perfusion imaging followed by prospectively electrocardi

117 agnostic sensitivity of adenosine myocardial perfusion imaging for the detection of flow-limiting cor

118 CMR), and positron emission tomography (PET) perfusion imaging for the diagnosis of obstructive coron

119 bnormalities detected using gated myocardial perfusion imaging (GMPI) in patients with esophageal can

120 ved on time to maximum greater than 6-second perfusion imaging (>/=90% vs <90%).

121 stenosis > or =50%, whereas SPECT myocardial perfusion imaging had a sensitivity of 67% and a specifi

122 Myocardial perfusion imaging had good diagnostic accuracy (area und

123 Quantitative CMR perfusion imaging has been established more recently and

124 Heretofore, radionuclide myocardial perfusion imaging has been primarily qualitative or at b

125 esolution cardiovascular MR (CMR) myocardial perfusion imaging has been shown to be clinically feasib

126 Dobutamine stress myocardial perfusion imaging has been shown to effectively risk str

127 oton emission computed tomography myocardial perfusion imaging has been validated in multiple patient

128 Myocardial perfusion imaging has limited sensitivity for the detect

129 Myocardial perfusion imaging has long been used off label by practi

130 ton emission computed tomographic myocardial perfusion imaging improved from a summed stress score of

131 : reduced radiation doses associated with CT perfusion imaging, improved spatial and temporal resolut

132 nt state of cardiac magnetic resonance (CMR) perfusion imaging in assessing alterations in myocardial

133 the usefulness of echocardiographic contrast perfusion imaging in differentiating cardiac masses.

134 comparing fully quantitative CMR against PET perfusion imaging in patients with CAD.

135 azonato)copper(II) ((62)Cu-ETS) PET/CT tumor perfusion imaging in patients with metastatic renal carc

136 ution and standard-resolution CMR myocardial perfusion imaging in patients with suspected coronary ar

137 of quantitative positron-emission tomography perfusion imaging in risk stratification for VAs.

138 of stress myocardial magnetic resonance (MR) perfusion imaging in the detection of coronary artery di

139 The role of myocardial perfusion imaging in the diagnosis of coronary artery di

140 on that assigns a larger role for myocardial perfusion imaging in the diagnosis of coronary artery di

141 ospective studies should address the role of perfusion imaging in the identification of high-risk pat

142 r the first time non-invasive whole-placenta perfusion imaging in utero.

143 Stress myocardial perfusion imaging is a noninvasive alternative to invasi

144 Myocardial metabolic and perfusion imaging is a vital tool for understanding the

145 Regadenoson (82)Rb myocardial perfusion imaging is accurate for the detection of obstr

146 The role of myocardial perfusion imaging is also expanding in various other pat

147 Dobutamine stress perfusion imaging is an important diagnostic tool in eld

148 oton emission computed tomography myocardial perfusion imaging is capable of identifying low-risk pat

149 Exercise CT myocardial perfusion imaging is feasible and accurate for assessmen

150 Noninvasive myocardial perfusion imaging is increasingly being applied to gauge

151 Quantitative myocardial perfusion imaging is increasingly used for the diagnosis

152 In fact, cardiac MR perfusion imaging is moving beyond traditional indicatio

153 hat MBF assessed at rest by quantitative CMR perfusion imaging is reduced in hibernating myocardium.

154 Myocardial perfusion imaging is widely used in the assessment of pa

155 rdial dynamic computed tomography myocardial perfusion imaging lacks standardization.

156 is of dynamic computed tomography myocardial perfusion imaging may permit robust discrimination betwe

157 ht prevent vendors from marketing cardiac MR perfusion imaging, may have hampered its progress.

158 b ischemia (HLI), coupled with laser Doppler perfusion imaging, microcomputed tomography, and targete

159 ging and contrast it with other conventional perfusion imaging modalities, and then address the poten

160 3 most commonly used noninvasive myocardial perfusion imaging modalities, single-photon emission com

161 n two independent cohorts, regardless of the perfusion imaging modality used.

162 A study was included if a perfusion imaging modality was used as a diagnostic test

163 Vasodilator stress myocardial perfusion imaging (MPI) accounts for up to 50% of all st

164 ensive literature on preoperative myocardial perfusion imaging (MPI) and outlines key trends; present

165 ositron emission tomography (PET) myocardial perfusion imaging (MPI) and the improved classification

166 CT angiography (CTA) and SPECT myocardial perfusion imaging (MPI) are complementary imaging techni

167 undergoing adenosine stress-rest myocardial perfusion imaging (MPI) by (99m)Tc-tetrofosmin CZT SPECT

168 teria recommend performing stress myocardial perfusion imaging (MPI) for intermediate- to high-risk p

169 ssion computed tomography (SPECT) myocardial perfusion imaging (MPI) has changed over time.

170 ssion computed tomography (SPECT) myocardial perfusion imaging (MPI) in a single academic medical cen

171 r appropriate use of radionuclide myocardial perfusion imaging (MPI) in multiple clinical sites and t

172 a strategy employing rest-stress myocardial perfusion imaging (MPI) in the evaluation of acute low-r

173 vascular magnetic resonance (CMR) myocardial perfusion imaging (MPI) is a state-of-the-art noninvasiv

174 ssion computed tomography (SPECT) myocardial perfusion imaging (MPI) is an effective method of risk s

175 Myocardial perfusion imaging (MPI) is the single medical test with

176 Myocardial perfusion imaging (MPI) is well established in the diagn

177 e the safety of dobutamine stress myocardial perfusion imaging (MPI) obtained by real-time contrast e

178 ositron emission tomography (PET) myocardial perfusion imaging (MPI) offers technical benefits compar

179 ith adenosine-stress radionuclide myocardial perfusion imaging (MPI) or not to be screened.

180 Radionuclide myocardial perfusion imaging (MPI) plays a vital role in the evalua

181 e patients underwent (82)Rubidium myocardial perfusion imaging (MPI) positron emission tomography (PE

182 Although SPECT myocardial perfusion imaging (MPI) provides valuable information ab

183 n of the left ventricle for SPECT myocardial perfusion imaging (MPI) quantification often requires ma

184 or (B) silent ischemia by stress myocardial perfusion imaging (MPI) remain controversial.

185 patients who had abnormal stress myocardial perfusion imaging (MPI) results versus cancer patients w

186 ew protocol, IQ SPECT, to acquire myocardial perfusion imaging (MPI) studies in a quarter of the time

187 ognostic value of normal exercise myocardial perfusion imaging (MPI) tests and exercise echocardiogra

188 s unclear whether the addition of myocardial perfusion imaging (MPI) to the standard ECG exercise tre

189 ssion computed tomography (SPECT) myocardial perfusion imaging (MPI) underwent a comprehensive cardia

190 s (201)Tl (stress)/(99m)Tc (rest) myocardial perfusion imaging (MPI) using a protocol that permitted

191 ought to evaluate the accuracy of myocardial perfusion imaging (MPI) using cadmium-zinc-telluride (CZ

192 Myocardial perfusion imaging (MPI) using nuclear cardiology techniq

193 of attenuation correction (AC) of myocardial perfusion imaging (MPI) with a virtual unenhanced cardia

194 Hybrid PET myocardial perfusion imaging (MPI) with CT allows the incorporation

195 ium score (CACS) as an adjunct to myocardial perfusion imaging (MPI) with SPECT for cardiac risk stra

196 Myocardial perfusion imaging (MPI) with SPECT is a well-established

197 ppropriate use criteria (AUC) for myocardial perfusion imaging (MPI) with SPECT on the estimated life

198 ositron emission tomography (PET) myocardial perfusion imaging (MPI) with Tc-99m single-photon emissi

199 The prognostic value of myocardial perfusion imaging (MPI) with the cadmium-zinc-telluride

200 ssion computed tomography (SPECT)-myocardial perfusion imaging (MPI), a technique that is a mainstay

201 ower the injected doses for SPECT myocardial perfusion imaging (MPI), but the exact limits for loweri

202 es in CT coronary angiography and myocardial perfusion imaging (MPI), including PET MPI, into a discu

203 oton emission computed tomography myocardial perfusion imaging (MPI).

204 of PET over conventional nuclear myocardial perfusion imaging (MPI).

205 on computed tomography (SPECT)/CT myocardial perfusion imaging (MPI).

206 consecutive patients referred for myocardial perfusion imaging (MPI).

207 o assess diastolic dysfunction by myocardial perfusion imaging (MPI).

208 CCTA or radionuclide stress myocardial perfusion imaging (MPI).

209 derivatives have shown promise in myocardial perfusion imaging (MPI).

210 symptomatic patients referred for myocardial perfusion imaging (MPI).

211 Contrast-enhanced ultrasound perfusion imaging of abdominal adipose tissue and skelet

212 Contrast ultrasound perfusion imaging of hindlimb skeletal muscle and femora

213 ing conditions, contrast-enhanced ultrasound perfusion imaging of the forearm flexor muscles was perf

214 of tissue characteristics beyond morphology; perfusion imaging of the liver has potential to improve

215 0 kg/m(2) should be scheduled for myocardial perfusion imaging on a conventional SPECT camera, as it

216 e patients who underwent clinical myocardial perfusion imaging on a SPECT/CT system.

217 low as assessed by stress-induced myocardial perfusion imaging or a significant fall in distal perfus

218 y assessment, substitute for rest studies in perfusion imaging, or improve localization of PET-derive

219 d second, to assess the incremental value of perfusion imaging over cardiac CT angiography in a dual-

220 y of torso PET and compare stress myocardial perfusion imaging patterns with myocardial (18)F-FDG upt

221 trable reversible defects on adenosine SPECT perfusion imaging performed while off caffeine.

222 Myocardial perfusion imaging plays an important role in clinical ma

223 termine whether changes in stress myocardial perfusion imaging protocols and camera technology can re

224 (82)Rb myocardial perfusion imaging protocols were implemented with highly

225 acroaggregated albumin ((99m)Tc-MAA) hepatic perfusion imaging provide essential information before l

226 Adenosine-augmented MDCT myocardial perfusion imaging provides semiquantitative measurements

227 lteplase alone from the International Stroke Perfusion Imaging Registry.

228 ly higher in patients with normal myocardial perfusion imaging results (6.5% +/- 5.4%) than in those

229 tcome was a comparison of nuclear myocardial perfusion imaging results and frequency of ischemia acro

230 Real-time perfusion imaging revealed markedly improved microvascul

231 However, laser Doppler perfusion imaging revealed that blood circulation in the

232 tion in stroke volumes from gated myocardial perfusion imaging scans (range = 33-85 mL; p = .016).

233 Site scoring of (82)Rb PET myocardial perfusion imaging scans was found to be in good agreemen

234 to fit stroke volumes from gated myocardial perfusion imaging scans with linear and quadratic terms

235 nces in stroke volumes from gated myocardial perfusion imaging scans, we assessed its performance in

236 m for high-speed SPECT (HS-SPECT) myocardial perfusion imaging shows excellent correlation with conve

237 -photon emission computed tomography (SPECT) perfusion imaging so as not to mask ischemia detection.

238 oton emission computed tomography myocardial perfusion imaging (SPECT MPI) has improved the diagnosis

239 oton emission computed tomography-myocardial perfusion imaging (SPECT-MPI) has high predictive value

240 Perfusion imaging started with a bolus injection of Sono

241 ssion computed tomography (SPECT) myocardial perfusion imaging studies among patients without history

242 n exposure to patients undergoing myocardial perfusion imaging studies, especially when combined with

243 than a useful adjunct to current myocardial perfusion imaging studies.

244 ale veterans who had both a positive nuclear perfusion imaging study and coronary angiography within

245 rence range of TID for (82)Rb PET myocardial perfusion imaging that is in the range of previously est

246 hypothesis, via multidetector row CT (MDCT) perfusion imaging, that smokers showing early signs of e

247 Among patients with normal PET myocardial perfusion imaging, the annualized event rate in patients

248 in patients with ischemia on PET myocardial perfusion imaging, the annualized event rate in those wi

249 lar on terms including "brain ischemia" and "perfusion imaging." The search was unrestricted by langu

250 hnologic developments in myocardial contrast perfusion imaging, three-dimensional imaging, and strain

251 is study assessed the value of (201)Tl SPECT perfusion imaging to define ventricular myocardial scar

252 ed for 6 months after their index myocardial perfusion imaging to determine subsequent rates of cardi

253 devices designed for indocyanine green-based perfusion imaging to identify cancer-specific bioconjuga

254 s, and with magnetic resonance diffusion and perfusion imaging to identify the areas of tissue dysfun

255 resonance (CMR) first-pass contrast-enhanced perfusion imaging to qualitative interpretation for dete

256 ion incorporating stress and rest myocardial perfusion imaging together with coronary computed tomogr

257 18)F-labeled BMS747158 is a novel myocardial perfusion imaging tracer that targets mitochondrial comp

258 s, and cost-effectiveness of low-dose (82)Rb perfusion imaging using 3-dimensional (3D) PET/CT techno

259 invasive Coronary Angiography and Myocardial Perfusion Imaging Using 320-Detector Row Computed Tomogr

260 eased body mass on the quality of myocardial perfusion imaging using a latest-generation gamma-camera

261 onary angiography and by quantitative serial perfusion imaging using cardiovascular magnetic resonanc

262 ndergone rest-dipyridamole (82)Rb myocardial perfusion imaging using PET.

263 lear fuel cycle as well as toward myocardial perfusion imaging utilizing (82)Sr/(82)Rb isotopic gener

264 ification over clinical and gated myocardial perfusion imaging variables.

265 , diagnostic accuracy of CT perfusion and MR perfusion imaging was 82% (75 of 92) and 74% (68 of 92),

266 Myocardial perfusion imaging was considered feasible for analysis i

267 Stress and rest perfusion imaging was performed as well as early and del

268 Cardiovascular magnetic resonance first-pass perfusion imaging was performed before and 5 to 6 months

269 Cardiovascular magnetic resonance perfusion imaging was performed during adenosine stress

270 First-pass perfusion imaging was performed during hyperemia (induce

271 Placental perfusion imaging was performed using velocity-selective

272 CT myocardial perfusion imaging was performed within 1 minute after pa

273 c susceptibility contrast magnetic resonance perfusion imaging, we demonstrate that lack of ABCD1 fun

274 nd after intravenous contrast and first-pass perfusion imaging were acquired, and assessed on the bas

275 ity for rest-stress (82)Rb PET/CT myocardial perfusion imaging were developed and validated by evalua

276 ton emission computed tomographic myocardial perfusion imaging were included.

277 , stress echocardiography, and/or myocardial perfusion imaging were performed to identify silent cTOD

278 angiogram within 4 mo after SPECT myocardial perfusion imaging were reviewed.

279 For gated SPECT myocardial perfusion imaging, when relative activity distribution o

280 for positron emission tomography myocardial perfusion imaging, which has advanced it from a strictly

281 and the clinical experience with cardiac MR perfusion imaging, which hopefully demonstrates that it

282 Using laser Doppler perfusion imaging, whole mount imaging of vascular caste

283 Maximizing the potential of perfusion imaging will continue to expand the nascent co

284 We hypothesized that PET myocardial perfusion imaging with (82)Rb (PET MPI), would reduce do

285 tients with ischemic stroke who underwent CT perfusion imaging with a 320-detector row CT scanner wer

286 tress dynamic computed tomography myocardial perfusion imaging with a second-generation dual-source s

287 Advances in perfusion imaging with cardiovascular magnetic resonance

288 tial clinical utility of myocardial contrast perfusion imaging with commercially available contrast a

289 Perfusion imaging with CT or MRI appears to have relevan

290 Dual (respiratory/cardiac)-gated perfusion imaging with Flurpiridaz F 18 is feasible and

291 Stress myocardial perfusion imaging with MRI, computed tomography, or posi

292 Computed tomography perfusion imaging with rest and adenosine stress 320-row

293 Myocardial perfusion imaging with RTCE had a higher accuracy for de

294 Perfusion imaging with RTMCE improves the detection of C

295 Myocardial perfusion imaging with RTMCE may improve the detection o

296 y calcium (CAC) scoring on top of myocardial perfusion imaging with single-photon emission computed t

297 e (CAD) is ambiguous, but nuclear myocardial perfusion imaging with single-photon emission tomography

298 Myocardial perfusion imaging with SPECT remains critically importan

299 hnology offers an opportunity for myocardial perfusion imaging without multi-slice reconstruction and

300 We hypothesized that myocardial perfusion imaging would be low yield with limited short-