ライフサイエンスコーパス: thallium

1 C reductive elimination (for both indium and thallium).

2 into nonimaging and imaging procedures (eg, thallium).

3 onomeric MX2 radicals of gallium, indium and thallium.

4 Oocytes were then exposed to extracellular thallium.

5 been identified as nonviable by both PET and thallium.

6 tion or exposure to chemical toxins, such as thallium.

7 the extent of myocardial injury assessed by thallium.

8 evere asynergy, there were considerably more thallium/18FDG discordances in the inferior wall than el

9 g (99m)Tc (or (124)I) for cell detection and thallium 201 (or ammonia 13) for myocardial delineation.

10 uracy to dobutamine echocardiography (DE) or thallium 201 (Tl(201)) scintigraphy.

11 se with two-dimensional echocardiography and thallium-201 ((201)Tl) tomography before coronary bypass

12 prospectively compared myocardial uptake of thallium-201 (201Tl) at rest with rest technetium-99m (9

13 omography) myocardial perfusion imaging with thallium-201 (n=173) or technetium-99m sestamibi (n=72)

14 hocardiography (DSE) and rest-redistribution thallium-201 (T1-201) scintigraphy.

15 Several centers used thallium-201 (Tl-201) as an alternative radiotracer for

16 ht to determine the significance of abnormal thallium-201 (Tl-201) lung uptake on stress imaging in t

17 mole technetium-99m (Tc-99m) tetrofosmin and thallium-201 (Tl-201) single-photon emission computed to

18 fluence of estimated functional capacity and thallium-201 (Tl-201) single-photon emission computed to

19 aphy (MCE), quantitative rest-redistribution thallium-201 (Tl-201) tomography and low and high dose (

20 puter-generated polar maps of the myocardial thallium-201 activity.

21 T protocol used separate acquisition of rest thallium-201 and adenosine Tc-99m sestamibi and was visu

22 Rest thallium-201 and exercise 99mTc-sestamibi or 99mTc-tetro

23 Thallium-201 brain SPECT appears to be a useful noninvas

24 choice has been expanded to include not only thallium-201 but also technetium-based imaging agents su

25 he positive predictive value of a reversible thallium-201 defect (r=0.70), increasing sixfold from lo

26 Thallium-201 demonstrates significantly greater tumor av

27 Thallium-201 gated SPECT imaging can be effectively perf

28 iomyopathy using rest and 4 h redistribution thallium-201 imaging and dobutamine technetium-99m sesta

29 y of detection of coronary artery disease by thallium-201 imaging is high, the actual detection of 3V

30 value of routine noninvasive testing--stress thallium-201 imaging, rest two-dimensional echocardiogra

31 atment with thrombolytic therapy and who had thallium-201 myocardial infarct-size measurements perfor

32 1994) identified 10 reports on dipyridamole-thallium-201 myocardial perfusion (1,994 patients) and 5

33 strated the prognostic value of dipyridamole-thallium-201 myocardial perfusion and dobutamine echocar

34 chocardiography (chi-square 9.21) and stress thallium-201 myocardial perfusion imaging (chi-square 16

35 ansient ischemic dilation (TID) after stress thallium-201 myocardial perfusion imaging and to provide

36 hic myocardial perfusion images using either thallium-201 or technetium-99m sestamibi, and no previou

37 only a single abnormal coronary territory by thallium-201 perfusion imaging does not necessarily conf

38 I/D genotyping, predischarge adenosine-thallium-201 perfusion tomography and radionuclide angio

39 ainty interval, 9 to 58) for a dual-isotope (thallium-201 plus technetium-99m) scan.

40 nergy (14- to 27-fold) than for dipyridamole-thallium-201 redistribution (4-fold); wider confidence i

41 attern (4.8% in 83 patients) and one or more thallium-201 redistribution abnormality (18.6% in 97 pat

42 life, and cardiac perfusion (as assessed by thallium-201 scanning) were evaluated at base line and 3

43 Thallium-201 scintigraphy has very high specificity (100

44 oring, exercise treadmill testing and stress thallium-201 scintigraphy.

45 cise have a high incidence of false positive thallium-201 single-photon emission computed tomographic

46 formally compare the diagnostic accuracy of thallium-201 single-photon emission computed tomographic

47 This is a prospective study using exercise thallium-201 single-photon emission computed tomography

48 and incremental prognostic value of exercise thallium-201 single-photon-emission computed tomography

49 patients undergoing symptom-limited exercise thallium-201 SPECT between September, 1990, and December

50 Thallium-201 SPECT may be less specific than previously

51 en, age 77+/-3 years) who underwent exercise thallium-201 SPECT were followed up for a median duratio

52 myocardial ischemia as assessed by exercise thallium-201 SPECT.

53 Normal thallium-201 stress myocardial perfusion imaging 1 year

54 a corresponding perfusion defect as shown by thallium-201 tomography (sensitivity 96%).

55 ed 109 patients who underwent both adenosine thallium-201 tomography and coronary angiography at 6.7

56 ght ventricular pacemaker underwent exercise thallium-201 tomography and coronary angiography within

57 Thus, results of adenosine thallium-201 tomography are nearly always abnormal in pa

58 sought to ascertain the utility of adenosine thallium-201 tomography for assessing graft stenoses lat

59 Adenosine thallium-201 tomography was assessed quantitatively by c

60 eveloped from several clinical, exercise and thallium-201 variables in a training population of 264 p

61 All patients had a dual isotope (rest thallium-201, stress sestamibi) study performed during t

62 oing maximal exercise perfusion imaging with thallium-201.

63 ences between technetium-labeled tracers and thallium-201.

64 e results are similar to those obtained with thallium-201.

65 ,173 consecutive patients who underwent rest thallium-201/adenosine technetium-99m sestamibi MPS, 254

66 over clinical and exercise variables of rest thallium-201/exercise technetium-99m sestamibi single-ph

67 ly irreversible thallium defects (scarred by thallium), 59 (43%) were viable by 18FDG PET, of which 5

68 y (76%), compared with stress-redistribution thallium (68%) and rest tetrofosmin (66%) (P<0.05).

69 Specificity of ratings based on thallium (85% +/- 6) and gallium (90% +/- 5) scintigraph

70 nificance to detect an effect of bridging on thallium abnormalities at an odds ratio of 3.

71 The rates of exchange of potassium and thallium across capillary walls and cell membranes in is

72 atical methods of mass bias correction using thallium additions were tested.

73 Redistribution of thallium after the resting injection was insensitive (18

74 ultimately dismissed because blood levels of thallium, although raised, were lower than toxic concent

75 dance between SPECT and PET technologies and thallium and 18FDG tracers for assessing viability regar

76 Thallium and BMIPP SPECT data were read separately by 3

77 Quantitative rest thallium and dipyridamole stress sestamibi imaging was a

78 A sequential thallium and gallium scan to specify the nature of the m

79 Sequential thallium and gallium scanning helped differentiate tumor

80 n immunodeficiency virus (HIV) who underwent thallium and gallium scanning to evaluate intracranial m

81 On the basis of results at thallium and gallium scanning, the patients were divided

82 for a retrospective evaluation of sequential thallium and gallium scans in AIDS patients for differen

83 racteristics similar to those of widely used thallium and may be useful in the assessment of myocardi

84 ities and large volumes of distribution make thallium and potassium among the best ionic deposition m

85 series (Eisenman type IV) but conducts only thallium and potassium readily.

86 e extent of myocardial injury as assessed by thallium and the severity of left ventricular (LV) dysfu

87 specialty metals (e.g., gallium, indium, and thallium) and some heavy rare earth elements are represe

88 inly associated with cobalt, copper, nickel, thallium, and silver, whereas the ecotoxicity potential

89 rily associated with cobalt, copper, nickel, thallium, and silver.

90 microgram per liter levels of cadmium, lead, thallium, and zinc in nondeaerated solutions yielded wel

91 rsus 27%, P<.001), supporting attenuation of thallium as a potential explanation for the discordant o

92 Qualitative thallium assessment provided a high sensitivity (98%) bu

93 (n = 24) for Tl+; the ratio of potassium to thallium averaged 0.40 +/- 0.19 (n = 18), thereby omitti

94 hallium (Tl+) ions and the low solubility of thallium bromide salt were used to develop a simple yet

95 quenching of FHS by nitromethane, TEMPO, or thallium, but did decrease the Stern-Volmer constant by

96 Adduct 3 features an almost linear thallium C(ipso)-Tl-B angle of 174.358(7) degrees and a

97 = 2, 3), while C6Me6 addition gave the first thallium-C6Me6 adduct, [Tl(eta6-C6Me6)2][H2N{B(C6F5)3}2]

98 averaged deposition records for highly toxic thallium, cadmium, and lead from a Greenland ice core sh

99 large extent to be ionic as it is made of a thallium cation and a trisubstituted cluster anion.

100 The thallium characteristics here are close to those in nume

101 cclusion, (18)F-FBnTP (92.5 MBq) and (201)Tl-thallium chloride (0.74 MBq) were injected intravenously

102 The chemical bonding schemes of thallium cluster anions commonly comply with neither Wad

103 ows that, in accordance with experiment, the thallium cluster anions known are electronically saturat

104 acy of frontier orbitals in highly symmetric thallium cluster anions.

105 tability in barium, selenium, strontium, and thallium concentrations than those of tree swallows (Tac

106 The final thallium content (maximum tracer uptake on redistributio

107 In contrast, final thallium content was similar in regions with mild-to-mod

108 myocardial tissue (as reflected by the final thallium content), the presence of inducible ischemia is

109 regions were grouped according to the final thallium content, at 60% threshold value, functional rec

110 ial proportion of patients with one abnormal thallium coronary territory have 3VLMD with subsequent d

111 the training population despite one abnormal thallium coronary territory.

112 Agreement between BMIPP and thallium data for the presence of an abnormality on the

113 myocardium, the identification of reversible thallium defect on stress in an asynergic region more ac

114 The size of the initial thallium defect was the best predictor of later adverse

115 e and 20 of 37 mild-to-moderate irreversible thallium defects (51% and 54%, respectively).

116 d with 6 of 20 mild-to-moderate irreversible thallium defects (79% and 30%, respectively; P<0.001).

117 37 segments exhibiting severely irreversible thallium defects (scarred by thallium), 59 (43%) were vi

118 reversible and mild-to-moderate irreversible thallium defects after stress retain viable myocardium,

119 hypothesized that stress-induced reversible thallium defects may better differentiate reversible fro

120 reversible and mild-to-moderate irreversible thallium defects retain metabolically active, viable myo

121 nd in patients with greater numbers of fixed thallium defects.

122 for DNA-based sensing, little is known about thallium detection.

123 Although it is believed that thallium differentiates between viable and nonviable myo

124 Group B underwent thallium dipyridamole scintigraphy.

125 combination of characteristics, and only 2 (thallium-doped sodium iodide and bismuth germanate) have

126 The camera uses a 10 x 10 cm thallium-doped sodium iodide crystal, a 2 x 2 array of 5

127 The reaction of thallium ethoxide with [H(OEt2)2][H2N{B(C6F5)3}2] in die

128 eached concentrations of chromium, lead, and thallium exceeded the California regulation limits.

129 ene leads to electron transfer; the isolable thallium-ferrocene complexes may therefore be viewed as

130 10 known hERG inhibitors determined in this thallium flux assay and in the patch clamp experiment.

131 Our findings indicate that this thallium flux assay can be used as an alternative method

132 Here we report a modified form of the FluxOR thallium flux assay, capable of measuring hERG activity

133 We anticipate that the GIRK-mediated thallium flux strategy will provide a novel tool to adva

134 Using GIRK-mediated thallium flux, we perform a side-by-side comparison of t

135 Viable segments by both DE and thallium had less fibrosis (1%) than those viable by 1 o

136 r action on the receptor, using stopped-flow thallium (I)-flux spectrofluorimetry.

137 The bonding between thallium(I) and arenes was explored by density-functiona

138 ted polyether complexes contain lead(ii) and thallium(i) but recent breakthroughs in regard to the pr

139 ion of DNA crystals grown in the presence of thallium(I) cations (Tl(+)).

140 Addition of thallium(I) triflate (TlOTf) to Pd(CNAr(Dipp2))(2) resul

141 Thallium(I), a K+ mimic, minimizes the effects of Pdx ti

142 ure was determined from crystals soaked with thallium(I), which has been broadly used as a mimic of K

143 rt that the electrophilic main-group cations thallium(III) and lead(IV) stoichiometrically oxidize me

144 A crucial late-stage thallium(III) mediated intermolecular oxidative dehydrod

145 Late-rest thallium images showed the highest sensitivity (76%), co

146 The early thallium images, acquired 15 min after the intravenous i

147 have examined the prognostic value of stress thallium imaging in several subsets of patients with isc

148 which include positron emission tomography, thallium imaging, and dobutamine echocardiography, can r

149 ve tests--exercise treadmill testing, planar thallium imaging, single-photon emission computed tomogr

150 costs relative to stress testing and planar thallium imaging.

151 essful implementation through the use of the thallium impurity levels in lead telluride (PbTe).

152 stions about the optimum time of imaging for thallium in high-grade lymphoma, whether delayed imaging

153 about previous reports of low sensitivity of thallium in undifferentiated lymphoma and about the mech

154 ng efficiency in the channel's closed state, thallium ion, a cationic quencher, has a higher quenchin

155 ture of the latter shows an eight-coordinate thallium ion, where the coordination to the six oxygen d

156 Thallium ions are transported to the interior of gallium

157 This high cellular influx for thallium is interpreted as due to its passage through io

158 O4)2, argentojarosite, AgFe3(OH)6(SO4)2, and thallium jarosite, TlFe3(OH)6(SO4)2, along with the sele

159 The unique geometric features of the anionic thallium layers bring on an unusual competition between

160 Ni(3)Sn family (P6(3)/mmc), and consists of thallium layers formed from two-center bond formation be

161 valence electron concentration (VEC) of the thallium layers is consistent with their two-dimensional

162 c (P < .0005) perfusion defect size; percent thallium lung uptake (P = .001); presence of infarct-zon

163 Thallium lung-to-myocardial ratio (L/M), left ventricula

164 ic ischemic heart disease, viable regions by thallium may fail to improve function after revasculariz

165 81 +/- 3% for the clinical and dipyridamole-thallium models.

166 ts (one with PML and two with infarcts) with thallium-negative, gallium-negative scans.

167 (tuberculosis, Cryptococcus, bacteria) with thallium-negative, gallium-positive scans.

168 ed using the double correction method (first thallium normalization followed by classical bracketing)

169 ll exercise, stress echocardiography, stress thallium or predetermined EBCT calcium score outpoints,

170 ement and either increased pulmonary uptake (thallium) or a decreased resting ejection fraction (sest

171 SPECT imaging with thallous chloride TI 201 (thallium) or technetium Tc 99m sestamibi for detection a

172 parallel channels, which are filled by lead, thallium, or mercury atoms.

173 not bridging, were independent predictors of thallium perfusion abnormalities.

174 related to the magnitude of exercise-induced thallium perfusion defect (r=0.6, P<0.001 for early BMIP

175 utcome (18% mortality rate with a reversible thallium perfusion defect and 8% mortality rate with no

176 The presence of SPECT thallium perfusion defects was a less powerful predictor

177 After adjustment for age, sex, thallium perfusion defects, and other confounders, failu

178 capacity, classified by age and gender, and thallium perfusion defects, expressed as a stress extent

179 a low chronotropic index, and 612 (21%) had thallium perfusion defects.

180 all-cause mortality, even after considering thallium perfusion defects.

181 A reversible thallium perfusion deficit demonstrated 6 months after m

182 A reversible thallium perfusion deficit documented after 6 months of

183 ect and 8% mortality rate with no reversible thallium perfusion deficit, p = 0.02).

184 f patients who were symptom-free after CABG, thallium-perfusion defects and impaired exercise capacit

185 G, and standard cardiovascular risk factors, thallium-perfusion defects remained predictive of death

186 Patients with thallium-perfusion defects were more likely to die (9% v

187 Exercise and thallium-perfusion variables were analysed to determine

188 Thallium poisoning was suspected and investigated but ul

189 A thallium-positive, gallium-negative pattern in AIDS pati

190 no opportunistic infections (19 patients), a thallium-positive, gallium-negative pattern was detected

191 The sensitivity and specificity of the thallium-positive, gallium-positive pattern for intracra

192 e multifocal leukoencephalopathy [PML]) with thallium-positive, gallium-positive scans.

193 second model was developed from dipyridamole-thallium predictors of myocardial infarction (i.e., fixe

194 timony (Ptrend < 0.01), 0.76 (0.51-1.13) for thallium (Ptrend = 0.13), 2.18 (1.51-3.15) for tungsten

195 ement and consensus agreement on gallium and thallium scan findings were evaluated with the kappa sta

196 with a concordant abnormal exercise ECG and thallium scan had a relative risk of 14.5.

197 An abnormal exercise test, thallium scan, or both occurred in 153 (21%) of 734 asym

198 by exercise ECG alone or in combination with thallium scan.

199 ations or were too unstable for a persantine thallium scan.

200 usion between the two groups, as assessed by thallium scanning.

201 , magnetic resonance imaging, and technetium thallium scans were 48%/21%, 52%/16%, 48%/14% and 42%/8%

202 ne to those with concordant positive ECG and thallium scintigraphic findings who had virtually identi

203 y (kappa +/- SD = 0.956 +/- 0.044) than with thallium scintigraphy (kappa = 0.638 +/- 0.110).

204 ormed with electrocardiography (n = 300) and thallium scintigraphy (n = 270).

205 e and extensive reversible defects on stress thallium scintigraphy (p = 0.0008), less functional impa

206 increase compared with pharmacologic stress thallium scintigraphy alone (0.05<P<0.10), whereas speci

207 purpose was to compare pharmacologic stress thallium scintigraphy and also exercise radionuclide ven

208 Myocardial contrast echocardiography, thallium scintigraphy and any contractile reserve during

209 coronary artery disease who had dipyridamole thallium scintigraphy and cardiac catheterization within

210 hirty patients had both pharmacologic stress thallium scintigraphy and exercise radionuclide ventricu

211 ive, predischarge stress testing with planar thallium scintigraphy and radionuclide ventriculography)

212 reversible perfusion defect during exercise thallium scintigraphy and/or as an abnormal result of an

213 ess the variability of results obtained with thallium scintigraphy as a method for tracking the exten

214 Thallium scintigraphy can help to predict the absence of

215 gle-photon-emission computed tomography with thallium scintigraphy for diagnostic purposes.

216 Pharmacologic stress thallium scintigraphy is commonly performed in the risk

217 y disease, stress-redistribution-reinjection thallium scintigraphy provides important information reg

218 This may limit the utility of thallium scintigraphy to detect improved myocardial perf

219 Exercise thallium scintigraphy was performed in 264 asymptomatic

220 Nuclear techniques, like thallium scintigraphy, are used in multicenter trials to

221 Stress thallium scintigraphy, echocardiography, and electron-be

222 h radionuclide ventriculography and exercise thallium scintigraphy, followed by coronary angiography

223 findings, treadmill exercise tests, exercise thallium scintigraphy, Holter monitoring and electrophys

224 r absence of myocardial perfusion defects on thallium scintigraphy, standard cardiac risk factors, th

225 normal exercise ECGs also underwent exercise thallium scintigraphy.

226 hi-square 8, p = 0.004) and by stress extent thallium score (adjusted RR 1.62, 95% CI 1.25 to 2.11, c

227 fusion defects, expressed as a stress extent thallium score on a 12-segment scale, were analyzed to d

228 2.7 mm and 87 +/- 13%, p < 0.001) and normal thallium segments (12.8 +/- 2.6 mm and 80 +/- 14%, p < 0

229 rsible (20.2 +/- 12.6%, p < 0.001) or normal thallium segments (15.0 +/- 8.7%, p < 0.001).

230 The irreversible thallium segments had lower wall thickness and more seve

231 rization exercise-redistribution-reinjection thallium single photon emission CT, gated MRI, and radio

232 sitron emission tomography scanning, and 201-thallium single-photo emission CT are all promising noni

233 cose (FDG) positron emission tomography, and thallium single-photon emission computed tomography.

234 ively with stress-redistribution-reinjection thallium single-photon emission computed tomography.

235 The aim was to compare 201Tl (thallium) single photon emission CT (SPECT), 99mTc-tetro

236 adults referred for symptom-limited exercise thallium SPECT (mean age 60 +/- 10, 25% women) for 6.7 y

237 Stress/redistribution thallium SPECT and resting MRI were repeated after surge

238 ibution and separate-day rest/redistribution thallium SPECT before surgery.

239 Myocardial perfusion defects detected by thallium SPECT imaging are independently predictive of l

240 cytomegalovirus infection, not tumor as the thallium SPECT results suggested.

241 rest) underwent 18FDG SPECT, 18FDG PET, and thallium SPECT studies.

242 2 patients with exercise-induced ischemia on thallium SPECT, BMIPP was injected at rest within 30 hou

243 Thallium stable isotope data are used in this study, for

244 operated under wet plasma conditions where a thallium standard solution was introduced to the mass sp

245 t these findings both TID and LHR had higher thallium stress defect and redistribution scores.

246 ) and had more evidence of ischemia based on thallium stress defect and redistribution scores.

247 Ischemia was defined as a reversible thallium stress defect.

248 nnaire for quality of life, and dipyridamole thallium stress test.

249 ide angiography at rest and during exercise, thallium stress testing and transesophageal dobutamine s

250 e radionuclide angiography and in 18% during thallium stress testing.

251 Group A underwent maximal exercise thallium stress testing.

252 Patients underwent dipyridamole thallium stress tests at baseline and 3, 6 and 12 months

253 Eighty-six patients underwent exercise thallium studies for evaluation of anginal symptoms.

254 In 16 scans, the thallium studies gave false-positive results.

255 ly six (17%) of the corresponding whole-body thallium studies had detectable uptake in the neck.

256 raphic observations are further supported by thallium studies in stable CAD that demonstrate that the

257 se into the routine interpretation of stress thallium studies may improve the prognostic power of thi

258 The results of thallium/technetium scintigraphy were negative in three

259 < or =25%, at 60% 18FDG PET threshold value, thallium tended to underestimate myocardial viability.

260 normal coronary artery territory on exercise thallium testing and had undergone coronary angiography.

261 er a reversible or fixed defect) on exercise thallium testing and to test the prognostic value of the

262 nts were symptomatic, had undergone exercise thallium testing between 1989 and 1991 and were followed

263 were referred for symptom-limited treadmill thallium testing.

264 Using a thallium (Tl(+))-sensitive fluorophore, we developed a n

265 -1-piperinyloxy) (TEMPO), iodide (I(-)), and thallium (Tl(+))] were used to assess both the steric an

266 Thallium (Tl) is a highly toxic heavy metal situated bet

267 Thallium (Tl) is emerging as a metal of concern in count

268 Here, for the first time, we report the thallium (Tl) isotope record in moderately contaminated

269 and urine arsenic (As), Cd, molybdenum (Mo), thallium (Tl), and U with markers of vitamin D metabolis

270 mine the prognostic capabilities of exercise thallium (Tl)-201 tomographic imaging performed relative

271 gh permeability of K+ channels to monovalent thallium (Tl+) ions and the low solubility of thallium b

272 This requirement can be satisfied by thallium (Tl+), a potassium (K+) surrogate.

273 ed using a channel-permeable quencher (e.g., thallium, Tl(+)) of a water-soluble fluorophore (8-amino

274 e myocardium in tissue declared nonviable by thallium (to 88% of the sensitivity achievable by PET),

275 to the agreement or disagreement between the thallium tomographic and coronary angiographic results.

276 ng is high, the actual detection of 3VLMD by thallium tomographic images alone is not optimal.

277 T and PET technologies and between 18FDG and thallium tracers to determine whether 18FDG SPECT could

278 cobalt, cesium, molybdenum, lead, antimony, thallium, tungsten, and uranium with diabetes prevalence

279 bis(boryl) complexes of gallium, indium, and thallium undergo oxidative M-C bond formation with 2,3-d

280 P<0.01), more glycogen (P=0.016), and higher thallium uptake (64% versus 35.5%, P<0.05) than those wi

281 low-dose DE (28% versus 3%, P<0.001), higher thallium uptake (69% versus 48%, P=0.03), and less inter

282 FDG uptake (r = 0.68, p < 0.001) as well as thallium uptake (r = 0.76, p < 0.001) in all asynergic r

283 We examined pretransplantation quantitative thallium uptake and post-transplantation extent and the

284 terns of normal, reversible and irreversible thallium uptake correlated with the magnitude of collage

285 ated the relation of contractile reserve and thallium uptake in hibernating myocardium to myocardial

286 entiated lymphoma and about the mechanism of thallium uptake in this type of tumor.

287 ed depending on the quantitative criteria of thallium uptake or combination of responses of the myoca

288 lel relationship among 13N-ammonia, FDG, and thallium uptake supports the concept that uptake of 13N-

289 ose dobutamine echocardiography (DE), higher thallium uptake, and less fibrosis (2.0 vs 28%) than tho

290 Quantification of thallium uptake, however, improved its accuracy: a maxim

291 n and fibronectin, more glycogen, and higher thallium uptake, than those segments without viability.

292 mentin and directly with rest-redistribution thallium uptake.

293 The delayed images 2 hr later showed intense thallium uptake.

294 azoxide-activated component of mitochondrial thallium uptake.

295 ssess the relation of contractile reserve to thallium uptake.

296 t accurate being a qualitative assessment of thallium uptake.

297 as to determine which clinical, exercise and thallium variables can aid in the identification of thre

298 Agreement between delayed BMIPP and thallium was 95% among 21 patients studied on the same d

299 positive studies, and the retention index of thallium was calculated (delayed/early target-to-backgro

300 ity surface products (PSc) for potassium and thallium were similar, 0.82 +/- 0.33 (mean +/- s.d., n =