ライフサイエンスコーパス: autoradiography

1 man BC specimens was compared using in vitro autoradiography.

2 9m)Tc-rhAnnexin V-128, or no radiotracer for autoradiography.

3 s (PSB1, PSB3) was determined using receptor autoradiography.

4 hAnnexin V-128) were determined with digital autoradiography.

5 CO) histochemistry analysis or [(3)H]proline autoradiography.

6 xtracts were tested for binding by ELISA and autoradiography.

7 PET/CT imaging, biodistribution studies, and autoradiography.

8 he activity distribution as determined using autoradiography.

9 lammation, shown on immunohistochemistry and autoradiography.

10 stribution of radionuclides visualized using autoradiography.

11 orated by ex vivo scintillation counting and autoradiography.

12 ed by an external optical imaging system and autoradiography.

13 in vivo small-animal PET imaging and ex vivo autoradiography.

14 ippocampus were confirmed by ex vivo PET and autoradiography.

15 ir and cold florbetapir compound and digital autoradiography.

16 ed in 18 mice using immunohistochemistry and autoradiography.

17 ere confirmed by ex vivo biodistribution and autoradiography.

18 mus and cortical regions of the pig brain by autoradiography.

19 tors by using quantitative in vitro receptor autoradiography.

20 vestigated in vivo with PET and ex vivo with autoradiography.

21 s performed using high-resolution (3)H-DPCPX autoradiography.

22 ured in the striatum using in vitro receptor autoradiography.

23 3.8 +/- 0.8 vs. 10.3 +/- 2.3, P < 0.01), and autoradiography.

24 was detected by phosphoprotein staining and autoradiography.

25 e same states as reported by 2-deoxy-glucose autoradiography.

26 orated by ex vivo scintillation counting and autoradiography.

27 stribution of (18)F-LMI1195 was evaluated by autoradiography.

28 assessed ex vivo by immunohistochemistry and autoradiography.

29 hin the lymph nodes was studied with digital autoradiography.

30 hrome oxidase (CO) and CTB-Au, or dipped for autoradiography.

31 level correlated well with tracer uptake on autoradiography.

32 bridizations as well as dopamine transporter autoradiography.

33 icantly correlated with uptake quantified by autoradiography.

34 aging with a small-animal PET/CT scanner and autoradiography.

35 distribution and clearance were assessed by autoradiography.

36 o by immunohistochemistry, Western blot, and autoradiography.

37 calization of FDG was determined directly by autoradiography.

38 ive positron emission tomography and ex vivo autoradiography.

39 e at 24 h on small-animal PET/CT imaging and autoradiography.

40 was detected with (64)Cu-DOTA-ECL1i by using autoradiography.

41 Additionally, we performed postmortem autoradiography.

42 anges in biodistribution were assessed using autoradiography.

43 n with M-CSF or GM-CSF by using quantitative autoradiography.

44 B cells or were further analyzed via digital autoradiography.

45 (0.41+/-0.04 versus 0.73+/-0.1, P=0.014) and autoradiography (1.1+/-0.3 versus 2.8+/-0.2 P=0.001).

46 by qRT-PCR, in situ hybridization, receptor autoradiography ([(125)I]OVTA binding), and immunohistoc

47 ro testing via competition binding assay and autoradiography, [(18)F]PF-NB1 emerged as the best perfo

48 ontrast to nearby regions equaling that from autoradiography; a lower contrast was found using the co

49 tu hybridization, Western blotting and GTPgS autoradiography an upregulation of expression and the fu

50 Ex vivo PET and autoradiography analysis further confirmed our in vivo P

51 Both autoradiography analysis of sciatic nerves excised from

52 y PET, PET/CT, or PET/MR imaging followed by autoradiography analysis.

53 rated for [(125)I]11d and [(11)C]11e through autoradiography and biodistribution studies, imaging of

54 ted for NMDAR binding specificity in ex vivo autoradiography and brain biodistribution studies.

55 PR and SSTR2 expression analyzed by in vitro autoradiography and by quantitative reverse transcriptas

56 ter injection was also evaluated via ex vivo autoradiography and compared with amyloid-beta plaque de

57 was validated ex vivo by gamma-counting and autoradiography and compared with cleaved caspase-3 (CC3

58 as quantified on arterial cryosections using autoradiography and compared with CXCR4 and RAM-11 (macr

59 luated for tracer distribution using digital autoradiography and compared with histologic markers of

60 clinical breast cancer specimens by in vitro autoradiography and correlated this with corresponding m

61 macodynamics and efficacy assessment by TSPO autoradiography and CSF proteomics.

62 and evaluated for (18)F-EF5 distribution by autoradiography and EF5 binding by immunohistochemistry.

63 We measured TK activity by plaque autoradiography and expression of frameshifted and unfra

64 mall-animal PET imaging and combined ex vivo autoradiography and fluorescence immunohistochemistry.

65 Autoradiography and fluorescent-based microscopic imagin

66 Autoradiography and focused ion beam/scanning electron m

67 Autoradiography and H&E staining of cross-sections revea

68 Autoradiography and hematoxylin-eosin staining were perf

69 (111)In-cetuximab-F(ab')(2) was evaluated by autoradiography and histologic markers evaluated by immu

70 Autoradiography and histology results were consistent wi

71 to the location of scar tissue identified by autoradiography and histology.

72 d, frozen, and sliced for serial dual-tracer autoradiography and histology.

73 ligands, PBB3 and AV-1451, by fluorescence, autoradiography and homogenate binding assays with homol

74 Autoradiography and immunoblotting data showed that muta

75 [3H]PiB autoradiography and immunocytochemistry for beta-amyloid

76 Tumors were assessed ex vivo by digital autoradiography and immunofluorescence for microscopic v

77 by histologic examination was compared with autoradiography and immunofluorescence.

78 ce visualised by histology was compared with autoradiography and immunofluorescence.

79 For autoradiography and immunohistochemical evaluation, addi

80 Autoradiography and immunohistochemistry demonstrated co

81 In addition to imaging, autoradiography and immunohistochemistry experiments wer

82 Autoradiography and immunohistochemistry further confirm

83 Autoradiography and immunohistochemistry of the aorta re

84 Ex vivo autoradiography and immunohistochemistry were performed

85 PET imaging, biodistribution, autoradiography and immunohistochemistry, and ex vivo HG

86 r 15- to 16-mo-old mice correlated well with autoradiography and immunostaining (i.e., increased (18)

87 ley rats using western blotting, [(3)H]UCB-J autoradiography and immunostaining with confocal microsc

88 in slices of Sprague-Dawley rats by in vitro autoradiography and in living rats by in vivo small-anim

89 [(18)F]3 to CB2 was demonstrated by in vitro autoradiography and in vivo PET experiments using the CB

90 take were compared ex vivo using dual-tracer autoradiography and in vivo using PET in different xenog

91 yacrylamide gel electrophoresis, followed by autoradiography and mass spectrometry.

92 86192 was evaluated in tumors using in vitro autoradiography and PET with mice bearing bilateral PD-L

93 biodistribution was investigated by in vitro autoradiography and positron emission tomography (PET) i

94 sities as determined by human tissue section autoradiography and preclinical in vivo PET studies in t

95 termined in cynomolgus monkeys by whole-body autoradiography and radioanalysis of ocular tissues.

96 in brains of untreated mice was analyzed by autoradiography and saturation analysis using [(3)H]-ABP

97 Autoradiography and scintillation counting confirmed the

98 then sliced, and the slices were imaged with autoradiography and stained with hematoxylin and eosin.

99 In vivo results were confirmed by autoradiography and staining of human CD3 after postmort

100 ively accurate and spatially concordant with autoradiography and the small-animal PET examination.

101 y, sectioned, with the sections subjected to autoradiography and thionine counterstaining.

102 Ex vivo autoradiography and TSPO/CD68 immunostaining were also p

103 protein synthesis inhibition as measured by autoradiography and was also observed with cycloheximide

104 action for inflammatory markers, 3) receptor autoradiography, and 4) transcriptome analysis in the hi

105 radiography, [F-18]-AV-1451 nuclear emulsion autoradiography, and [H-3]-AV-1451 in vitro binding assa

106 periments with rat brain membranes, in vitro autoradiography, and blocking and displacement experimen

107 hematoxylin and eosin staining, (3)H-PK11195 autoradiography, and CD11b immunohistochemistry.

108 Here, we used 64Cu-PET-CT, MRI, autoradiography, and fluorescence imaging to track the k

109 tomography (SPECT)/computed tomography (CT), autoradiography, and fluorescence microscopy.

110 stigations were followed by biodistribution, autoradiography, and fluorescence-activated cell sorting

111 ubicin treatment was quantified by microPET, autoradiography, and gamma counting.

112 earts, by Pro-Q-Diamond/Sypro-Ruby staining, autoradiography, and immunoblotting using phosphoserine-

113 ce were analyzed with (18)F-FAC PET, digital autoradiography, and immunohistochemistry, and deoxyribo

114 gs were analyzed using fluorescence imaging, autoradiography, and immunohistochemistry.

115 ll-binding experiments using flow cytometry, autoradiography, and internalization assays with various

116 ts along the lines of fluorescence staining, autoradiography, and mass spectrometry.

117 The results from biodistribution, autoradiography, and microPET imaging showed higher [(18

118 Biodistribution studies, autoradiography, and PET experiments were performed to d

119 11)C with positron emission tomography, root autoradiography, and radiometabolite flux analysis to un

120 00 nM) were subjected to (18)F-fluorination, autoradiography, and small-animal PET imaging.

121 terogeneity of RP782 uptake was confirmed by autoradiography, and specificity was demonstrated using

122 y-derived indices correlated poorly with the autoradiography- and PET-derived ones (R = 0.06-0.54).

123 explained with PSMA expression levels using autoradiography (ARG) and immunohistochemistry (IHC).

124 , ex vivo biodistribution (BD), and in vitro autoradiography (ARG) experiments.

125 ound 1, which exhibited target engagement in autoradiography (ARG) studies in brain slices from HD mo

126 ystem and compared with quantitative ex vivo autoradiography as a gold standard.

127 ion of the radionuclide was visualized using autoradiography at predefined time points.

128 The autoradiography binding density of (18)F-fluorodeprenyl-

129 In vitro and ex vivo autoradiography binding experiments in Wistar and in mGl

130 Autoradiography binding patterns were consistent with th

131 cryosections of the brains were evaluated by autoradiography, by histology, and for EBD fluorescence

132 Within the tumor, (111)In-RGD2 autoradiography coincided with vascular integrin alphavb

133 ceptors using quantitative in vitro receptor autoradiography combined with a detailed analysis of the

134 Brain autoradiography confirmed clot dissolution in recombinan

135 Ex vivo autoradiography confirmed in vivo findings demonstrating

136 Autoradiography confirmed increased uptake in the cerebe

137 Both external optical imaging and autoradiography confirmed the high signal from the (18)F

138 Autoradiography confirmed the spatiotemporal profile.

139 (111)In-cetuximab-F(ab')(2) as determined by autoradiography correlated well with the distribution of

140 ce in (18)F-PBR06 uptake in these mice using autoradiography (cortex/striatum: 1.13 +/- 0.04 vs. 0.96

141 nd in the absence of motion, one can achieve autoradiography, CT, and PET image registration with spa

142 Quantitative autoradiography demonstrated a 1.6-fold induction of (18

143 Autoradiography demonstrated complete ablation of KOR bi

144 Ex vivo autoradiography demonstrated high uptake of (18)F-FPPRGD

145 Autoradiography demonstrated minimal uptake of flortauci

146 Ex vivo autoradiography demonstrated specific binding of (64)Cu-

147 Autoradiography demonstrated that (68)Ga-DOTA-ECL1i spec

148 The autoradiography-derived indices differed significantly (

149 ed indices correlated significantly with the autoradiography-derived ones (R = 0.57-0.85), but the va

150 rly gene expression and (14)C 2-deoxyglucose autoradiography during mother-to-infant fear transmissio

151 l CB2 attributes as demonstrated by in vitro autoradiography, ex vivo biodistribution, and positron e

152 Ex vivo autoradiography experiments were performed after the fin

153 In autoradiography experiments, (18)F-OF-NB1 displayed a he

154 and in vivo (small-animal PET/CT imaging and autoradiography) experiments in the presence of succinat

155 ensity in PET (F(DF=3) = 5.9, P = 0.001) and autoradiography (F(DF=3) = 4.2, P = 0.008).

156 We applied [F-18]-AV-1451 phosphor screen autoradiography, [F-18]-AV-1451 nuclear emulsion autorad

157 In all three cases, autoradiography failed to show detectable [F-18]-AV-1451

158 Activity concentrations were obtained using autoradiography for 20 specimens extracted with 18- and

159 on specific brain structures using receptor autoradiography, found that the desensitization treatmen

160 )F-FTC-146 in rats were assessed via PET/CT, autoradiography, gamma counting, and high-performance li

161 (2) [(3)H] muscimol-related autoradiography grains were distributed in all six neoco

162 (3) [(3)H] muscimol-related autoradiography grains were localized to the cortical ar

163 The combination of uptake studies and autoradiography greatly increases our understanding of h

164 vo retention of [F-18]-AV-1451 and performed autoradiography, [H-3]-AV-1451 binding assays, and quant

165 Cryosections were prepared for autoradiography, hematoxylin and eosin (H&E), and immuno

166 scanner correlated with results obtained by autoradiography, histologic evaluation, and polymerase c

167 the PET/CT scan, animals were sacrificed for autoradiography, histologic work-up, or RNA expression a

168 Here we use electron microscopy, autoradiography, histology and preclinical and clinical

169 ET/CT, tumors were cut into cryosections for autoradiography, histology, and immunohistochemistry.

170 with macrophages in aorta cryosections using autoradiography, histology, and immunostaining.

171 was to solve this problem by using combined autoradiography-histology methods.

172 of tumors and lymph nodes was performed via autoradiography, histopathology, and immunohistochemistr

173 d tomography/computed tomography imaging and autoradiography illustrated spatial distribution within

174 The Hoechst-to-autoradiography image registration was done using rigid

175 m was clearly visualized in PET and in vitro autoradiography images of control animals and was no lon

176 cer uptake was determined on micro-SPECT and autoradiography images of tumor sections.

177 Digital autoradiography images revealed a nonhomogeneous distrib

178 Autoradiography images were correlated with histopatholo

179 The response of autoradiography imaging plates was calibrated using dumm

180 es through a combination of fluorescence and autoradiography imaging.

181 Autoradiography, immunohistochemical staining, and HGF E

182 specimens including radioactivity counting, autoradiography, immunohistochemistry, and antigen densi

183 In vitro PET autoradiographies in rat brain sections with this radiot

184 on tomographic imaging as well as postmortem autoradiography in an independent sample with Parkinson

185 d specificity were evaluated by quantitative autoradiography in apolipoprotein E-deficient (apoE(-/-)

186 labeled recombinant human LCN2 (rh-LCN2) and autoradiography in baboon, macaque, and human brain sect

187 o aneurysm and its specificity were shown by autoradiography in carotid aneurysm.

188 nd distribution determined by tissue-section autoradiography in preclinical species and humans.

189 opharmacologic evaluations included in vitro autoradiography in rat brain and PET scans on anesthetiz

190 ith a commercial small-animal PET system and autoradiography in tumor-bearing mice.

191 Using competitive autoradiography in wildtype (WT) and AVPR1A knockout (KO

192 At autoradiography, intravenous pretreatment with the selec

193 Using thin tissue section autoradiography, it is possible to visualize the spatial

194 l animal positron emission tomography (PET), autoradiography, microdialysis and molecular biology in

195 s evaluated for CCR2 with immunostaining and autoradiography (n = 6, COPD) with (64)Cu-DOTA-ECL1i.

196 Autoradiography of (177)Lu-DOTA-PP-F11N (without and wit

197 Binding characteristics were determined by autoradiography of AD brain sections in vitro and using

198 Autoradiography of aortae at 2 h postinjection revealed

199 oal was to develop a method for quantitative autoradiography of biopsy specimens (QABS), to use this

200 Autoradiography of biopsy specimens obtained using 5 typ

201 Finally, ex vivo autoradiography of brain sections from amyloid precursor

202 Autoradiography of brain slides confirmed that the accum

203 In vitro autoradiography of human and animal pancreatic sections

204 on preclinical work, on quantitative in vivo autoradiography of human tumor slices, and on human data

205 Microscopic ex vitro autoradiography of kidney showed F-Dapa binding to the a

206 These findings were verified directly by autoradiography of normal and atherosclerotic arteries.

207 Ex vivo brain autoradiography of radioligands was performed at subacut

208 in each group) and were killed afterward for autoradiography of the brain.

209 Similar results were obtained from ex vivo autoradiography of the ipsilateral versus contralateral

210 Ex vivo autoradiography of tissue sections confirmed uptake of (

211 Autoradiography on a human heart specimen was conducted

212 ptor (alpha2A-AR) expression was assessed by autoradiography on brain slices, and Galphai proteins ex

213 and selectivity for the GRPR during receptor autoradiography on human cancer samples (IC(50) in nM: G

214 n of 50% (IC50) values were determined using autoradiography on human tissues with (125)I-GLP-1(7-36)

215 Autoradiography on rat brain sections indicated that the

216 binding measures with postmortem human brain autoradiography outcomes showed a high correlation for t

217 of (18)F-FET uptake were observed in PET and autoradiography (P > 0.05).

218 indicated by ex vivo gamma-well counting and autoradiography (P < 0.05).

219 validated in rodents using in vitro/ex vivo autoradiography, PET experiments, and dose-response stud

220 and was evaluated in Wistar rats by in vitro autoradiography, PET imaging, ex vivo biodistribution, m

221 istribution over time using a combination of autoradiography, positron emission tomography (PET)/comp

222 es correlate strongly with the corresponding autoradiography protein levels.

223 Quantitative whole-body autoradiography (QWBA) analyses obtained on high-resolut

224 small-animal PET were highly correlated with autoradiography (r > 0.99) and with each other (r = 0.97

225 The mean error of Hoechst to (18)F-FLT autoradiography registration (both images acquired from

226 either of the in vitro methods, and digital autoradiography resulted in the highest measurements.

227 Similarly, PET/CT and autoradiography results demonstrated accumulation of (18

228 Postmortem autoradiography results revealed lower expression of the

229 Autoradiography revealed [3H]PiB binding in neocortical

230 wed by quantitative electron microscopy (EM) autoradiography revealed abundant viral RNA synthesis as

231 PET imaging and ex vivo autoradiography revealed more parenchymal distribution o

232 t analysis of in vivo and ex vivo images and autoradiography revealed significantly higher Tc-99m-HL9

233 Autoradiography revealed that [(11)C]DASB was sensitive

234 ing for fibrillary beta-amyloid, and ex vivo autoradiography served as terminal gold standard assessm

235 SPECT/CT and autoradiography showed a very heterogeneous distribution

236 Quantitative autoradiography showed an increase in N/OFQ receptor bin

237 Ex vivo autoradiography showed excellent spatial correlation wit

238 Autoradiography showed high (11)C-donepezil binding (dis

239 Results: Autoradiography showed no difference in (11)C-JNJ717 bin

240 take could be observed on PET scans, whereas autoradiography showed slight radiotracer accumulation i

241 Both PET/CT and autoradiography showed that [(64)Cu]-NPs entered the let

242 Ex vivo autoradiography showed that regional brain distribution

243 Autoradiography showed that the localizations of radioac

244 g using a silicon-strip detector for digital autoradiography, staining for histologic characterizatio

245 ich correlated well with biodistribution and autoradiography studies (i.e., much higher tracer uptake

246 Furthermore, brain-slice autoradiography studies demonstrated the absence of [(3)

247 ific binding of [3H]CUMI-101 by quantitative autoradiography studies in postmortem baboon and human b

248 -9 with AD brain tissue sections and ex vivo autoradiography studies in transgenic mouse brain sectio

249 Furthermore, in vitro autoradiography studies of [(18)F]-9 with AD brain tissu

250 sitron emission tomography (PET) and ex vivo autoradiography studies of [(18)F]13 in mice showed high

251 Semiquantitative autoradiography studies on postmortem tissue sections of

252 Ligand binding autoradiography studies showed nicotine and CSE to have

253 Biodistribution and autoradiography studies were also performed to confirm t

254 In vitro receptor autoradiography studies were performed to establish the

255 n identified as a promising I(2) ligand from autoradiography studies, displaying high affinity and go

256 In autoradiography studies, N-(11)C-methyl-JNJ-31020028 rec

257 generation patient brain tissue slices using autoradiography studies.

258 By autoradiography, the TSPO radiotracer binding potential

259 We first used receptor autoradiography to compare MOR binding densities between

260 human hearts were compared using radiocaine autoradiography to determine that the failing heart has

261 14-16 d), rats underwent ex vivo dual-tracer autoradiography using (18)F-FET and (3)H-MET.

262 Micro-PET and autoradiography using [(11)C]raclopride confirmed a stro

263 vestigated in competition binding assays and autoradiography using a fresh cardiac thrombus from an e

264 ted by saturation binding assay and in vitro autoradiography using post-mortem Alzheimer's disease br

265 25)I-pentixafor uptake in the vessel wall on autoradiographies was located in macrophage-rich regions

266 Autoradiography was conducted to determine regional FBzB

267 Autoradiography was performed in 1 PSP patient, with dig

268 In vitro receptor autoradiography was performed on 55 NETs, comparing in e

269 stologic samples were available; (68)Ga-PSMA autoradiography was performed on an exemplary case of PE

270 Ex vivo autoradiography was performed on resected brain slices a

271 Autoradiography was performed using technetium-pertechne

272 In vitro receptor autoradiography was performed with (125)I-JR11 and (125)

273 Whole-hemisphere autoradiography was performed with (18)F-fluorodeprenyl-

274 define CGRP receptor binding sites, in vitro autoradiography was performed with [(3)H]MK-3207 (a CGRP

275 Autoradiography was performed with [(3)H]MK-3207 to demo

276 (99m)Tc-AGA-2 uptake detected by autoradiography was significantly higher in AAA compared

277 Using autoradiography, we confirmed lower SV2A in the substant

278 the method of in vitro quantitative receptor autoradiography, we demonstrated that-for instance, in n

279 With autoradiography, we determined binding affinities and le

280 Using receptor autoradiography, we provide the first distributional map

281 Using [(5)S]GTPgamma binding autoradiography, we show that application of flupenthixo

282 stimulated [(35)S]GTPgammaS and [(3)H]ligand autoradiography were assessed by statistical parametric

283 nalysis of vascular integrin alphavbeta3 and autoradiography were completed.

284 (18)F-FET PET scans and ex vivo autoradiography were performed in animals receiving a si

285 Fluorescence microscopy, histopathology, and autoradiography were performed on representative section

286 X-ray computed tomography and autoradiography were performed to identify the spatial l

287 in vivo and ex vivo imaging and quantitative autoradiography were performed.

288 Histochemical analyses and ex vivo autoradiography were ultimately performed in a subset of

289 Subsequently, SPECT imaging and autoradiography were used to determine in vivo binding o

290 stribution studies, and small-animal PET and autoradiography were used to determine the uptake of (64

291 Immunofluorescence, immunohistochemistry and autoradiography were utilized to examine the tumor vascu

292 tumor was assessed using PET/CT imaging and autoradiography, whereas TAM burden was determined using

293 Moreover, autoradiography, which recorded beta particles from (198

294 hods: For the in vitro portion of the study, autoradiography with (18)F-DPA714 and (11)C-JNJ717 was p

295 Autoradiography with [H-3]-(+)-PHNO and in situ hybridiz

296 (123)I-PIP autoradiography with human tissue revealed accumulation

297 ion, we used in vivo PET imaging and ex vivo autoradiography with Pittsburgh compound B ((11)C-PIB) a

298 In vitro autoradiography with the 5-HT7R selective radioligand (3

299 n with ER expression was studied by in vitro autoradiography with the GRP-R agonist (111)In-AMBA.

300 wed colocalization of tracer accumulation on autoradiography, with insulin-positive cells and GLP-1R