ライフサイエンスコーパス: coregister

1 mages from the two modalities are accurately coregistered.

2 tically normalized to whole-brain counts and coregistered.

3 MRI scan to which each functional image was coregistered.

4 sex- and age-matched normal volunteers were coregistered.

5 C-arm CT and MR imaging data sets were coregistered.

6 nd MRI scans of the thighs were obtained and coregistered.

7 basis of histology and were transferred into coregistered (11)C-choline PET/CT volumes to calculate t

8 for the volumes of interest determined using coregistered (18)F-FDG images for both the volume of int

9 Coregistered 18F-FDG PET/CT can provide precise anatomic

10 We describe a novel fluoroscopy coregistered, 4-dimensional catheter tracking technology

11 her landmarks on a scan to semiautomatically coregister a digital mouse phantom with a small-animal P

12 Each was spatially coregistered according to predefined segmental and subse

13 The ICG-enhanced optical images coregistered accurately with Gadolinium-enhanced magneti

14 eries from three donor hearts were acquired, coregistered among modalities, and assessed for the pres

15 Coregistered anatomic MR and CT images of 15 glioblastom

16 Tracts were superimposed on coregistered anatomic MR images to parcel the white matt

17 Intravascular ultrasound provided coregistered anatomical images of arteries.

18 mbrane antigen (PSMA) expression was used to coregister and correlate the CLI signal observed with th

19 ensional matching of rCBF images was used to coregister and quantify results.

20 de microdistribution and histology were then coregistered and analyzed to assess radionuclide trappin

21 pectrometry and corresponding histology were coregistered and analyzed using multivariate statistical

22 IVOCT and histological TCFA images were coregistered and compared.

23 The SPECT images were coregistered and fused.

24 software, and processed metabolite maps were coregistered and normalized to a standard brain template

25 PET and CT images were coregistered and ROIs drawn on the basis of the location

26 The imaging data were coregistered and segmented.

27 The images were coregistered and warped to standard space for significan

28 The EI defined lesion areas were coregistered and warped to the corresponding histopathol

29 -MR images of NCI-H460 xenograft tumors were coregistered, and a population-based GMM was implemented

30 parametric images of CBF (in mL/100 g/min), coregistered, and analyzed using grid-based regions of i

31 These images were coregistered, and differences in tumor-water diffusion v

32 ic and magnetic resonance imaging scans were coregistered, and the caudate and the putamen were trace

33 The PET and MRI images for each subject were coregistered, and the whole thalamus, mediodorsal nucleu

34 and glucose metabolism (MRglc) from the MRI-coregistered, atrophy-corrected PET scans.

35 A coregistered bone probability map was also included in t

36 PET/CT and MR images were coregistered by using pelvic bones as fiducial markers;

37 ent molecular tomography in conjunction with coregistered computed tomography imaging.

38 Positron emission tomography (PET) and coregistered computed tomography/fluorine 18 fluorodeoxy

39 hors developed and evaluated a technique for coregistering computed tomographic (CT) and computed rad

40 SPECT with coregistered contrast-enhanced CT or MR imaging and SPEC

41 On (18)F-FDG PET/CT and coregistered contrast-enhanced CT scans of 159 females (

42 ametric MR imaging models developed by using coregistered correlative histopathologic data yielded a

43 S) for detection of prostate cancer by using coregistered correlative histopathologic results, and to

44 Successful fusion of real-time US to coregistered CT and FDG PET scans was achieved in all pa

45 ar phases enabled acquisition of a perfectly coregistered CT angiogram and venous phase-enhanced CT s

46 creased 18F-FDG uptake was compared with the coregistered CT image to differentiate physiologic from

47 The collimator response model used the coregistered CT image to estimate the source-target dist

48 how that anatomic information available from coregistered CT images may improve in vivo localization

49 which consists of dual-echo UTE images and a coregistered CT scan from the same subject.

50 Automatically coregistered CTA images and extracted trees were used to

51 V contours were adjusted in 11 studies using coregistered CTA images as a guide.

52 g coefficients were interpreted by using the coregistered DBT images.

53 se parcellation maps were then compared with coregistered diffusion tensor imaging color maps to assi

54 ensor imaging maps were then overlaid on the coregistered DIR images, and mean FA and MD values were

55 Coronary assignment for coregistered displays and the 17-segment LV model differ

56 For data analysis, correspondence between coregistered displays and the 17-segment LV model for as

57 cardial disease was assessed, and utility of coregistered displays in optimizing surgical revasculari

58 Assessment of CIHD can be improved by using coregistered displays that directly relate the condition

59 ent of CIHD was evaluated, accuracy of using coregistered displays to evaluate the extent of CAD and

60 compared with alternate imaging modalities, coregistered displays were believed to demonstrate the r

61 Coregistered displays were deemed concordant with select

62 were also blood group incompatible to their coregistered donor.

63 tion assessed by histology and compared with coregistered ex vivo VH-IVUS and OCT.

64 display of US/CT image fusion with overlaid coregistered FDG PET targets was used for guidance; navi

65 egions of interest (ROIs) were derived after coregistering FDG PET and MR images by using high-throug

66 These coregistered FMT and SPECT/CT results with MOMIAs may fa

67 uired on separate, dedicated scanners may be coregistered for therapy planning; however, dual-acquisi

68 The subtraction SPECT and the coregistered fused SPECT/CT studies were interpreted sep

69 Resulting transformations were applied to coregistered gray matter probability maps, and the quali

70 fin-embedded histology using a protocol that coregistered histological sections to NLM images for pai

71 assessed VH-IVUS and CT Plaque Maps against coregistered histology in 72 (VH-IVUS) and 87 (CT) segme

72 ified as cancer or noncancer on the basis of coregistered histopathologic data.

73 anced by the ability to acquire sequentially coregistered ictal and postictal SPECT images of a singl

74 In order to properly coregister images from different modalities, each tissue

75 This method provides coregistered images of oxygenation and blood volume/flow

76 y and are capable of producing superimposed, coregistered images, greatly facilitating interpretation

77 Coregistering images from male and female brains identif

78 Imaging coregistered increased catS and osteogenic activities in

79 These unfolded cervical cord images were coregistered into a common standard space, and smoothed

80 of interest were automatically delineated on coregistered magnetic resonance images and full kinetic

81 Coregistered magnetic resonance imaging (MRI) and positr

82 never-medicated schizophrenic patients using coregistered magnetic resonance imaging (MRI) templates.

83 orodeoxyglucose for metabolic assessment and coregistered magnetic resonance imaging for atrophy asse

84 thod (regions of interest were identified on coregistered magnetic resonance imaging scans) and by a

85 With the analysis of coregistered MALDI imaging and CD31 immunohistochemical

86 sive way of data acquisition and analysis by coregistering mass spectrometric data on photomicrograph

87 Coregistered micro-CT with small-animal PET along with b

88 ical coherence tomography (SD-OCT) scans and coregistered microperimetry.

89 The procedure consisted of sequential coregistered MR and PET image acquisition, using gadolin

90 this preclinical study, we demonstrated that coregistered MR and PET images provide helpful informati

91 Region-of-interest analysis on coregistered MR images and statistical parametric mappin

92 atlas, we created a PET brain template using coregistered MR images.

93 l striatum, SN, and cerebellum were drawn on coregistered MR images.

94 neated on the individual SPECT scans and the coregistered MR images.

95 (SN), and cerebellum were manually drawn on coregistered MR images.

96 Regions of interest (ROIs) were defined on coregistered MR images.

97 Coregistered MR/PET images were used to guide tumor biop

98 asurement with (18)F-FDG in regions drawn on coregistered MRI after partial-volume correction in 41 p

99 salignment between the 2 scanners, perfectly coregistered MRI and PET volumes were reproducibly obtai

100 Overlap between coregistered MRI and SPECT scans corroborated the presen

101 the applicability of cortical flattening of coregistered MRI to (18)F-FDG PET on the HRRT system (hi

102 as performed using predefined templates from coregistered MRI.

103 These data demonstrate the utility of coregistered multimodal imaging as a platform for evalua

104 aw of rats provided spatially and temporally coregistered nuclear and optical contrasts.

105 This study suggests that OCT alone (OCTA and coregistered OCT B-scans) features sensitivity and speci

106 After the spatial coregistering of images acquired at 3.0-T and 1.5-T MR i

107 All (18)F-FDG PET/CT acquisitions were coregistered on the initial scan.

108 perfusion-weighted image-defined lesion were coregistered onto tp1 CMRO(2) maps.

109 aim of this study was to evaluate the use of coregistered PET and CT (PET/CT) in patients with suspec

110 Within IBV, coregistered PET data were extracted to identify the act

111 tic resonance images and were transferred to coregistered PET data.

112 For analysis, we coregistered PET images to individual MR images and auto

113 an and the parcellations were applied to the coregistered PET scans.

114 defined on MR imaging and applied to dynamic coregistered PET to generate time-activity curves.

115 dose to metabolically active sites based on coregistered PET/CT data.

116 The coregistered PET/MR images were in excellent agreement w

117 fter percutaneous coronary stenting (PCS) by coregistering PET and coronary CT angiography (CTA).

118 tion of methylene blue accumulation, whereas coregistered photoacoustic/US images depict lymph node p

119 r improved MPS quantification by guiding the coregistered physiologic (MPS) with anatomic CTA informa

120 This work illustrates that anatomically coregistered pO(2) maps of tumors can be readily obtaine

121 On coregistered positron emission tomography (PET) and MRI

122 s of the structures were applied to matching coregistered positron emission tomography scans, and thr

123 We used coregistered positron emission tomography with [18F]fluo

124 The electrode was localized by coregistering preoperative magnetic resonance imaging an

125 A pixel-based analysis of coregistered pretreatment CTP and 24-hour diffusion-weig

126 unofluorescent double-labeling techniques to coregister PV- and CB-expressing neurons with GAD67 in t

127 nued the chain as many as 5 months after the coregistered recipients in their own pairs had received

128 f the transplantations, the donors and their coregistered recipients underwent surgery simultaneously

129 ractional anisotropy (FA) were obtained from coregistered regions of interest.

130 oint confidence scale, 2 readers interpreted coregistered scan sets on a workstation.

131 olution elemental imaging platform combining coregistered secondary ion mass spectrometry and high re

132 The coregistered set of morphological and compositional info

133 The combination of coregistered SIMS and MALDI images results in detailed a

134 Images were coregistered so that region-of-interest placement was id

135 nstruction and attenuation correction of the coregistered SPECT images.

136 First, the mean reconstructed values within coregistered SPECT VOIs were estimated from MLEM reconst

137 Reconstructed and coregistered SPECT/CT images were converted into 3D dens

138 First, the coregistered structural image (MRI/CT) is downgraded to

139 Coregistered T1 MR images were used for region-of-intere

140 ring registration technique was then used to coregister the (18)F-FDG PET and CT planning image datas

141 A similar procedure was used to coregister the anatomic MR data for a new subject to the

142 registration algorithm that was designed to coregister the coordinates of endoluminal colonic surfac

143 tumors in the liver, which was confirmed by coregistering the gamma camera and T2-weighted MR images

144 nomically, and without selection bias, while coregistering the genetic information with the preserved

145 l receive coil was sufficiently accurate for coregistering the smallest clinically important lesions

146 (PBR) and negative BOLD response (NBR) after coregistering their spatial locations.

147 The tractography data were overlaid on coregistered three-dimensional T1-weighted images to vis

148 All images were coregistered to a common minimum deformation template fo

149 The PET images were manually coregistered to a MR imaging atlas of the pig brain.

150 tracking was applied to reconstruct TS maps coregistered to B-scans.

151 on was assessed using subacute perfusion MRI coregistered to baseline imaging.

152 and soft tissue in volumetric head MR images coregistered to CT data for training.

153 mpling was performed on PET images that were coregistered to MR images acquired from each volunteer.

154 SPECT, ictal SPECT, subtraction ictal SPECT coregistered to MR imaging (SISCOM), and interictal PET

155 ated for cancer and noncancerous disease and coregistered to MR imaging with an interactive deformabl

156 chnique of composite subtraction ictal SPECT coregistered to MRI (SISCOM).

157 Magnetic resonance images (coregistered to PET) were used to define regions of inte

158 Images were coregistered to pretreatment scans, and changes in tumor

159 Perfusion images were coregistered to structural images, corrected for partial

160 DT imaging data were coregistered to the anatomic magnetic resonance study an

161 The resulting images were coregistered to the block-face images using a moving lea

162 MR images were similarly coregistered to the block-face images, allowing the stru

163 serially collected histological sections and coregistered to the distribution of each shear metric.

164 nantly at mid menstrual cycle, and were best coregistered to the fallopian tubes on contrast-enhanced

165 performed using individual volumetric MRI's coregistered to the PET ADD image.

166 fiber tracts from a probabilistic atlas were coregistered to the reference brain.

167 Postresection MR images were coregistered to the SPECT scans using image analysis sof

168 , transposon repeats, and more as a stack of coregistered tracks.

169 based on a pixel-by-pixel comparison of two coregistered transmission images for each subject.

170 Coregistered US and photoacoustic images were acquired s

171 sensors, was used to simultaneously acquire coregistered US images and optical data.

172 maged with a hand-held probe consisting of a coregistered US transducer and an NIR imager.

173 The lesion location provided by coregistered US was used to guide optical imaging.

174 tissue, and air), which were then nonrigidly coregistered using a diffeomorphic approach.

175 Respiration-gated PET data were coregistered using the MR-derived motion fields to obtai

176 fMRI signal change in response to spatially coregistered visual, somatosensory, and bimodal stimuli.

177 sion scanning and shifting cine CT images to coregister visually with PET.

178 (cine) 2D images of the bicuspid valves were coregistered with 4D flow data, directly linking cusp fu

179 determinations; (3) measurements are exactly coregistered with all other chemical, elemental, isotopi

180 Cross-sectional images were coregistered with CF and FA to obtain depth-resolved inf

181 adiotracer with positron emission tomography coregistered with computed tomography (FDG PET/CT) provi

182 CLIO-VT750 FMT signal coregistered with contrast enhancement in the hypokineti

183 was measured on sodium 23 ((23)Na) MR images coregistered with delayed contrast-enhanced (1)H MR imag

184 Daily pretreatment images were coregistered with digitally reconstructed radiographs so

185 nd collagen and degree of discontinuity were coregistered with electrophysiological parameters (MI+;

186 scans using (18)F-fluoride ion and (18)F-FDG coregistered with high-resolution small-animal CT scans

187 Images obtained by MSI can be coregistered with images obtained by other molecular ima

188 For image validation, parameters were coregistered with immunohistochemical analysis.

189 When the same regions were coregistered with immunohistochemical stains for tyrosin

190 s of the heart to be acquired in vivo and be coregistered with in vivo cardiac magnetic resonance ima

191 Positron emission tomography scans coregistered with magnetic resonance images of eight sub

192 [11C]AMT scans were coregistered with magnetic resonance imaging and with gl

193 SPECT datasets were coregistered with MR images, and regional time-activity

194 Spectroscopic imaging data were coregistered with MR imaging segmentation data to obtain

195 Ictal and interictal studies were coregistered with patients' MRI scans using automated so

196 s was used to delineate the pancreas and was coregistered with PET and X-ray computed tomography imag

197 rmal breathing, or shifted cine CT data that coregistered with PET data.

198 Computed tomographic images were coregistered with PET images to improve delineation of a

199 NIR optical imaging system, and images were coregistered with plain radiographic images.

200 he advantage that the specific signal can be coregistered with soft-tissue anatomy and functional tis

201 CT coregistered with SPECT was used to identify the positio

202 tically normalized to whole-brain counts and coregistered with standard anatomic space.

203 sotropy (FA) and ADC maps were generated and coregistered with T2-weighted MR images.

204 distribution of radioactivity predominantly coregistered with the infarcted regions.

205 FMT reconstructions were coregistered with the MR images.

206 plaque components using combined in vivo CT coregistered with virtual histology intravascular ultras

207 Anatomic images of LFP and BOLD were coregistered within 0.10 mm accuracy.

208 In addition, the coregistered x-ray CT image was used to determine anatom