ライフサイエンスコーパス: interobserver variability

1 ere performed to determine intraobserver and interobserver variability.

2 -to-muscle contrast and demonstrated minimal interobserver variability.

3 opulation characteristics, CT technique, and interobserver variability.

4 pa analysis was also performed to assess for interobserver variability.

5 e and mass with good accuracy and acceptable interobserver variability.

6 art, and we calculated the intraobserver and interobserver variability.

7 icient of variation was calculated to assess interobserver variability.

8 images had the highest specificity and least interobserver variability.

9 MR images and is an important contributor to interobserver variability.

10 RY are robust radiomics tools with excellent interobserver variability.

11 >=7) but is limited by reader experience and interobserver variability.

12 icipants with CRLM demonstrated considerable interobserver variability.

13 oper biopsy orientation, and it suffers from interobserver variability.

14 plex or have not been assessed for intra- or interobserver variability.

15 underestimation of flow values and increased interobserver variability.

16 DCIS is challenging due to undersampling and interobserver variability.

17 ility of pathologists with IBD expertise and interobserver variability.

18 as associated with significant reductions in interobserver variability.

19 e diagnosis of LGD is limited by substantial interobserver variability.

20 is laborious and may be prone to intra- and interobserver variability.

21 iquantitative and can have intraobserver and interobserver variability.

22 however, its assessment is complex with high interobserver variability.

23 is approach is time-consuming and subject to interobserver variability.

24 mode echogenicity are negatively affected by interobserver variability.

25 PS has started efforts aimed at reducing the interobserver variability.

26 prone to error due to tumor heterogeneity or interobserver variability.

27 st Gleason pattern segmentation despite high interobserver variability.

28 ch optimization method was evaluated through interobserver variability.

29 hology, which is associated with substantial interobserver variability.

30 between surgeon and radiologist may decrease interobserver variability.

31 to assess the deep learning model as well as interobserver variability.

32 p vascular network may be subject to greater interobserver variability.

33 access to both SBR and CPR data to minimize interobserver variability.

34 -Altman plots were used to assess intra- and interobserver variability.

35 orrelation coefficient was used to determine interobserver variability.

36 ilcoxon signed-rank test were used to assess interobserver variability.

37 scans from patients with nAMD is subject to interobserver variability.

38 reprocessed for determination of intra- and interobserver variability.

39 used in rheumatoid arthritis (RA), have high interobserver variability.

40 nature of the procedure, sampling error, and interobserver variability.

41 r-intensive analyses and potential intra- or interobserver variability.

42 there has been little attempt to quantitate interobserver variability.

43 due to PE, but with low sensitivity and high interobserver variability.

44 thickness were assessed, as were intra- and interobserver variability.

45 were used to evaluate both intraobserver and interobserver variability.

46 sible for significantly increased intra- and interobserver variabilities.

47 Additionally, the RT3D technique reduced the interobserver variability (37% to 7%) and intraobserver

48 e index (diagnostic accuracy range, 50%-87%; interobserver variability, +/-7%).

49 To assess the interobserver variability, a Cohen kappa analysis was us

50 out contrast injection for intraobserver and interobserver variabilities (all p < 0.001).

51 ssification with a high accuracy and without interobserver variability, along with the molecular reso

52 Practice Advice 2: Given the significant interobserver variability among pathologists, the diagno

53 Intra- and interobserver variability analyses showed high agreement

54 By avoiding interobserver variability and accelerating computation,

55 mance to conventional assessment and reduced interobserver variability and assessment time.

56 ented in practice, AI-based VSS could reduce interobserver variability and could standardize treatmen

57 assessment, quantitative assessment has low interobserver variability and could yield a tumor size c

58 to routine practice because it is limited by interobserver variability and generally only meets accep

59 However, interobserver variability and image quality influence ob

60 ved a more guarded reception lately owing to interobserver variability and lack of standardized proto

61 stological features, generating considerable interobserver variability and limited diagnostic reprodu

62 compared with T2-weighted imaging, reducing interobserver variability and measurement error.

63 ctional MR examination significantly reduces interobserver variability and offers reliable and reprod

64 Interobserver variability and practice guidelines remain

65 Interobserver variability and specialized experience are

66 n tumour histology) resulted in considerable interobserver variability and substantial variation in p

67 Interobserver variability and the correlation between au

68 tial but also challenging due to significant interobserver variability and the time consumed in manua

69 1.6% for intraobserver variability, 4.0% for interobserver variability, and 10.3% for scan-rescan var

70 .6% for intraobserver variability, 10.7% for interobserver variability, and 19.8% for scan-rescan var

71 0.7% for intraobserver variability, 1.5% for interobserver variability, and 8.1% for scan-rescan vari

72 le segmentation is labor intensive, prone to interobserver variability, and impractical for large-sca

73 to improve endoluminal visualization, reduce interobserver variability, and improve patient acceptanc

74 e heterogeneity quantification, with reduced interobserver variability, and independent prognostic va

75 and stages steatosis accurately with limited interobserver variability, and performance is not hamper

76 ompliance is more often identified, has less interobserver variability, and poses less risk to the pa

77 er biopsy is associated with sampling error, interobserver variability, and potential complications.

78 n interclass correlation were used to define interobserver variability, and receiver operating charac

79 ppropriate testing, improve accuracy, reduce interobserver variability, and reduce diagnostic and rep

80 n PET measures (22%-44%) was attributable to interobserver variability as measured by the reader stud

81 The addition also reduced interobserver variability (Az = 0.86 vs Az = 0.75).

82 To study possible differences in interobserver variability between the 3 applied PSMA rad

83 ncer patients were analyzed to determine the interobserver variability between the automated BSIs and

84 ations still exist including sampling error, interobserver variability, bleeding, arteriovenous fistu

85 3D-Gd-MRA revealed a slightly improved interobserver variability but incorrectly graded 6 of 34

86 evaluation of renal artery stenosis with an interobserver variability comparable with that of conven

87 LV-METRIC had reduced intraobserver and interobserver variability compared with other methods.

88 Owing to the high interobserver variability, CT scan was not associated wi

89 g +/- 9, kappa = 0.49 [P < .0001]) and less interobserver variability (difference, 5.4 g +/- 18, kap

90 Conclusion: Interobserver variability differs among the 3 clinically

91 cinoma is of major importance; however, high interobserver variability exists.

92 Interobserver variability expressed as 1 SD was 3.6 mm f

93 (F = 6.9, P = 0.011; trained observers) and interobserver variability (F = 33.7, P = 0.004; group of

94 ed with TTE, CMR has lower intraobserver and interobserver variabilities for RVol(AR), suggesting CMR

95 pectively compare diagnostic performance and interobserver variability for computed tomography (CT) a

96 Interobserver variability for conventional angiograms wa

97 roach can provide a significant reduction in interobserver variability for DCE MR imaging measurement

98 considered clinically insignificant because interobserver variability for echocardiographic measurem

99 Interobserver variability for individual CT findings was

100 Interobserver variability for interpretation of the lesi

101 However, data on interobserver variability for pancreatoduodenectomy-spec

102 (100% versus 47%; P<0.0001) and with better interobserver variability for RT-ungated (coefficient of

103 Intraobserver and interobserver variability for score assessment were 6% a

104 Good interobserver variability for the definitions of surgica

105 Interobserver variability for the degree of renal artery

106 DSA had a substantial interobserver variability for the grading of stenosis (m

107 The interobserver variability for the ISGPS-defined complica

108 kappa Values for assessment of interobserver variability for the T2, single-voxel, mult

109 Herein we report interobserver variability for two validated radiomic too

110 t the two ROIs demonstrated good to moderate interobserver variability (for the two ROIs, 0.46 and 0.

111 ese challenges, however, they are subject to interobserver variability if semi-automated segmentation

112 This finding may be associated with high interobserver variability in Apgar scoring, reduced vita

113 ial for improving specificity and decreasing interobserver variability in biopsy recommendations.

114 causality, but there was still considerable interobserver variability in both.

115 eneous histological patterns and substantial interobserver variability in classification.

116 This AI system overcomes substantial interobserver variability in expert predictions, perform

117 its clinical application remains limited by interobserver variability in grading and quantification,

118 The uncertainty is compounded by interobserver variability in histologic diagnosis.

119 Analyses of the interobserver variability in hue scaling revealed multip

120 ot quite as good, and there is slightly more interobserver variability in interpretation.

121 a significant difference, there was greater interobserver variability in lesion descriptions among r

122 There was significant interobserver variability in Pflex, with a maximum diffe

123 ime needed to complete this task, as well as interobserver variability in radiologist predictions.Key

124 Interobserver variability in reporting between a senior

125 A change of >32 mum was likely to exceed interobserver variability in SFCT.

126 imaging can have may be in the reduction of interobserver variability in target volume delineation a

127 of best practice guidelines results in high interobserver variability in TC assessments.

128 acy for less experienced readers and reduces interobserver variability in the diagnosis of ECE of pro

129 There is significant interobserver variability in the diagnosis of LGD even a

130 as evaluated in the 2 trained observers, and interobserver variability in the group of 15 observers.

131 chnique also minimized right-left kidney and interobserver variability in the measurement of EF.

132 Large interobserver variability in the measurement of vascular

133 s investigations have identified significant interobserver variability in the measurements of central

134 Purpose To evaluate interobserver variability in the morphologic tumor respo

135 n that of physicians, who showed significant interobserver variability in their assessment.

136 eatures, and radiology residents had greater interobserver variability in their selection of five of

137 doses, reducing the toxicity issues and the interobserver variability in tumor detection.

138 Interobserver variability, interobserver correlation, an

139 FI vascularization flow index for intra- and interobserver variability; intraobserver values were 0.9

140 compare AI-to-expert variability and expert interobserver variability (IOV), and an external set to

141 Interobserver variability is presented with Gwet AC-1 me

142 Interobserver variability (kappa statistic or intraclass

143 toxylin and eosin-stained slides is prone to interobserver variability, leading to inconsistent clini

144 The MRA measurements had low interobserver variability (< or =5%) and good correlatio

145 Interobserver variability may be reduced in the future b

146 A and PC-flow revealed the best (P = 0.0003) interobserver variability (median kappa = 0.75) and almo

147 aobserver variations were small, with a mean interobserver variability of -0.1 g +/- 2.3 and a mean i

148 ty to the radiologists with 0.74 mm than the interobserver variability of 0.77 mm and generalised to

149 Our purpose was to determine and compare the interobserver variability of 3 clinically frequently use

150 d to evaluate the diagnostic performance and interobserver variability of CO-RADS (COVID-19 Reporting

151 been reported evaluating the performance and interobserver variability of computerized tomographic co

152 rdance with current guidelines to assess the interobserver variability of FCT measurement by intracla

153 es and calcification contributed to the high interobserver variability of FCT measurement.

154 The overall interobserver variability of K(trans) with manual ROI pl

155 s to determine preliminary intraobserver and interobserver variability of measurements in a subset of

156 normal values, and determine the intra- and interobserver variability of measurements.

157 The interobserver variability of MRI and the relative import

158 Knowledge of the interobserver variability of quantitative parameters is

159 idated by comparing its accuracy against the interobserver variability of six trained graders from th

160 orrections that in turn resulted in a higher interobserver variability of SUVmean (CCCs for follow-up

161 These results were compared with the interobserver variability of the same radiologists obtai

162 Our results show substantial interobserver variability, particularly for overall diag

163 SPECT/CT demonstrated both a high intra- and interobserver variability (R(2) = 0.997) and an accuracy

164 Overall intra- and interobserver variability rates were similar; in clinica

165 F-PSMA-1007 showed a significantly increased interobserver variability regarding bone metastases, com

166 F-PSMA-1007 showed a significantly increased interobserver variability regarding overall agreement an

167 ce and positive correlation, but significant interobserver variability remains.

168 e but have poor diagnostic accuracy and wide interobserver variability that limit their reproducibili

169 al studies are required to further establish interobserver variability, to assess intraobserver varia

170 Our study showed minimal interobserver variability using CAM based quantification

171 vity determination, assessment of intra- and interobserver variability, validation of data from qPSMA

172 ment of regional wall motion, and intra- and interobserver variability values are low.

173 e interstudy reproducibility, and intra- and interobserver variability values were analyzed.

174 of myocardial velocity with small intra- and interobserver variability values.

175 High interobserver variability warrants further investigation

176 The mean kappa value for interobserver variability was 0.62 (95% confidence inter

177 Interobserver variability was analyzed by calculating in

178 Interobserver variability was analyzed by using three di

179 Interobserver variability was analyzed by using weighed

180 Interobserver variability was analyzed.

181 Interobserver variability was assessed by placing cases

182 Interobserver variability was assessed by using the Pear

183 Interobserver variability was assessed for the grading o

184 Interobserver variability was assessed in 10 patients.

185 Intra- and interobserver variability was assessed in a subset of 18

186 Interobserver variability was assessed with the Cohen ka

187 Interlot and interobserver variability was assessed.

188 reast Imaging Reporting and Data System, and interobserver variability was calculated with the Cohen

189 Descriptive statistics were used and interobserver variability was calculated.

190 Interobserver variability was calculated.

191 The interobserver variability was compared to the variabilit

192 Interobserver variability was determined (kappa analysis

193 d for assessment by the senior observer, and interobserver variability was determined.

194 Interobserver variability was evaluated using a sample o

195 by expert readers (r = 0.96; p < 0.001), but interobserver variability was greater (3.4 +/- 2.9% vs.

196 Interobserver variability was high for CT colonography w

197 EF than for manual EF or manual LS, whereas interobserver variability was higher for both visual and

198 Significant interobserver variability was identified during these as

199 Interobserver variability was negligible.

200 Interobserver variability was not explained by positive

201 Interobserver variability was not statistically signific

202 Significant interobserver variability was observed (P < .001).

203 Interobserver variability was only fair (kappa = 0.54) f

204 Interobserver variability was reported using multirater

205 Intraobserver and interobserver variability was small, with intraclass cor

206 Intra- and interobserver variability was tested by using intraclass

207 sum test and two-sample Student t test, and interobserver variability was tested with kappa coeffici

208 Interobserver variability was tested with the kappa coef

209 ct patient outcomes and overcome substantial interobserver variability, we developed an unsupervised

210 Intraobserver and interobserver variabilities were determined.

211 Intraobserver and interobserver variabilities were excellent (4+/-4% and 4

212 Intraobserver and interobserver variabilities were similar.

213 an square percent error (accuracy), bias and interobserver variability were 0.992, 11.9 g, 4.8%, -4.9

214 Intra- and interobserver variability were analyzed in image categor

215 Accuracy, bias and interobserver variability were calculated.

216 Intermodality and interobserver variability were measured using the intrac

217 Whole-lesion measurement showed the lowest interobserver variability with both measurement methods

218 manual segmentation, with errors similar to interobserver variability with manual segmentation.

219 Interobserver variability yielded excellent agreement fo