ライフサイエンスコーパス: radiographic

1 honor of the most recent emeritus editor of RadioGraphics.

2 of tuberculosis compared with those with no radiographic abnormalities (incidence rate ratio 3.2, 95

3 Radiographic abnormalities include undermineralization o

4 wer respiratory tract sample with or without radiographic abnormality (defined as proven or probable

5 positive upper respiratory tract sample with radiographic abnormality (possible LRTI).

6 Greater radiographic alveolar bone loss was observed among parti

7 patients were more likely to be female, have radiographic alveolar or interstitial changes, and histo

8 re obtained for histologic, biochemical, and radiographic analysis.

9 Sixty-two radiographic and 14 CT orders were cancelled.

10 Radiographic and clinical analyses were carried out incl

11 Radiographic and clinical data were recorded, and a trea

12 In a radiographic and clinical evaluation, four relevant dist

13 Long-term radiographic and clinical follow-up was obtained for 36

14 clinical trials include using physiological, radiographic, and biological criteria to select patients

15 We compared the epidemiologic, radiographic, and clinical characteristics of S. aureus

16 ultifaceted approach that includes clinical, radiographic, and laboratory evidence of disease.

17 al, or malarial infection based on clinical, radiographic, and laboratory results.

18 tandard frequent intervals with symptomatic, radiographic, and microbiologic data collected, includin

19 Results from micro-computed tomographic, radiographic, and optical microscopic analyses showed de

20 ty pneumonitis risk, survival, and clinical, radiographic, and pathological features.

21 the exomes of individuals with SMD with the radiographic appearance of "corner fractures" at metaphy

22 Radiographic (as per Prostate Cancer Working Group 2 Cri

23 The reliability of FP compared with radiographic assessment depends on the anatomy and locat

24 study is to evaluate the validity of FP and radiographic assessment of FI compared with visual asses

25 , osteophytes and meniscal extrusion, and of radiographic assessment of joint space narrowing and ost

26 Many observational studies included proper radiographic assessment of pneumonia, but they are limit

27 Clinical and radiographic assessments performed at baseline and after

28 he aim of the present study is to assess the radiographic bone changes around customized, platform-sw

29 These soft tissue responses do not determine radiographic bone changes.

30 healing, rhBMP-2-treated sites showed better radiographic bone density, greater defect fill, and sign

31 l gain, bleeding on probing (BOP) reduction, radiographic bone fill (RBF), and mucosal recession.

32 Primary outcome measures included: 1) radiographic bone fill as measured from the cemento-enam

33 esult in better PD reduction, CAL-V gain, or radiographic bone fill compared with PLAC 12 and 24 mont

34 ical bone fill of 1.35 +/- 1.60 mm, and mean radiographic bone fill of 1.10 +/- 1.01 mm.

35 ical bone fill of 1.53 +/- 1.64 mm, and mean radiographic bone fill of 1.14 +/- 0.88 mm.

36 Mean radiographic bone fill was 1.06 +/- 0.81 and 1.0 +/- 0.9

37 D), Clinical Attachment Level (CAL) gain and radiographic bone gain were assessed.

38 ally significant PPD reduction, CAL gain and radiographic bone gain.

39 ent, decreased pocket probing depth, gain in radiographic bone height, and overall improvement in per

40 periodontal disease history; 4) peri-implant radiographic bone level from most recent examination; an

41 Periodontal examination was performed and radiographic bone level measured.

42 Radiographic bone loss (BL) was examined using orthopant

43 large case-control study of PD, verified by radiographic bone loss and with a careful consideration

44 Peri-implantitis was defined as radiographic bone loss of > 2 mm, probing depth (PD) >/=

45 Peri-implantitis was defined as radiographic bone loss of >2 mm, probing pocket depth (P

46 0 years of follow-up) observed a decrease in radiographic bone loss of approximately 30% among quitte

47 involved in the production of Radiology and RadioGraphics by working closely with the editors, assoc

48 n with suspected pneumonia but without chest radiographic changes or clinical or laboratory findings

49 or partial response based on symptomatic and radiographic changes, was greater in the aggressive drai

50 med on the basis of localization and type of radiographic changes.

51 o use these findings to develop an objective radiographic classification for predicting IT.

52 ssess the level of concordance between chest radiographic classifications of A and B Readers in a nat

53 Subjective radiographic classifications of alveolar bone have been

54 ice classification system to ensure accurate radiographic classifications.

55 imary end point was freedom from clinical or radiographic CNS infarction at 7 days (+/- 3 days) after

56 Routine radiographic control on post-intervention day one was wi

57 ients with tumors who met centrally reviewed radiographic criteria registered.

58 have ventilator-associated pneumonia because radiographic criteria were not met.

59 surgeons evaluated BCT candidacy by clinico-radiographic criteria; surgery performed was at surgeon

60 No radiographic criterion of SCPN (including number, size,

61 Radiographic damage was limited for all strategies, with

62 tional deterioration and clinically relevant radiographic damage, and normalized survival are realist

63 Clinical and standardized radiographic data were collected at baseline and 6 month

64 , PRF + 1.2% ATV showed a similar percentage radiographic defect depth reduction (50.96% +/- 4.88%) c

65 showed a significantly greater percentage of radiographic defect depth reduction (52.65% +/- 0.031%)

66 d with a significantly greater percentage of radiographic defect depth reduction at 6 and 9 months.

67 clinical parameters, with greater percentage radiographic defect depth reduction compared to MF, PRF,

68 linical parameters with a greater percentage radiographic defect depth reduction compared with PRF al

69 Percentage radiographic defect depth reduction was evaluated using

70 showed a significantly greater percentage of radiographic defect fill (56.01% +/- 2.64%) when compare

71 mel discoloration/cavitation but no clinical/radiographic dentin involvement, 12% (95% CI, 6%-22%) of

72 ositivity for MAC (MAC-PP) and its impact on radiographic deterioration in MAC-LD.

73 No evidence of clinical or radiographic disease activity was observed in 62% of SID

74 f tuberculosis correlates with the extent of radiographic disease and is diminished upon effective tr

75 was more abundant and better correlated with radiographic disease burden.

76 n combined with cyclophosphamide resulted in radiographic disease control in 8 of the 10 patients.

77 orth America) and the presence or absence of radiographic disease progression at baseline.

78 es initiating a new treatment after clinical/radiographic disease progression, ultimately resulting i

79 Knees were matched according to radiographic disease stage and patient sex and age.

80 r respiratory tract infection (LRTI) without radiographic documentation.

81 esent study aims to explore the clinical and radiographic effectiveness of autologous PRF versus PRF

82 s 28 data sets was consistent with published radiographic estimates of ePVS; mean width of clusters s

83 Lateral ankle injuries without radiographic evidence of a fracture are a common pediatr

84 graphs (CXRs) were graded from 0 to 6 (0, no radiographic evidence of disease; 5, bilateral cavitatio

85 In patients with radiographic evidence of metastases and minimal symptoms

86 teoarthritis Index score of at least 39, and radiographic evidence of OA of the knee were recruited f

87 ep showed clinical signs of OA, and they had radiographic evidence of only mild or, in one case, mode

88 Among 2320 adults with radiographic evidence of pneumonia (93%), the median age

89 ty in IS specimens was associated with chest radiographic evidence of pneumonia (radiographic pneumon

90 Among 2259 patients who had radiographic evidence of pneumonia and specimens availab

91 Among 2222 children with radiographic evidence of pneumonia and with specimens av

92 gible children (69%), 2358 of whom (89%) had radiographic evidence of pneumonia.

93 ed by opioid use for cancer-related pain and radiographic evidence of progression.

94 All subjects had radiographic evidence of unusually protruding cervical r

95 irst-line docetaxel treatment established by radiographic evidence, and previous treatment with abira

96 ns obtained within 1 year of the index chest radiographic examination and that met inclusion criteria

97 e an abnormal finding on an outpatient chest radiographic examination has a high yield of clinically

98 graphic records were preserved, we undertook radiographic examination of the skeletons of Dolly and h

99 tion was obtained within 1 year of the index radiographic examination that contained the recommendati

100 s evident because individuals had to undergo radiographic examination to be included in the analysis.

101 upper gastrointestinal tract barium-contrast radiographic examination was performed at 1 year to asse

102 T with TCM was performed after one localizer radiographic examination with anteroposterior (AP) or po

103 s reporting M3 impaction prevalence based on radiographic examination.

104 nation within the year after the index chest radiographic examination.

105 e 70 patients (27%) who completed the 1-year radiographic examination.

106 teria, after physical, microbiologic, and/or radiographic examination.

107 Clinical and radiographic examinations are essential in establishing

108 was assessed based on clinical and intraoral radiographic examinations at the recalls after 6, 12, 24

109 tients (78%) underwent imaging in the ED; 57 radiographic examinations in 30 patients and 16 computed

110 Patients were subjected to plain radiographic examinations of abdomen which revealed larg

111 The conventional ultrasonographic and radiographic examinations of the abdomen are insufficien

112 Reports of all outpatient chest radiographic examinations performed at a large academic

113 erval {CI}: 4.3%, 4.8%]) of outpatient chest radiographic examinations that contained a recommendatio

114 Clinical and radiographic examinations were performed to assess ridge

115 Current radiographic examinations, however, do not provide adequ

116 ent needs is primarily based on clinical and radiographic examinations.

117 This article reviews the prenatal radiographic features and postnatal clinical findings of

118 ohort, we saw associations between extent of radiographic fibrosis and MUC5B rs35705950 minor alleles

119 e matter hyperintensities (WMH) are a common radiographic finding and may be a useful endophenotype f

120 n abnormality that corresponded to the chest radiographic finding that prompted the recommendation.

121 277 [78.7%]) had IA diagnosis established by radiographic findings and maximum galactomannan positivi

122 in 1st-, 2nd-, 3rd-, 4th-, 6th-, or 8th-year radiographic findings compared with baseline).

123 Radiographic findings from cone beam computed tomography

124 Characteristic radiographic findings include bilateral regions of subco

125 lusive features on MRI, but subtle important radiographic findings led to a specific diagnosis.

126 ctors for osteoarthritis or mild to moderate radiographic findings of osteoarthritis, categorized int

127 s possible to predict IT accurately based on radiographic findings of the patient.

128 Familiarity with subtle radiographic findings of these conditions may lead to ea

129 hic factors, comorbidities, and preoperative radiographic findings were analyzed as possible indicato

130 Serum levels of sIL-2R and ACE and chest radiographic findings were assessed.

131 ion of PCP occurring based on characteristic radiographic findings with elevated lactate dehydrogenas

132 hocardiography enabled confirmation of these radiographic findings, and pericardiocentesis was perfor

133 s, and patients presented for a clinical and radiographic follow-up examination.

134 e procedure, an acrylic stent and millimeter radiographic grid were used.

135 ia was significantly associated with lack of radiographic growth ( P < 0.001).

136 een serum lipid profile and the incidence of radiographic hand osteoarthritis (RHOA).

137 Percentage radiographic IBD depth reduction was evaluated at baseli

138 Percentage radiographic IBD depth reduction was evaluated using com

139 Material/Radiographic images were acquired using either computed

140 Clinical and operative records and radiographic images were reviewed.

141 nically relevant information extraction from radiographic images, intracranial pressure processing, l

142 esting as optional and discourage the use of radiographic imaging for routine surveillance.

143 Radiographic imaging indicated that cachectic NHP lost a

144 sent; and diagnosis of cIAI with sonogram or radiographic imaging or visual confirmation.

145 xtreme use as > 12 STM and/or more than four radiographic imaging tests in a 12-month period.

146 ed in vivo anticancer therapy in addition to radiographic imaging via the dual decay modes of (177)Lu

147 A blinded review of radiographic imaging was performed, and intracranial hem

148 toring tests (serum tumor markers [STMs] and radiographic imaging) among women with MBC.

149 With the widespread use and advances in radiographic imaging, Intraductal Papillary Mucinous Neo

150 sults can be used to predict symptomatic and radiographic improvement as well as long-term sputum cul

151 RSV results in significantly greater clinico-radiographic improvement than 1.2% ATV or placebo gels a

152 wever, the rates of symptomatic improvement, radiographic improvement, and sputum culture conversion

153 s improvement in cough, and especially early radiographic improvement.

154 Clinical and radiographic information was retrospectively reviewed an

155 performance and comorbidity profiles, and no radiographic interface between primary tumor and mesente

156 tion of the condyle coupled with appropriate radiographic interpretation would thus be critical for t

157 ecommendations compared with two-dimensional radiographic interpretation?

158 Purpose To investigate the risk of radiographic joint space narrowing (JSN) progression eva

159 ependently associated with increased risk of radiographic JSN progression and KR in patients with a r

160 Radiographic JSN progression was evaluated by using Oste

161 ere was a higher risk of KR in subjects with radiographic KL grade of less than 2 (adjusted HR, 6.97

162 rker proteins could support the diagnosis of radiographic knee OA.

163 uld serve as indicators for the diagnosis of radiographic knee OA.

164 rs) in the Osteoarthritis Initiative without radiographic knee osteoarthritis (OA) and without medial

165 To determine the impact of early radiographic knee osteoarthritis (ROA) and ROA risk fact

166 ammation and produced modest improvements in radiographic lung disease in subjects with G551D-CFTR mu

167 Clinical, radiographic (magnetic resonance imaging), electrophysio

168 ents (83%) had complete clinical healing and radiographic markers of response.

169 y thicker peri-implant soft tissue have less radiographic MBL in the short term.

170 Specifically, radiographic measurements of grafted bone height at the

171 Standardized clinical and radiographic measurements of soft and hard tissues were

172 factor-alpha inhibitors (TNFi) and NSAIDs on radiographic measures of spinal damage.

173 nts of interest included different clinical, radiographic, microbiologic, histologic, and patient-rep

174 ization of all bone tissue parameters, using radiographic, microcomputed tomography, biochemical, and

175 By assessing radiographic mineralization and histological osteoid pro

176 rs of MAC-PP were low body mass index (BMI), radiographic nodular-bronchiectatic (NB) pattern, and in

177 In patients with radiographic nodules less than 3 cm, the negative predic

178 ure of DAS28 of less than 3.2 at week 78 and radiographic non-progression from baseline to week 78, c

179 rom 15 trials found that stimulation reduced radiographic nonunion rates by 35% (95% CI 19% to 47%; n

180 ere pain relief, functional improvement, and radiographic nonunion.

181 g have less pain and are at reduced risk for radiographic nonunion; functional outcome data are limit

182 ere identified if at least one knee had both radiographic OA and pain.

183 We report a prevalence and distribution of radiographic-OA similar to that observed in naturally co

184 There were no radiographic or pathologic features of rickets in the co

185 rate and synovial fluid crystal analysis and radiographic or ultrasonography changes); clinical decis

186 onary angiography and extensive clinical and radiographic oral examination.

187 Clinical and radiographic oral health examination was made at Helsink

188 lage defects at 3.0-T MR imaging and without radiographic osteoarthritis (Kellgren-Lawrence score, 0-

189 mass index, physical activity, symptoms, and radiographic osteoarthritis features (Kellgren and Lawre

190 0.005; adjusted for covariates) but not with radiographic osteoarthritis.

191 ndependent replication cohort for studies of radiographic outcome.

192 (P <0.05), with a difference in clinical and radiographic parameters at 6 and 12 months.

193 in significant improvements of clinical and radiographic parameters compared with OFD alone.

194 one, was effective in improving clinical and radiographic parameters of patients with CP at the 6-mon

195 Radiographic parameters showed significant improvement o

196 Clinical and radiographic parameters were assessed at baseline and 12

197 Clinical and radiographic parameters were assessed at site level and

198 each annual follow-up session, clinical and radiographic parameters were assessed, including the fol

199 seline, 6 mo, and 1 y clinical, esthetic and radiographic parameters were assessed.

200 Clinical and radiographic parameters were evaluated at baseline, 6, a

201 All clinical and radiographic parameters were recorded again after 3 mont

202 Clinical and radiographic parameters were recorded at baseline and af

203 Clinical and radiographic parameters, including plaque index (PI), mo

204 from individuals that underwent clinical and radiographic peri-implant examinations as part of a univ

205 present study is to compare the clinical and radiographic periodontal status between habitual WPs and

206 A reproducible quantitative definition of radiographic PFS (rPFS) was tested for association with

207 The primary end point was radiographic PFS (rPFS; time from random assignment to r

208 antigen response (81% v 31%; P < .001); and radiographic PFS in metastatic patients (HR, 0.32; 95% C

209 e pneumonia, we identified 1935 (45.7%) with radiographic pneumonia and 573 (13.5%) with nonpneumonia

210 d density in IS specimens from children with radiographic pneumonia and children with suspected pneum

211 more frequently in the IS specimens from the radiographic pneumonia compared with the nonpneumonia ca

212 quantity in the IS specimens from cases with radiographic pneumonia compared with the nonpneumonia ca

213 The prevalence of radiographic pneumonia in North American studies was 19%

214 th chest radiographic evidence of pneumonia (radiographic pneumonia), we compared prevalence and dens

215 confers protection against MERS-CoV-induced radiographic pneumonia, as assessed using computerized t

216 and culture results were not associated with radiographic pneumonia, regardless of prior antibiotic u

217 ted meningitis or pneumonia, and evidence of radiographic pneumonia.

218 nation findings in identifying children with radiographic pneumonia.

219 ls per low-power field, and 1162 (44.6%) had radiographic pneumonia.

220 The presence of pulmonary copathogens, radiographic presentation, or pulmonary hemorrhage did n

221 Radiocontrast agents are required for radiographic procedures, but these agents can injure tis

222 p; these patients had a higher proportion of radiographic progression (54%) than patients in the nega

223 th Assessment Questionnaire [HAQ] score) and radiographic progression (Sharp-van der Heijde score) we

224 ntinued as a result of rapid symptomatic and radiographic progression at 8 weeks.

225 receding knee trauma was not associated with radiographic progression of JSN (adjusted HR, 0.91 [95%

226 of preceding knee trauma was associated with radiographic progression of JSN (adjusted HR, 1.27 [95%

227 development of new lesions, confirmation of radiographic progression on follow-up imaging is recomme

228 median time to biochemical, symptomatic, or radiographic progression was 20.2 months in the combinat

229 lution of resistance with treatment failure (radiographic progression) occurs at a median of 16.5 mo

230 ome of late treatment failure defined as [1] radiographic progression, [2] persistence of severe resp

231 Acute stroke or hemorrhage, or delayed radiographic progression, are indications for endovascul

232 The outcome was radiographic progression, namely, increased number of in

233 At the time of radiographic progression, there was optional crossover f

234 free survival (PSA PFS), and clinical and/or radiographic progression-free survival (PFS).

235 eview committee was the secondary end point; radiographic progression-free survival (rPFS) and effect

236 igen (PSA) response, time receiving therapy, radiographic progression-free survival (rPFS), and overa

237 Key secondary end points (radiographic progression-free survival [rPFS], >/= 50% d

238 Coprimary endpoints were radiographic progression-free survival and overall survi

239 The two primary endpoints were radiographic progression-free survival and overall survi

240 The rate of radiographic progression-free survival at 12 months was

241 etate plus prednisone significantly improved radiographic progression-free survival compared with pla

242 significantly increased overall survival and radiographic progression-free survival compared with pla

243 Median radiographic progression-free survival was 13.8 months (

244 nt was 38% (25 of 65), while median clinical/radiographic progression-free survival was 3.5 (95% CI,

245 Median follow-up for radiographic progression-free survival was 8.4 months (I

246 static castration-resistant prostate cancer, radiographic progression-free survival was prolonged wit

247 (PSA progression-free survival), clinical or radiographic progression-free survival, and overall surv

248 d no anti-MAC treatment were correlated with radiographic progression.

249 t uncommon and leads to an increased risk of radiographic progression.

250 studies have suggested that TNFi may reduce radiographic progression.

251 As none of the original clinical or radiographic records were preserved, we undertook radiog

252 ion pseudonormalization and tissue with true radiographic recovery.

253 b, demonstrated a near-complete clinical and radiographic remission for 5 years.

254 nic anonymized patient portal analysis using radiographic reports and admission and discharge diagnos

255 The use of radiographic response as the primary end point in phase

256 All trials used RECIST or WHO radiographic response criteria and the primary end point

257 and doxorubicin) for 6 or 12 weeks based on radiographic response followed by surgery and further ch

258 to be safe and lead to clinical healing and radiographic response in 10 patients.

259 ed, many studies have demonstrated promising radiographic response rates, delayed tumor progression,

260 re determined to be inactive on the basis of radiographic response rates.

261 The patient achieved a complete radiographic response to immune checkpoint blockade, whi

262 Radiographic response was seen in six (43%) of 14 target

263 All 5 patients had clinical and radiographic responses to PD-1 blockade, and 3 patients

264 Objective radiographic responses were observed in 53% of patients,

265 Routine radiographic restaging generally is not suggested but ca

266 o correlate magnetic resonance imaging (MRI) radiographic results with histopathologic growth pattern

267 width at 5 months (6.0 versus 4.62 mm), and radiographic ridge width at 3 mm from the alveolar crest

268 erences between the 2 experimental groups in radiographic root development ( P > 0.05).

269 Of 14 patients with radiographic sacroiliitis according to modified New York

270 has been exponential growth in the number of radiographic scans performed, resulting in increased awa

271 ng patients for MERS-related symptoms, chest radiographic screening, and employee symptom monitoring,

272 lignancy was not associated with presence of radiographic septations or preoperative cyst fluid analy

273 a more sensitive and possibly more specific radiographic sign vs other common CT findings of invasiv

274 r group, 412 patients (69%) had demonstrated radiographic stability at the 5-year time point.

275 al field loss) who demonstrated clinical and radiographic stability were enrolled.

276 Twelve weeks later, clinical, radiographic, stability, histomorphometric, and microcom

277 rom July 2010 to October 2014, patients with radiographic stage III LAPC were treated with IRE and mo

278 o identify patients with NSCLC with clinical radiographic stage T1-3, N0-3, M0 disease that had EBUS-

279 help to prevent long-term side-effects from radiographic staging procedures.

280 nd phenotypic drug susceptibility tests, and radiographic studies, among other diagnostic tools, are

281 Despite the use of high-resolution radiographic studies, endoscopic evaluation, cyst fluid

282 h the absence of parenchymal lung disease on radiographic studies.

283 sociation recommended the discontinuation of radiographic surveillance after 5 years for patients wit

284 late complications still occurred, mandating radiographic surveillance and open or endovascular inter

285 Patients who initially underwent radiographic surveillance were divided into those with <

286 with daily aspirin, embolic monitoring, and radiographic surveillance.

287 ement was most significantly correlated with radiographic suspicion of pneumonia and less so with res

288 n clinical decision making provided standard radiographic techniques are used.

289 rmediate outcomes (results of laboratory and radiographic tests, such as serum urate and synovial flu

290 Patients with non-AFP-producing tumors had radiographic tumor characteristics similar to those of p

291 Radiographic tumor responses were numerically higher for

292 ify and update the underlying laboratory and radiographic variables that fulfil the criteria for the

293 variates included demographic, clinical, and radiographic variables.

294 the absence of an accepted definition for a radiographic ventral hernia and differentiating pseudore

295 mproved BMD and reduced the incidence of new radiographic vertebral fractures in 1 high-quality trial

296 Denosumab also reduces risk for radiographic vertebral fractures, based on 1 trial.

297 ry, gated outcomes included new and worsened radiographic vertebral fractures, clinical fractures (a

298 The primary outcome was new radiographic vertebral fractures.

299 llowship, in honor of the founding editor of RadioGraphics, with the first Eyler fellow selected in 2

300 ned patients were required to undergo annual radiographic (x-ray) analysis for stent fracture.