ライフサイエンスコーパス: radiograph

1 ory signs and absence of infiltrate on chest radiograph).

2 he modNY criteria (false positive results on radiographs).

3 cementoenamel junction to the root apex, on radiographs).

4 lization of the aortic valve on supine chest radiograph.

5 stent with pulmonary oedema on frontal chest radiograph.

6 smear result, and extent of disease on chest radiograph.

7 ements of number of rib fracture detected on radiograph.

8 %) of the 188 with parenchymal infiltrate on radiograph.

9 ossible) and hip osteoarthritis confirmed by radiograph.

10 echocardiography is equivalent to the chest radiograph.

11 acic echocardiography and confirmed by chest radiograph.

12 ensive than the routine postprocedural chest radiograph.

13 eral dimensions measured on the patient's CT radiograph.

14 mulate the pulmonary anatomy seen on a chest radiograph.

15 dy radiologists independently reviewed chest radiographs.

16 ormalized heights and hand skeletal maturity radiographs.

17 d equivalent to or even better than standard radiographs.

18 e quality and magnification of the panoramic radiographs.

19 ar and molar MBLs were measured on panoramic radiographs.

20 interpretation of isolated adult limb injury radiographs.

21 e imaging, renal ultrasound, and total spine radiographs.

22 te changes in the pin position on plain film radiographs.

23 nd pulmonary contusion or laceration seen on radiographs.

24 ist radiographs and those from cephalometric radiographs.

25 (distance bone-implant [DIB]) by periapical radiographs.

26 sults, normal examinations, and normal chest radiographs.

27 patients (87%) presented with abnormal chest radiographs.

28 f cervical vertebrae utilizing cephalometric radiographs.

29 permanent tooth site on preexisting bitewing radiographs.

30 tal CBL was measured on standardized digital radiographs.

31 ver 48 months with ICDAS and yearly bitewing radiographs.

32 assessed by radiopaque markers and abdominal radiographs.

33 f the wrist on NMR in patients with negative radiographs.

34 s to improved diagnosis of emphysema in lung radiographs.

35 e-Salmon system, which includes conventional radiographs.

36 ng; MR imaging findings were correlated with radiographs.

37 as measured on standard posteroanterior knee radiographs.

38 for detection of small lung cancers on chest radiographs.

39 Ns) for detecting tuberculosis (TB) on chest radiographs.

40 BL) around all teeth was measured on digital radiographs.

41 e were no arterial placements found on chest radiographs.

42 at physical examination or on initial plain radiographs.

43 hich consisted of 1007 posteroanterior chest radiographs.

44 oth MBL and MCI were assessed from panoramic radiographs.

45 Participants were shown 30 chest radiographs, 14 of which had a pneumothorax, and were as

46 ndred posteroanterior (PA) and lateral chest radiographs (189 radiographs with negative findings and

47 ty: 71% vs. 22%, specificity: 90% vs. 94% on radiographs according to New York criteria.

48 Routine chest radiograph after this common procedure is an unnecessary

49 mage]) and erosions of the hands and feet on radiographs, all-cause mortality, and treatment response

50 834 molars were assigned for FI by FP and in radiographs analyzed by an experienced (EE) and less exp

51 A panoramic radiograph and a computed tomography revealed extensive

52 s were obtained at the time of the long limb radiograph and at followup examinations.

53 N1 influenza, is largely restricted to chest radiograph and computed tomography (CT), which can detec

54 of the patients without infiltrate on chest radiograph and excluded CAP in 56 (29.8%) of the 188 wit

55 sessed each patient, determined the need for radiograph and separately recorded their interpretation

56 rwent radiological assessment using standing radiograph and supine CT scan of the whole spine.

57 single consultant radiologist reviewed each radiograph and their interpretation was seen as the gold

58 that were planned and performed according to radiographs and 24% after computed tomography.

59 FI Class III, 57% were detected correctly by radiographs and 32% by FP.

60 Among the 5239 patients, 1174 had early radiographs and 349 had early MRI/CT.

61 rformance was optimized by providing lateral radiographs and BSIs.

62 A total of 14 036 clinical hand radiographs and corresponding reports were obtained from

63 ssociated with improved findings on skeletal radiographs and improved pulmonary and physical function

64 Posteroanterior radiographs and knee magnetic resonance (MR) images were

65 classifications, including the corresponding radiographs and laboratory data, were prospectively revi

66 All subjects with available baseline knee radiographs and magnetic resonance (MR) images were incl

67 , including 61 women and 40 men, referred to radiographs and MR examinations by rheumatologists due t

68 Radiographs and MRI are characterised by low, near to ra

69 The aim of the paper was to compare radiographs and MRI in assessment of active and chronic

70 s and whether there is a correlation between radiographs and MRI in their identification.

71 weighted kappa-coefficient (kappaw) = 0.588; radiographs and OFS had kappaw = 0.542 (OPG kappaw = 0.5

72 In 63 cases of negative radiographs and persistent clinical problem, simplified

73 Pelvic radiographs and proximal femur BMD measurements were obt

74 fractures, such as spine fractures on chest radiographs and sagittal multidetector CT reconstruction

75 ogists have traditionally focused on frontal radiographs and the measurement of scoliosis curves as i

76 th an increased emphasis on standing lateral radiographs and the sagittal position of the spine.

77 en bone age assessments made from hand-wrist radiographs and those from cephalometric radiographs.

78 crestal height (ACH) measures from intraoral radiographs and tooth loss and 2) Centers for Disease Co

79 Applicants underwent a chest radiograph, and any with results suggestive of tuberculo

80 giography, magnetic resonance imaging, chest radiograph, and chest computed tomography) together cont

81 g for carbon monoxide, pulse oximetry, chest radiograph, and high-resolution thoracic computerized to

82 period, unadjusted arterial blood gas, chest radiograph, and RBC utilization in the intervention peri

83 centives targeting arterial blood gas, chest radiograph, and RBC utilization.

84 All patients had scoliosis on standing radiographs, and 12 had scoliosis persisting in the supi

85 8 fewer arterial blood gases, 73 fewer chest radiographs, and 16 fewer RBCs per 100 patients (p < 0.0

86 employed an oral HL (OHL) survey, full-mouth radiographs, and clinical examination.

87 Standard clinical measurements, radiographs, and intraoral photographs were taken over p

88 Detection Assessment System (ICDAS), yearly radiographs, and QLF.

89 Arterial blood gas testing, chest radiographs, and RBC transfusions provide an important e

90 se the avoidable arterial blood gases, chest radiographs, and RBC utilization on utilization of these

91 er of orders for arterial blood gases, chest radiographs, and RBCs per patient.

92 n; multiple infiltrates or cavities on chest radiograph; and comatose state, intubation, receipt of p

93 lysis of cervical vertebrae in cephalometric radiographs appears to be the most desirable method of b

94 Chest radiograph approximated accurate catheter tip position i

95 , 3.02; 95% CI, 2.60-3.52), and normal chest radiograph (aPR, 1.88; 95% CI, 1.63-2.16) and was invers

96 Routine postprocedure chest radiographs are considered standard practice.

97 Radiographs are frequently unremarkable, but may reveal

98 Radiographs are routinely performed, because even when n

99 While radiographs are the basis of any imaging of the hip, MR

100 arately recorded their interpretation of the radiograph as either definite fracture, no fracture or p

101 order to fulfill the objectives, hand-wrist radiographs as well as cephalometric radiographs of 30 p

102 of 19-27 kg/m(2), and no knee pain or OA on radiographs at baseline.

103 onger among knees that had completely normal radiographs before incidence (K/L grade of 0) (odds rati

104 accuracy in interpreting isolated adult limb radiographs between emergency nurse practitioners and em

105 d at 6 months was calculated on standardized radiographs by using image analysis software.

106 and 6 months was calculated on standardized radiographs by using image-analysis software.

107 and 6 months was calculated on standardized radiographs by using the image analysis software.

108 Use of BS imaging together with a standard radiograph can improve radiologists' accuracy for detect

109 included 79 185 matched A and B Reader chest radiograph classifications.

110 king into account a distortion rate for each radiograph compared with original implant measurements.

111 ture positive), probable tuberculosis (chest radiograph consistent), possible tuberculosis (chest rad

112 an time between catheter insertion and chest radiograph control (28.3 min) was clearly longer than ag

113 Similarly, patient care items ("chest radiograph correctly interpreted"; "time to start of com

114 (PVR) obtained in routine follow-up digital radiographs could be used for such assessment.

115 atient was examined with ultrasound, sternal radiographs, CT and MRI.

116 microbiologically confirmed cases and chest radiograph (CXR)-positive cases compared to controls.

117 Chest radiographs (CXRs) are a valuable diagnostic tool in epi

118 Chest radiographs (CXRs) are frequently used to assess pneumon

119 Chest radiographs (CXRs) were graded from 0 to 6 (0, no radiog

120 er a transient ischemic attack, when a chest radiograph demonstrated a right lung mass.

121 Lateral chest radiograph demonstrated lytic destruction of the xiphist

122 Annual screening with chest radiograph did not reduce lung cancer mortality compared

123 Radiographs do not allow early inflammatory lesions indi

124 Textural analysis of pelvic radiographs enables discrimination of patients at risk f

125 e for the detection of lung nodules on chest radiographs, even when baseline performance was optimize

126 cal disability, destructive changes on joint radiographs, extra-articular manifestations, and cortico

127 Teamwork behavior items (e.g., "chest radiograph findings communicated to team" and "team memb

128 ulin skin test, syphilis serology, and chest radiograph) followed by more complex investigations acco

129 lly relevant complications detected on chest radiographs following ultrasound-guided right internal j

130 lly relevant complications detected on chest radiographs following ultrasound-guided right internal j

131 ve, expeditious alternative to routine chest radiograph for position controls of central venous cathe

132 h, 2) clinical attachment level, and 3) oral radiographs for alveolar crestal height in a study ancil

133 -dose CT assessments with three annual chest radiographs for the early detection of lung cancer in hi

134 the distal fibula are rare in children with radiograph fracture-negative lateral ankle injuries.

135 measured the mechanical axis from long limb radiographs from the Multicenter Osteoarthritis Study (M

136 ent with necrotising enterocolitis and whose radiographs fulfilled criteria for Bell's stage 2 or 3 n

137 At 12 months, neither the early radiograph group nor the early MRI/CT group differed sig

138 itative indices calculated on oral panoramic radiographs have been proposed as useful tools to screen

139 oid cancer risk for every 10 reported dental radiographs (hazard ratio = 1.13, 95% confidence interva

140 A chest radiograph helps localise the site and possible contents

141 hy could be reserved for those with abnormal radiographs, high-risk mechanisms, or abnormal physical

142 noramic radiographs (OPGs) and 77 intra-oral radiographs (I-Os) were evaluated.

143 lly evaluated by measuring the Cobb angle in radiograph images taken while the patient is standing.

144 aortic valve location on plain supine chest radiograph images, which can be used to evaluate intraca

145 ne the aortic valve location on supine chest radiograph images.

146 ion of catheter was then controlled by chest radiograph in all cases.

147 A plain radiograph in frog leg position showed a widening of the

148 ociated with alveolar consolidation on chest radiograph in nonconfirmed cases, and with high (>6.9 lo

149 ld be easily monitored on plain supine chest radiograph in the ICU.

150 nced high-tech imaging, the utility of plain radiographs in conditions of the bone is increasingly be

151 ted tomography (CBCT) versus periapical (PA) radiographs in detecting PA changes at baseline (T0) and

152 stically the effectiveness of CBCT versus PA radiographs in detecting PA changes.

153 o analyze the correlation of ultrasound with radiographs in imaging of callus formation after fractur

154 role is to appropriately order and interpret radiographs in the emergency department.

155 d using a modified Larsen method for scoring radiographs (in the discovery cohort) or modified Sharp/

156 ph consistent), possible tuberculosis (chest radiograph inconsistent), or not tuberculosis (improved

157 l patients had dyspnoea, congestion on chest radiograph, increased brain natriuretic peptide (BNP) or

158 Experience in analyzing conventional radiographs increases the potential of correct diagnosis

159 Conclusion Chest radiograph interpretation skill increased with experienc

160 pose To investigate the development of chest radiograph interpretation skill through medical training

161 pects such as antibiotic pretreatment, chest radiograph interpretation, utility of induced sputum in

162 comparing efficacy of CBCT versus intraoral radiographs (IRs).

163 Location of an intrathoracic lesion on chest radiograph is facilitated by application of 'silhouette

164 Chest radiograph is key in establishing parenchymal lung invol

165 nother objective was to point out that chest radiograph is not sufficient to depict the evolution of

166 Plain radiograph is the initial modality used to evaluate pati

167 screening for lung cancer with modern chest radiographs is unknown.

168 counts, chemistry panels, bone scans, chest radiographs, liver ultrasounds, pelvic ultrasounds, comp

169 emia (LR range, 2.2-3.3), and abnormal chest radiograph (LR range, 2.5-3.8).

170 ods are used - dental radiographs, panoramic radiographs, magnetic resonance imaging with diffusion-w

171 arly CT scan findings complementary to chest radiograph markedly affect both diagnosis and clinical m

172 Imaging is helpful in most DFIs; plain radiographs may be sufficient, but magnetic resonance im

173 ts obtained by ultrasound were compared with radiograph measurements and with the subjective assessme

174 computed tomography (CT, n = 9,357) or chest radiograph (n = 9,357) screening and monitored for a mea

175 1.27] per cycle threshold [CT]), and a chest radiograph not suggestive of active tuberculosis (aOR, 0

176 previous tuberculosis, high CT, and a chest radiograph not suggestive of active tuberculosis.

177 A chest radiograph obtained at the outside hospital prompted tra

178 A chest radiograph obtained at the time of physical examination

179 for evaluation of findings on thoracic spine radiographs obtained at a peripheral hospital.

180 Pelvis radiographs obtained at year 2 were analyzed for variati

181 igitalized standardized intraoral periapical radiographs obtained from natural teeth and dental impla

182 The periapical radiographs, obtained in a standardized manner, revealed

183 A standing radiograph of the knee was taken for Kellgren-Lawrence (

184 A frontal radiograph of the pelvis taken six months before showed

185 r distance was measured on the mammogram and radiograph of the specimen, and reflector depth was meas

186 Lateral cephalometric radiographs of 269 untreated adults with skeletal classe

187 d-wrist radiographs as well as cephalometric radiographs of 30 patients (15 girls and 15 boys) betwee

188 Radiographs of alginate hydrogel with PRP-treated bone d

189 Radiographs of both knees were read for Kellgren/Lawrenc

190 in 450 adults using standardized periapical radiographs of maxillary central incisors.

191 Supine anterior-posterior chest radiographs of patients with an aortic valve prosthesis

192 Frontal and lateral radiographs of the chest were obtained and indicated inc

193 We selected women for whom bilateral radiographs of the knees (with the legs in full extensio

194 Five of 110 radiographs of the specimen (4.5%; 95% CI: 1.7%, 10.4%)

195 Radiographs of the specimen and pathologic analysis help

196 L) were identified, and high-detail computed radiographs of the wrists and knees were obtained.

197 The PVR from radiographs of thirty children with ceramic bone substit

198 Plain radiographs often play a pivotal role in diagnosing meta

199 ctive tuberculosis (most with abnormal chest radiographs, only 18% symptomatic).

200 For the investigation, 143 panoramic radiographs (OPGs) and 77 intra-oral radiographs (I-Os)

201 inical practice-eg, 50 (73%) ordered a chest radiograph or sputum test during the vignette compared w

202 crobial use (P = 0.032), and number of chest radiographs (P = 0.005), when controlling for potential

203 in detecting PA radiolucencies compared with radiographs (P = 0.0069).

204 following imaging methods are used - dental radiographs, panoramic radiographs, magnetic resonance i

205 ation (ie, tuberculin skin test and/or chest radiograph) per prevalent case diagnosed; number of cont

206 Of 451 patients with chest radiographs performed, 195 (43%) had pneumonia (spring,

207 One such surgery is described in detail with radiographs, photographs, and a videoclip.

208 ly with extent of lung infiltration on chest radiographs (r = 0.483; p < 0.05).

209 modeling was performed to integrate multiple radiograph records per patient over time.

210 atoid Arthritis Study (421 patients and 3758 radiographs; recruitment: 1986-1999; 2005 as final follo

211 ritis Register (NOAR; 1691 patients and 2811 radiographs; recruitment: 1989-2008; 2008 as final follo

212 come a standard of care, postinsertion chest radiograph remains the gold standard to confirm central

213 Conventional radiographs represented 92% of examinations, whereas car

214 thicknesses were extracted directly from the radiographs, representing a greatly enhanced scope of da

215 90.4% were deemed healthy using CBCT and PA radiographs, respectively, at T12.

216 ed radiolucency were 30.8%/9.6% with CBCT/PA radiographs, respectively.

217 In relation to MRI, radiographs resulted in 40% of incorrect sacroiliitis di

218 Chest radiograph revealed a parenchymal infiltrate in 188 pati

219 near-normal MRI of the spine, in whom plain radiographs revealed subtle findings and aided in making

220 Chest radiograph ruled out pneumothorax in 137 of 137 patients

221 ll foci suspicious of lytic lesions on skull radiographs, seen as arachnoid granulations fovea in CT.

222 lities in 13 of 75 patients (17%), and spine radiographs showed anomalies in 10 of 77 patients (13%).

223 Chest radiographs showed mild pulmonary edema with a small rig

224 Chest radiographs showed pulmonary infiltrates in all patients

225 re coregistered with digitally reconstructed radiographs so that the patient position could be adjust

226 ortion of implant, and subsequent periapical radiographs taken demonstrated a radiolucent lesion.

227 Demographics, panoramic radiographs (taken at the beginning of dental treatment)

228 iagnosis relies on oxygenation and the chest radiograph that might be directly influenced by the prop

229 Standard standing pelvic radiographs that included the transverse processes of L5

230 ted tomographic (CT) images and conventional radiographs that were electronically flagged by reviewin

231 On radiographs (the standard of reference), 27 patients had

232 the senior radiologist (V.M.C.) reviewed the radiographs, the patient was called back for assessment

233 following characteristics are evaluated on a radiograph: the appearance, size and shape of ossificati

234 Based on marginal bone loss, measured on radiographs, three different groups were identified: par

235 utomatic custom algorithm was applied to the radiographs to calculate the texture parameters along th

236 nce just after loading by digital periapical radiographs to determine the marginal bone loss (BL).

237 We obtained posteroanterior chest radiographs to identify the prevalence of pleural abnorm

238 les that were missed after evaluation of the radiographs together with BSIs pooled over all observers

239 nd between bone age assessed from hand-wrist radiographs using Bjork's method and bone age assessed f

240 and 12 months was calculated on standardized radiographs using image analysis software.

241 and 6 months was calculated on standardized radiographs using image analysis software.

242 Dental age was assessed from panoramic radiographs using the Demirjian's method.

243 hod and bone age assessed from cephalometric radiographs using the method by Baccetti et al.

244 parameters, including clinical observations, radiographs, viral load in blood, throat swabs, and sele

245 amination, likely imported if preimmigration radiograph was abnormal and TB was reported less than or

246 l, and likely reactivation of inactive TB if radiograph was abnormal but TB was reported more than 6

247 An infiltrate on chest radiograph was considered the reference standard for the

248 Chest radiograph was suggestive of a posterior mediastinal les

249 The interrater reliability for radiographs was dependent on the experience of the exami

250 Bone age on hand-wrist radiographs was evaluated using the Bjork method, wherea

251 al shape modeling (SSM) of the digitized hip radiographs was performed to assess the shape of the pro

252 n a calibrated value based on 100 reassessed radiographs was used.

253 rcentage IBD depth reduction, assessed using radiographs, was evaluated at baseline and postoperative

254 To quantify the convective fluxes from the radiographs, we introduced a convection-diffusion model

255 sing the Bjork method, whereas cephalometric radiographs were analyzed by the Baccetti et al. method.

256 e matrix were included, and 1,536 periapical radiographs were analyzed.

257 -up, and their previous clinical records and radiographs were assessed.

258 ratan sulfate (KS) and baseline and followup radiographs were available for 353 knees without baselin

259 inal (baseline, 12-month, and 24-month) knee radiographs were available for 60 female subjects with k

260 Migrants whose chest radiographs were compatible with active tuberculosis but

261 Periapical radiographs were evaluated before surgery, post-surgery,

262 Periapical radiographs were evaluated immediately after implant pla

263 ized procedure notes and postprocedure chest radiographs were extracted and individually reviewed to

264 Chest radiographs were independently assessed by two observers

265 Chest radiographs were interpreted according to the Internatio

266 to assess the maturity of bones, hand-wrist radiographs were introduced in the second decade of the

267 Lateral thoracolumbar spine radiographs were obtained at baseline and 12 months.

268 Radiographs were obtained for 461 participants.

269 Panoramic radiographs were obtained from 129 CKD patients (78 male

270 Posteroanterior and lateral chest radiographs were obtained in the emergency department.

271 For calcifications, specimen radiographs were obtained, and for masses or architectur

272 l attachment level [CAL-V]) and standardized radiographs were obtained.

273 At this time, chest radiographs were obtained.

274 Independent reviews of chest radiographs were performed by radiologists.

275 Clinical parameters and periapical radiographs were registered on the day of implant placem

276 Chest radiographs were reviewed independently by study radiolo

277 Radiographs were scored by three readers with use of the

278 Radiographs were scored for OA in a blinded manner, usin

279 CBCT/PA radiographs were taken at T0 and T12.

280 h were also evaluated for pulp vitality, and radiographs were taken at the dentist's discretion.

281 ng on probing) were measured, and periapical radiographs were taken at the time of implant placement

282 Periapical radiographs were taken using the long-cone technique bef

283 Bitewing radiographs were taken yearly.

284 Panoramic radiographs were taken; patients were categorized into l

285 Radiation charts and simulation radiographs were used to estimate in-field heart volume

286 h (PD), clinical attachment level (CAL), and radiographs, were used to classify patients into healthy

287 and lung ultrasound is noninferior to chest radiograph when used to accurately assess central venous

288 ensity posterior mediastinal lesion on chest radiograph with destruction of the vertebral body and pr

289 Screening Trial (NLST), which compared chest radiograph with spiral computed tomographic (CT) screeni

290 which included all conventional screen-film radiographs with a classification by at least one A Read

291 loss (ABL), measured on intraoral periapical radiographs with a modified Schei ruler method.

292 9 radiographs with negative findings and 111 radiographs with a solitary nodule) in 300 subjects were

293 25 mm of reproducible sensor displacement on radiographs with as little as 100 N of axial compressive

294 diologists and three residents evaluated the radiographs with BSIs available, first, without CAD and,

295 sion A Readers classified substantially more radiographs with evidence of pneumoconiosis and classifi

296 rior (PA) and lateral chest radiographs (189 radiographs with negative findings and 111 radiographs w

297 ning bone age assessment model based on hand radiographs with that of expert radiologists and that of

298 illness such as cough and an abnormal chest radiograph without antecedent tuberculosis or pneumonia.

299 bjects were enrolled, sampled, examined, and radiographed yearly for 3 years.

300 The periapical radiographs yielded stable peri-implant bone levels, wit

301 rial, which compared CT screening with chest radiograph, yielded a mortality advantage of 20% to part