ライフサイエンスコーパス: thorax

1 than blood and other tissues of the head and thorax).

2 chest compliance (by elastic binding of the thorax).

3 send projections into the central neuropil (thorax).

4 y information about antennal movement to the thorax.

5 with intact interlobar fissures on CT of the thorax.

6 between tactile sensors on the head and the thorax.

7 ulate wind resistance against their legs and thorax.

8 as autotransplantation of splenic tissue in thorax.

9 ing queens that hunt have a more worker-like thorax.

10 culation into two sites--the abdomen and the thorax.

11 f chemotherapy and close surveillance of the thorax.

12 ulation coupled with aseptic wounding of the thorax.

13 ypomagnesaemia, and one pain in the chest or thorax.

14 y the sensorimotor system of the abdomen and thorax.

15 sion from the proximal limb bud out onto the thorax.

16 ned with low nonspecific accumulation in the thorax.

17 h double segment periodicity in the head and thorax.

18 ative to the adipocyte-free vertebrae of the thorax.

19 gion extending from the anterior neck to the thorax.

20 who interpret cross-sectional images of the thorax.

21 producing a "crab-like" configuration of the thorax.

22 ract, and 1 each from the peritoneum and the thorax.

23 d (DIBH) technique in combined PET/CT of the thorax.

24 elongate, and migrate from the wing into the thorax.

25 domen and pole cells instead of the head and thorax.

26 ed by specialized muscles located within the thorax.

27 ir breath at midexpiration during HCT of the thorax.

28 al compression and expansion in the head and thorax.

29 ce a super-resolution 3D volume of the fetal thorax.

30 ion and improving quantitation of PET in the thorax.

31 nts (44%); no cases of lymphoma involved the thorax.

32 t of this system, the air sacs of the dorsal thorax.

33 including CT scout images (topograms) of the thorax.

34 mensional routine radiographic images of the thorax.

35 collapse of the head and abdomen toward the thorax.

36 images of inhomogeneous regions such as the thorax.

37 orm attenuation characteristics of the human thorax.

38 omewhat lower level induction in abdomen and thorax.

39 3, which was induced approximately 5-fold in thorax.

40 nt to which the phantom represents the human thorax.

41 egions such as the extremities, abdomen, and thorax.

42 volving more severe injuries to the head and thorax.

43 ct images of conductivity changes inside the thorax.

44 laced subcutaneously in the left side of the thorax.

45 mean and SD were less than 5% except in the thorax.

46 ngage each wing from the mechanically linked thorax.

47 ound in the abdomen (56%), pelvis (18%), and thorax (11%).

48 bserved in the head and neck (16/77, 20.7%), thorax (11/77, 14.2%), abdomen (16/77, 20.7%), lower ext

49 heart plus central vasculature (17 +/- 2%), thorax (14 +/- 2%), inferior vena cava (23 +/- 2%) and l

50 Operator equivalent dose at the thorax (77 muSv) was significantly higher with radial th

51 for local staging and computed tomography of thorax, abdomen, and pelvis (CT TAP) to identify distant

52 ntigen (CEA) and computed tomography (CT) of thorax, abdomen, and pelvis as part of protocol-specifie

53 was measured at each clinic visit, and CT of thorax, abdomen, and pelvis was performed at 12 and 24 m

54 blished, and computed tomography (CT) of the thorax, abdomen, and pelvis was requested to depict lymp

55 ial-enhanced computed tomography (CT) of the thorax, abdomen, and pelvis was requested to enable excl

56 330 consecutive patient studies of the neck, thorax, abdomen, and pelvis.

57 erity by Abbreviated Injury Scale (for head, thorax, abdomen, extremities), and occurrence of prehosp

58 ased on body regions, such as head and neck, thorax, abdomen, lower extremity, and upper extremity.

59 CT-thorax-abdomen and ultrasound guided biopsy revealed a p

60 twork was developed to segment the spleen on thorax-abdomen CT scans.

61 The thorax above the membrane was perfused with degassed wat

62 r regions of expression were in the head and thorax across all castes, and the abdomen in male and fe

63 sions underwent 45-min dynamic PET/CT of the thorax after intravenous administration of 366.3 +/- 14.

64 realistic phantom (lesions plus breasts plus thorax, all containing activity) was used, as compared t

65 From CT of the thorax and (18)F-FDG PET (neck to pelvis) performed befo

66 Soft tissues in the thorax and abdomen (alveolar lungs and liver) suggest th

67 ed by fluorescent AV-750 accumulation in the thorax and abdomen (in vivo), in isolated organs (ex viv

68 performed with EUS-FNA, with CT scan of the thorax and abdomen and FDG-PET, to detect metastatic dis

69 rwent computed tomography examination of the thorax and abdomen and tissue Doppler echocardiography w

70 to whole-body (18)F-FDG PET/CT or CT of the thorax and abdomen as the imaging modality.

71 CT of the thorax and abdomen demonstrated changes in the liver, sp

72 RNA of AlucJHEH gene was detectable in head, thorax and abdomen from all life stages.

73 le most tetrapods expand this pattern in the thorax and abdomen into four.

74 ential positioning of Cho organs between the thorax and abdomen is known to be regulated by Hox genes

75 fferential positioning of Cho organs between thorax and abdomen may be determined by Hox gene-mediate

76 stems, have flexible valving systems between thorax and abdomen that can separate pressures.

77 re evident in the Apyr-R strain in both head+thorax and abdomen tissues than in the ACY strain.

78 hough expression patterns of CYP4G19 in head+thorax and abdomen tissues were similar (i.e. lower in h

79 Computer tomography (CT) scan of the thorax and abdomen to detect metastatic disease, and end

80 In 33%, aneurysms in other arteries in the thorax and abdomen were diagnosed, and in 48%, arterial

81 Fifteen whole-body (spanning thorax and abdomen) PET/CT image pairs acquired separate

82 lorectal liver metastases underwent body CT (thorax and abdomen) with a 64-section multidetector unit

83 ean, Ubx/AbdA proteins are expressed in both thorax and abdomen, including the limb primordia, but do

84 ttern, restricted to the non-mammal tetrapod thorax and abdomen, is observed in the mammalian perineu

85 hich are essential for the patterning of the thorax and abdomen, respectively [8, 9].

86 suppress growth of some dorsal flaps in the thorax and abdomen.

87 rlapping striped patterns in the presumptive thorax and abdomen.

88 yer ventrolateral muscular patterning of the thorax and abdomen.

89 isocontour VOIs with elevated uptake in the thorax and abdomen/pelvis.

90 left differentiation of the embryonic heart, thorax and aorta.

91 nt lacking most of the large bristles on the thorax and by several EMS-induced recessive lethals.

92 and bacterial load are due to injury of the thorax and can be recapitulated by abdominal inoculation

93 Optimized 3D volumes of the fetal thorax and cardiac chambers were rapidly acquired and la

94 elia with broad and bowed long bones, narrow thorax and craniofacial abnormalities.

95 The body has a wide, stout thorax and elongated abdomen with biramous parapodia wit

96 Vg was expressed in thorax and head fat body cells in an age-dependent manne

97 iratory epithelia (tracheal air sacs) of the thorax and head.

98 neration-regeneration were observed in head, thorax and limb muscles.

99 dy axis-a region corresponding to the entire thorax and most of the abdomen of insects-and that they

100 f each image within 50 adult CT scans of the thorax and of the abdomen and pelvis and was also measur

101 rdinated out-of-phase axial rotations of the thorax and pelvis.

102 atus of the mosquitoes by analysing the head-thorax and saliva at 13 days post-exposure to birds.

103 from a combination of the dorsal part of the thorax and the body wall.

104 5 patients with tumor manifestations in the thorax and upper abdomen were acquired on a simultaneous

105 sis constitute dose-limiting side effects of thorax and whole body irradiation.

106 d individuals displayed abnormalities of the thorax and/or long bones, as well as renal, hepatic, or

107 n into a region with locomotory appendages ("thorax") and a region with reduced appendages ("abdomen"

108 element, the hinge, which attaches it to the thorax, and a distal one, the wing blade.

109 on admission was collected, as well as head, thorax, and abdomen AIS, and timing of prophylaxis (with

110 sed arrangement of hairs on the legs, wings, thorax, and abdomen of adult Drosophila.

111 and female alates), tissues (antennae, head, thorax, and abdomen), and developmental stages (egg, lar

112 6-(18)F-fluorodopamine scanning of the head, thorax, and abdomen, with or without treatment with desi

113 ding false-positive PET imaging in the neck, thorax, and abdomen.

114 twice as many SOPs in the abdomen as in the thorax, and do so at the expense of an abdomen-specific

115 rotein levels of ALAT1 or ALAT2 in fat body, thorax, and Malpighian tubules compared with dsRNA firef

116 tail, monofilaments around the head and the thorax, and more complex featherlike structures around t

117 r fluid volume (ECFV), and ECFV of the neck, thorax, and right leg before and after sleep.

118 eased bristle number occurs in the head, the thorax, and the anterior and posterior abdomen.

119 wings evolved as an extension of the dorsal thorax, and the gill-exite hypothesis, which proposes th

120 inations include portions of the lungs, bony thorax, and upper abdomen.

121 urance testing, dynamic kinematic MRI of the thorax, and ventilatory adjustments to single-breath ins

122 development and at the same level in heads, thoraxes, and abdomens.

123 otype, in which most head structures and the thorax are deleted, as are the three most posterior abdo

124 t germ' embryogenesis, wherein only head and thorax are patterned in a syncytial environment while th

125 mably increase power and flexibility of head-thorax articulation, emphasizing that workers are not si

126 on of alternating current applied across the thorax as a function of blood volume in the heart and gr

127 y located in the neck rather than inside the thorax as in other birds, while the internal structure i

128 ction of a new pupal cuticle on the head and thorax as well as on the abdomen.

129 CUP metastases in the thorax associated with a relative's cancers in the upper

130 gnant pulmonary nodules underwent PET of the thorax at 2 time points: scan 1 at 70 min (range, 56-110

131 tude alternating current of 5 mA through the thorax at a frequency of 35 kHz.

132 n of depth the heart and the skeleton of the thorax at the same time.

133 s high-resolution computed tomography of the thorax, BAL cell patterns and other characteristics freq

134 nical translation for imaging cancers of the thorax because of the low background signal in healthy t

135 g pads that were medially articulated to the thorax but also broadly contiguous with the notum anteri

136 re in CT images was first extracted from the thorax by marking manually the regions of interest on th

137 d with sagittal and coronal diameters of the thorax by using the Student t test, Fisher exact test, a

138 ed lung cancer detection.Keywords: CT, Lung, Thorax(C) RSNA, 2020.

139 sion of the trunk gap genes so that head and thorax can properly form.

140 that a single dose of 15 Gy of x-rays to the thorax causes severe pneumonitis in rats by 6-8 wk.

141 Smn reduce dSMN protein levels in the adult thorax, causing flightlessness and acute muscular atroph

142 tal epithelia of Drosophila pupae leading to thorax closure corresponds with spatiotemporal gradients

143 e fusion, embryonic dorsal closure and pupal thorax closure in Drosophila are useful experimental mod

144 icroscopy of the breathing lung under sealed thorax conditions was combined with multispectral oximet

145 lung apices or subpleural alveoli under open thorax conditions.

146 ure is indeed uniform within the abdomen and thorax, congruent with the predicted behavior of an open

147 y-six patients suspicious for lung cancer on thorax CT imaging were prospectively further evaluated b

148 blade and surrounding regions of the dorsal thorax cuticle, providing tissue for subsequent modifica

149 In the thorax, D(W)versus D(eff) had an R(2) of 0.51 (n = 200,

150 xcluded from the anterior to permit head and thorax development [1,2].

151 sion of unlocalized nos mRNA suppresses head/thorax development, emphasizing the importance of spatia

152 whereas mis-specified cells in the head and thorax die, presumably because equivalent survival signa

153 ging were prospectively further evaluated by thorax diffusion-weighted imaging and PET/CT.

154 ncreased the temperature of the butterflies' thorax dramatically, showing that the V-shaped basking p

155 lesions plus breasts containing activity; no thorax), due to the effects of increased scatter and att

156 n invasive mass that penetrates the adjacent thorax during a period of high 20E.

157 pel is expressed in a gap-like domain in the thorax during the blastoderm and germband stages of embr

158 eloped to enhance the return of blood to the thorax during the chest decompression phase.

159 e was designed to create a vacuum within the thorax during the decompression phase of cardiopulmonary

160 mesochrysopids exhibit a uniquely prolonged thorax, elongate legs, and dramatically reduced hind win

161 By examining how the Drosophila pupal dorsal thorax epithelium responds to morphogenetic forces, we f

162 uccessfully estimates blast tolerance of the thorax, fails to capture the brain mechanical response t

163 Two woman underwent a CT examination of the thorax for different thoracic pathologies.

164 In the thorax, Grh prolongs neural proliferation by maintaining

165 had radiotherapy to the head, neck, or upper thorax have an increased risk of subsequent primary thyr

166 cation of helical computed tomography of the thorax (HCTT) for the diagnosis of blunt aortic injury (

167 specification of body wall identities in the thorax; however, contrasting with results from other spe

168 of senseless loss-of-function clones in the thorax implicates Senseless not in the primary SO precur

169 entrations, and they accumulate fat in their thorax in a manner analogous to mammalian obesity.

170 dge, a structure that separates the head and thorax in all insects.

171 cant role in the development of the head and thorax in Drosophila melanogaster.

172 , results of computed tomography (CT) of the thorax in each case were highly suggestive of septic pul

173 diolaterally wide and anteroposteriorly deep thorax in KNM-WT 15000 that differs considerably from th

174 ly onset, and manifests predominantly in the thorax in lung transplant and heart-lung transplant reci

175 nal-tactile information from the head to the thorax in the cricket Gryllus bimaculatus.

176 erior (A-A) position (left and right lateral thorax) in nine dogs.

177 phology of joints connecting the legs to the thorax, in bristle patterns, and in the positioning of s

178 , the default state of vvl expression in the thorax, in the absence of Hox gene expression, features

179 ces in the contributions of each disc to the thorax, in the morphology of joints connecting the legs

180 p to total occlusion of central veins of the thorax including superior vena cava (SVC), brachiocephal

181 Thorax inoculation results in increased bacterial prolif

182 mal mortality and lower bacterial loads than thorax inoculation.

183 ranscriptional regulators that subdivide the thorax into expression domains (prepattern) required for

184 73(-/-) mice received a single dose of whole thorax irradiation (WTI, 15 Gy).

185 L/6 mice to a single dose (15 Gray) of whole thorax irradiation triggered a progressive increase in C

186 CT of the thorax is clinically useful in selected situation in pat

187 the boundary between the embryonic head and thorax is formed by the dorsal ridge, a fused structure

188 rosophila notum, the dorsal body wall of the thorax, is subdivided genetically into longitudinal doma

189 the cardiopulmonary system, mediastinum, and thorax it will help to guide therapeutic decisions.

190 gions of nonuniform attenuation, such as the thorax, it is possible that foci of increased tracer upt

191 n is expanding the applications of CT of the thorax, its role as a diagnostic tool still needs to be

192 to direct proper development of the head and thorax, leading to embryonic lethality.

193 ive effects of seminal receptacle length and thorax length in both experiments.

194 etic correlation between ovariole number and thorax length was positive, but the strength of this cor

195 ovariole number, and body size, measured as thorax length, are developmentally plastic traits with r

196 Thorax length, testis mass, sperm length, egg-to-adult d

197 uSv [5-27] in group 2; P<0.0001) and also at thorax level (4 uSv [1-13] in group 1, 2 uSv [1-4] in gr

198 ive to reduce operator radiation exposure at thorax level during percutaneous coronary procedures, bu

199 er radiation dose to operators at pelvic and thorax level.

200 With a broad thorax, long lumbar spine and extended hips and knees, a

201 nd cause lethality following high-dose whole-thorax lung irradiation (WTLI).

202 urs after exposure to a single dose of whole thorax lung irradiation sufficient to cause minor to maj

203 ed within each sample at 180 days post whole-thorax lung irradiation.

204 e oesophagectomy with two-field (abdomen and thorax) lymphadenectomy was done within 4-6 weeks of com

205 in the development of sensory organs in the thorax, mainly in the positioning of specific proneural

206 We analyzed thorax morphology of queens and workers in species from

207 dimorphism is an important feature of adult thorax morphology, but when and how sex-related differen

208 omography (PET)/computed tomography (CT) and thorax MR examinations.

209 y (n = 130), sacrococcygeal region (n = 98), thorax (n = 23), and other (n = 47).

210 al FOV D(W) increased from 54% to 90% in the thorax (n = 3602 images) and from 95% to 100% in the abd

211 g the anteroposterior axis of the Drosophila thorax (notum).

212 ing Pathways in Evaluation of Cancers of the Thorax) NSCLC data set.

213 by age, were implanted subcutaneously in the thorax of 18 nude (nu/nu) mice.

214 wide gene expression changes in the head and thorax of adult Indy mutant with control flies over the

215 incidence and titer were higher in the head-thorax of adults than in nymphs.

216 The distribution of sensory bristles on the thorax of Diptera (true flies) provides a useful model f

217 , two-dimensional pattern of bristles on the thorax of Drosophila has been intensively investigated a

218 The polarity of sensory bristles on the thorax of Drosophila is linked to the orientation of the

219 otal, 75 muscles have been identified in the thorax of Epiophlebia.

220 differs considerably from the much shallower thorax of H. sapiens, pointing to a recent evolutionary

221 en DFDBA was implanted subcutaneously in the thorax of nude mice, there was no histologic evidence of

222 The spiders attacked the lateral side of the thorax of termites and immobilised them within 1 min.

223 oid (Bcd) morphogen establishes the head and thorax of the Drosophila embryo.

224 of Bicoid protein that patterns the head and thorax of the embryo.

225 tive three-dimensional reconstruction of the thorax of the juvenile H. erectus skeleton, KNM-WT 15000

226 nt secreted from the "building organ" on the thorax of the worm.

227 Thorax operator dose did not differ for right radial (84

228 of fungus-infected fluid collections in the thorax or abdomen treated by using percutaneous catheter

229 patients with suspected malignancies in the thorax or abdomen underwent whole-body (18)F-FDG CBM PET

230 ing and possibly contrast-enhanced CT of the thorax or abdomen-pelvis.

231 brain scans and 5 subjects had scans of the thorax or abdomen.

232 g childhood who received radiotherapy to the thorax or head and neck region.

233 s in other body part representations such as thorax or leg muscles.

234 eggs, embryos, larvae, pupae, adult head and thorax, ovary, testis, and S2 tissue culture cells, as w

235 FV of the right leg (P = 0.044), ECFV of the thorax (P = 0.001), and ECFV of the neck (P = 0.003).

236 of abnormalities of the central veins in the thorax, particularly with regard to selection of venous

237 ns (Homo sapiens) evolved via changes in the thorax, pelvis and limbs.

238 multiple detector computed tomography of the thorax, performed on two modern CT scanners, were retros

239 of a resolution phantom, an anthropomorphic thorax phantom and a human subject.

240 For the thorax phantom and human subject, short (2-min) and long

241 were acquired using both an anthropomorphic thorax phantom containing a cardiac insert and a human v

242 A nonuniform heart-thorax phantom was filled with 111 MBq of (82)Rb injecte

243 A thorax phantom was imaged with spheres of 3 sizes simula

244 different experiments: in a realistic heart-thorax phantom, in a uniformity-resolution phantom, and

245 polarized fashion such that bristles on the thorax point posteriorly.

246 venous return out of the brain and into the thorax, preclinical outcomes are improved significantly

247 ed that 13 or more operators, each wearing a thorax (primary endpoint), wrist, and head (secondary en

248 fractures and a compression deformity of the thorax, probably acquired while encased in the glacier,

249 ue-equivalent anthropomorphic phantom of the thorax (Radiology Support Devices, Inc., Long Beach, CA)

250 unt of scatter and tissue attenuation in the thorax region depends on source distribution and body at

251 ) and cell death in the presumptive head and thorax regions.

252 tumors combined with a low background in the thorax resulted in a statistically higher tumor to backg

253 that CLas bacterium had moved into the head-thorax section (containing the salivary glands) in 26.7-

254 ronchoscopy in an anesthetized adult sheep's thorax: section thickness (2, 4, 8 mm), pitch (1.0, 1.5,

255 ssed against the uveal region of the TM, the thorax securely inserted within the TM, and the head loc

256 eal that ants invest in the relative size of thorax segments according to their tasks.

257 We found that fractionated radiation to the thorax significantly reduced circulating T and B cells a

258 Our results show that the trajectories of thorax size and shape between sexes diverge at around 12

259 T) of an image of the considered transversal thorax slice.

260 In the thorax, spalt and spalt-related are expressed in a restr

261 Moreover, we identified three thorax-specific neuroblasts not previously characterized

262 Data regarding the thorax, spine, face, limbs, hands, and feet were compare

263 In all patients, the thorax station was examined with free-breathing radial V

264 In the thorax, sternocostal connections were arranged asymmetri

265 y the projection of anatomic features in the thorax, such as ribs and pulmonary vessels, can greatly

266 verage 62% higher in the abdomen than in the thorax, suggesting that functional compartmentalization

267 -specified cells in the presumptive head and thorax survive and continue to develop, but they are tra

268 differentially expressed in the female head-thorax than the abdomen following mating, whereas the op

269 es, which cause cyclical deformations of the thorax that are amplified through the intricate wing hin

270 tify specific mechanical linkages within the thorax that passively mediate both wing-wing and wing-ha

271 In the larval thorax, the majority of imaginal myoblasts are associate

272 any of five different regions of the head or thorax; they are curved, straight, branched or bladed; a

273 rs and thorax tissue of workers, followed by thorax tissue of female alates and abdomen tissue of mal

274 tissue of both female alates and workers and thorax tissue of workers, followed by thorax tissue of f

275 ed, the transcriptional profile of male head-thorax tissue was largely unaffected by mating, and no d

276 men tissues were similar (i.e. lower in head+thorax tissues and higher in abdomen tissues) in both th

277 CYP4G19 mRNA were readily detectable in head+thorax tissues and increased ( approximately 5-fold) in

278 of CYP4G19 mRNA were relatively low in head+thorax tissues and were about 7-fold increase in the abd

279 tre of mass moved from a position in the mid-thorax to a more caudal position nearer to the pelvis.

280 ntises first rotated their abdomen about the thorax to adjust the center of mass and thus regulate sp

281 ody imaging and SPECT/CT were performed from thorax to pelvis using a double-head 16-slice SPECT/CT s

282 l and Smith in 2003, as the inability of the thorax to support normal respiration and growth.

283 a broad dorsal vessel extending through the thorax to the brain where anastomosing branches overlap

284 We estimate that the loom of a kite's thorax towards a locust at these speeds should be charac

285 wing structure is strikingly similar to the thorax tymbals with which arctiine moths produce their a

286 In the thorax, Ubx is necessary for gill development and for re

287 on and scatter properties of the adult human thorax was employed to assess eight imaging systems in a

288 viding attenuation equal to that of an adult thorax was used.

289 -0.75 mm isotropic) 3D datasets of the fetal thorax were generated in all 85 cases.

290 nt dedicated computed tomography (CT) of the thorax were prospectively recruited into the study.

291 om 14 subjects with malignant lesions in the thorax were registered.

292 e patients with renal cell metastases in the thorax were studied using [15O]water and dynamic PET.

293 rnum bone lies at the ventral midline of the thorax where it provides a critical attachment for the p

294 proper development of the head and anterior thorax, which is the counterpart of the ANTC in Drosophi

295 similar result is obtained for patients with thorax widths of <40 cm.

296 extract anatomical components of mosquitoes-thorax, wings, abdomen and legs from images.

297 of tumor quantification in PET images of the thorax with ACT.

298 stic whole-body phantom consisting of brain, thorax with lungs and liver, and pelvis with bladder was

299 computed tomographic (CT) angiography of the thorax with retrospective electrocardiographic gating.

300 We used a rat model of whole thorax x-ray irradiation to profile the microRNA (miRNA)