ライフサイエンスコーパス: thigh

1 skull base to mid thigh, from vertex to mid thigh).

2 l T2 mapping from the iliac crest to the mid thigh.

3 cular injection of turpentine into the right thigh.

4 within the muscle vascular bed of the human thigh.

5 phenylephrine (PE), in the exercising human thigh.

6 competence in the deep veins of the calf and thigh.

7 aicin dressing applied to the distal lateral thigh.

8 a ratio of 1.6 for inflamed thigh to normal thigh.

9 activated (inflammation model) cultures in a thigh.

10 PET was performed from ear to middle of the thigh.

11 d via ice cup massage over the anterolateral thigh.

12 e injection of carbon particles into a mouse thigh.

13 sutism were higher for all body areas except thigh.

14 eritonitis; the third had pyomyositis of the thigh.

15 red from the top of the head through the mid thighs.

16 f the neck, shoulders, hips, upper arms, and thighs.

17 t on the central or upper back, buttocks, or thighs.

18 based on measuring soft-tissue uptake in the thighs.

19 nsfer pads applied directly to the trunk and thighs.

20 ion scans were obtained from the head to mid thighs.

21 e around her lips, trunk, axillae, arms, and thighs.

22 cutaneous nodules on the buttocks, arms, and thighs.

23 , calf -1.1 pu [0.2]; Charcot-Marie-Tooth 1A thigh -0.3 pu [0.1], calf -0.7 pu [0.1]).

24 ], calf 3.5 ms [0.6]; Charcot-Marie-Tooth 1A thigh 1.0 ms [0.3], calf 2.0 ms [0.3]) and MTR reduced c

25 pared with controls (inclusion body myositis thigh -1.5 percentage units [pu; 0.2], calf -1.1 pu [0.2

26 eg IENFD (6.48 [1.06]) was lower than distal thigh (13.32 [1.08]) and proximal thigh IENFD (19.98 [1.

27 ase was larger in the calf (20%) than in the thigh (14.5%) (P <or= 0.005) and was partially explained

28 e cuff inflation to >200 mm Hg in the arm or thigh (20 mm Hg in the control) with 5-minute breaks bet

29 The loss in strength was greater in the thigh (20.4%) than in the calf (15%).

30 ce bearing ARO tumor xenografts in the right thigh, 24 h after being reconstituted with 10(5), 10(6),

31 ession coefficients: inclusion body myositis thigh 4.0 ms [SE 0.5], calf 3.5 ms [0.6]; Charcot-Marie-

32 quently intramuscular (82%) and involved the thigh (51%).

33 In vivo secretion was measured in a murine thigh abscess model, where similar levels of SEl-K accum

34 cluding rectus abdominis insertional injury, thigh adductor injury, and articular diseases at the pub

35 most and earliest affected muscles were the thigh adductors, glutei and posterior thigh groups, whil

36 We conclude that greater thigh adipose tissue in women is associated with greater

37 a ratio of 2.3 for infected thigh to normal thigh and a ratio of 1.6 for inflamed thigh to normal th

38 ity in Hounsfield units were measured in the thigh and abdomen by using computed tomography.

39 skin-to-muscle depth (STMD) at anterolateral thigh and anterior thigh were performed.

40 in methicillin-sensitive S. aureus and MRSA thigh and bacteremia infections and pneumococcal lung in

41 Chicken thigh and breast skin proteins were hydrolysed using alc

42 elocity of lipid oxidation in cooked chicken thigh and breast was demonstrated after 48 and 96h of re

43 Chicken samples (thigh and breast) were then separated into five groups:

44 Reduced physical activity decreased thigh and calf muscle volumes by 7.4% and 7.9% (P < 0.00

45 br cells, followed by 10 injections into the thigh and calf of the index leg.

46 ced a disulfide "clamp" between the alphaIIb thigh and calf-1 domains.

47 a large plaque of FDH on her left posterior thigh and calf.

48 d by using magnetic resonance imaging in the thigh and calf.

49 ifference in surface temperature between the thigh and foot regions (thigh-foot index) of the legs in

50 innervate a pair of adductor muscles in the thigh and hence compete for survival during the period o

51 ly (5000-8000 IEQ/device) at two sites (left thigh and interscapular region) and were explanted at 2,

52 from proximal (ie, cervical) and distal (ie, thigh and leg) sites to study small nerve fiber and intr

53 or long bones fractures of the arm, forearm, thigh and lower leg.

54 (time to permanent failure) was similar for thigh and upper extremity grafts (median, 14.8 versus 20

55 Intervention-free survival was similar for thigh and upper extremity grafts (median, 3.9 versus 3.5

56 mbosis-free survival was also comparable for thigh and upper extremity grafts (median, 5.7 versus 5.5

57 15 versus 1.70 per year) was similar between thigh and upper extremity grafts.

58 (abscessed) thigh than in the contralateral thigh (and higher uptake than the inactivated tracer).

59 shoulders, hips, or proximal aspects of the thighs), and erythrocyte sedimentation rate (ESR) > or =

60 - 10 in the pelvis, 45 seconds +/- 10 in the thigh, and 35 seconds +/- 14 in the calf.

61 irls it was biceps, subscapular, suprailiac, thigh, and calf (SEE = 3.51).

62 at triceps, biceps, subscapular, suprailiac, thigh, and calf sites was measured with use of Holtain c

63 y of the major blood vessels of the abdomen, thigh, and calf were evaluated.

64 me occurred in 30%, 35%, and 35% of the arm, thigh, and control groups, respectively (P=0.64).

65 D change over time at the distal leg, distal thigh, and proximal thigh irrespective of cause are -1.4

66 IPP, tourniquets were positioned around both thighs, and an inflated pressure suit was placed at a su

67 tered pink papules and plaques on the trunk, thighs, and buttocks and multiple raised, erythematous n

68 woody induration of the muscles of the legs, thighs, and forearms.

69 hip swing, more asymmetric movements of the thighs, and intermediate levels of asymmetric movements

70 of CUA involving lower abdomen and/or upper thigh areas (odds ratio, 1.49; 95% confidence interval,

71 Measures of calf and thigh arterial compliance (MaxV50) were recorded in 267

72 ze the diagnostic accuracy in the pelvic and thigh arteries.

73 roid cancer (ARO) cells in the contralateral thigh as control.

74 e length (15.02 mm), using the anterolateral thigh as the recommended administration site.

75 1/10 IPV-Al], or IPV) intramuscularly in the thigh at 6, 10, and 14 weeks of age.

76 med 5 min after injection from the vertex to thighs at 3 min per bed position.

77 ody PET/CT scans, from the vertex to the mid thigh, at 10, 60, 120, and 240 min after injection.

78 ity at the T cell injection sites and in the thigh (background) was measured.

79 n uptake was determined from measurements of thigh blood flow and femoral arterial - venous differenc

80 een contraction frequencies during exercise, thigh blood flow was higher (P < 0.05) at 100 compared t

81 ible, the cuff is placed at the ankle or the thigh, but this common practice has never been assessed.

82 of cutaneous inflammation was induced in the thigh by intradermal injection of tuberculin.

83 ns at a muscle-bone interface in nine rabbit thighs by using focused ultrasound under closed-loop tem

84 d was compared between treated and untreated thighs by using the one-sided Wilcoxon signed rank test.

85 ENFD and 30-day cutaneous regeneration after thigh capsaicin axotomy were compared for participants w

86 Adjusted postintervention body- and thigh-composition measures were all lower with RT+CR exc

87 The associations of thigh-composition measures with disability and physical

88 verall physical function, and total body and thigh compositions.

89 ely 5% of peak exercise hyperaemia.Likewise, thigh compressions alone or in combination with passive

90 or artery ATP infusion (n=6), and (5) cyclic thigh compressions at rest and during passive and volunt

91 =8), distal limb perfusion improved, and mid-thigh conductance vessels increased in number and total

92 LC3B lipidation inversely correlates with thigh cross-sectional area, FEV1, and FEV1/FVC ratio.

93 dy found a correlation coefficient for total thigh CSA and total neck CSA of 0.88.

94 nations performed concurrently with chest or thigh CT or for trauma were not included in the 106.

95 Thigh CT-derived measures of body composition, particula

96 In addition, predictions of thigh cuff data from spectral estimates were extremely i

97 and with partial flow restriction (bilateral thigh cuff inflation at 100 mmHg) to evoke muscle metabo

98 blood flow and once with local ischaemia by thigh cuff inflation to 220 Torr.

99 on with partial flow restriction (bi-lateral thigh cuff inflation) during leg cycling exercise, (2) i

100 rwent limb ischemia-reperfusion generated by thigh cuff inflation, and plasma miRNA changes were anal

101 the lower leg was occluded by inflation of a thigh cuff to above 200 mmHg.

102 three manoeuvres (neck pressure, unilateral thigh-cuff release and isometric handgrip) would be grea

103 After thigh-cuff release, femoral vascular conductance decline

104 ressure subsequent to deflation of ischaemic thigh cuffs.

105 Skin biopsy of an erythematous plaque on the thigh demonstrated a suppurative folliculitis.

106 whom magnetic resonance imaging of the left thigh demonstrated edematous changes in the muscle compa

107 he amount of adipose tissue in abdominal and thigh depots may also convey risk beyond BMI.

108 und to an alpha4 integrin beta-propeller and thigh domain fragment shows that natalizumab recognizes

109 and nearby species-specific residues in the thigh domain.

110 n open region between the beta-propeller and thigh domains of the alpha7 chain.

111 a interface between IE2 (EGF-like 2) and the thigh domains.

112 otocol consisted of a midcranium to proximal thigh emission scan of 2-4 minutes per bed position.

113 constriction in the resting leg, and dynamic thigh exercise attenuates alpha(1)- and alpha(2)-mediate

114 terior rectus sheath, and the right anterior thigh fascia was required to gain control of the infecti

115 idfemoral quantitative CT for measurement of thigh fat area (TFA), thigh muscle area (TMA), and thigh

116 tolerance test, and abdominal, thoracic, and thigh fat areas by CT.

117 circumference; and abdominal, thoracic, and thigh fat areas measured by CT.

118 Abdominal, thoracic, and thigh fat areas were measured by using computed tomograp

119 Fat mass, percentage of fat, and all thigh fat volumes decreased in both groups, but only the

120 teer's legs were measured at ankle, calf and thigh following guidance from British nurses and in acco

121 perature between the thigh and foot regions (thigh-foot index) of the legs in trauma patients was det

122 locking PET scans were acquired from head to thigh for 3 rhesus monkeys for approximately 120 min aft

123 ed to contralateral areas on the skin of the thigh for 48 hours.

124 increasing numbers of human NKs in the right thigh (from 2.5x10(6) to 40x10(6)) and human granulocyte

125 rom vertex to ischia, from skull base to mid thigh, from vertex to mid thigh).

126 t extension occurs by a rearrangement at the thigh/genu interface.

127 Thigh girth change was more strongly associated with fat

128 tivity was associated with an attenuation of thigh girth decline in men and women (F ratio = 5.13, P

129 Waist and thigh girths, rather than skinfold thicknesses, should b

130 Placement of a thigh graft is an option in hemodialysis patients who ha

131 d were evaluated prospectively, including 63 thigh grafts (15% of the total).

132 e median cumulative survival was 27.6 mo for thigh grafts and 22.5 mo for upper extremity grafts (P =

133 The outcome of thigh grafts has been reported only in retrospective stu

134 In conclusion, placement of thigh grafts should be considered a viable option among

135 result of infection tended to be higher for thigh grafts than for upper extremity grafts (11.1 versu

136 ure rate was approximately twice as high for thigh grafts, as compared with upper extremity grafts (1

137 re the thigh adductors, glutei and posterior thigh groups, while lower leg muscles were relatively sp

138 argest acquisition field, from vertex to mid thigh: ICC, 0.994; 95% confidence interval [95% CI], 0.9

139 han distal thigh (13.32 [1.08]) and proximal thigh IENFD (19.98 [1.07]) (P = .001).

140 erial measurements at each site (arm, ankle, thigh [if Ramsay sedation scale >4]) and, in case of cir

141 BMI and thigh IMAT area (independent of BMI) were particularly s

142 (95% CI) associated with an SD increment in thigh IMAT for mobility limitation and poor performance

143 8)F-PBR06, images were acquired from head to thigh in 7 healthy humans.

144 viable beta cells in interscapular site and thigh in autologous recipients and 85.6%+/-4.01% (inters

145 = 6, including 5 using the neutropenic mouse thigh infection model), and clinical studies in humans (

146 er the mouse peritonitis-sepsis model or the thigh infection model.

147 ty and shows efficacy in a mouse neutropenic thigh infection model.

148 the Staphylococcus aureus neutropenic murine thigh-infection model, the ratio of the free area under

149 egrin leg and head domains, identify the IE2-thigh interface as a critical steric barrier in integrin

150 isceral adipose tissue (VAT), thigh SAT, and thigh intermuscular adipose tissue CSA and attenuation w

151 In longitudinal analyses, changes in thigh intermuscular fat and total thigh muscle were the

152 High and increasing thigh intermuscular fat are important predictors of gait

153 Baseline thigh intermuscular fat predicted the annual gait-speed

154 deled together, every 5.75-cm(2) increase in thigh intermuscular fat was associated with a 0.01 +/- 0

155 or trend = 0.004), inversely associated with thigh intramuscular fat (P for trend = 0.02), and not si

156 se, glycated hemoglobin, fasting insulin, or thigh intramuscular fat.

157 t the distal leg, distal thigh, and proximal thigh irrespective of cause are -1.42, -1.59, and -2.8 f

158 55 (40.7%) of the 135 patients allocated to thigh-length CES and in 36 (27.3%) of those randomized t

159 44 (32.6%) of the 135 patients randomized to thigh-length CES and in 47 (35.6%) of the 132 allocated

160 We conclude that thigh-length CES do not offer a better protection agains

161 al randomisation system to routine care plus thigh-length GCS (n=1256) or to routine care plus avoida

162 ccurred in 126 (10.0%) patients allocated to thigh-length GCS and in 133 (10.5%) allocated to avoid G

163 These data do not lend support to the use of thigh-length GCS in patients admitted to hospital with a

164 We assessed the effectiveness of thigh-length GCS to reduce DVT after stroke.

165 us thrombosis were randomized to wear either thigh-length or below-knee CES for 2 years.

166 abel, randomized clinical trial, we compared thigh-length with below-knee CES for the prevention of P

167 hange 1.2%, 95% CI 0.5-1.9, p=0.002) but not thigh level (0.2%, -0.2 to 0.6, p=0.38) in patients with

168 d at calf level (2.6%, 1.3-4.0, p=0.002) and thigh level (3.3%, 1.8-4.9, p=0.0007) in patients with i

169 Nerve proton spin density at the thigh level is a novel quantitative imaging biomarker of

170 ll MS patients, with a mean lesion number at thigh level of 151.5 +/- 5.7 versus 19.1 +/- 2.4 in cont

171 RG) or a segment of the sciatic nerve at mid-thigh level was maintained by perfusion with 30-mM gluco

172 of bolus-chase MR angiography at the pelvis-thigh level was slightly higher when it was performed fi

173 f microstructural nerve alteration is at the thigh level with a strong proximal-to-distal gradient.

174 = 0.003) with strong spatial predominance at thigh level, where average lesion voxel load was signifi

175 tors around one healthy sciatic nerve at mid-thigh level.

176 ee depots), and muscle (truncal postural and thigh locomotive) FFA uptake using [(11)C]palmitate posi

177 The average of calf and thigh MaxV50 was strongly predictive of extent of aortic

178 eactive protein, and the average of calf and thigh MaxV50.

179 Either the ankle or the thigh may be reliable alternatives, only to detect hypot

180 ptake in abscessed thigh to uptake in normal thigh, mean +/- SD] and 0.72 +/- 0.01 for scVEGF/Cy and

181 brae L1-L5 plus intervertebral discs and the thigh (midthigh, 10 cm distally from the midthigh, and 1

182 arison of 5x and PMB in a murine neutropenic thigh model against P. aeruginosa strains with matched M

183 ivo mouse systemic infection and neutropenic thigh model experimental results confirmed the therapeut

184 ines, and (iv) efficacy in an in vivo murine thigh model of infection employing MRSA.

185 An in vivo porcine thigh model was used to study systemically delivered mag

186 hamide-treated mouse lung model but not in a thigh model, suggesting a role for RitR in regulation of

187 resistance in vivo was examined in a murine thigh model.

188 ned on different scanners, and collected mid-thigh MR data.

189 s: the gluteus muscle (r = 0.875; P = .001), thigh muscle (r = 0.903; P , .001), calf muscle (r = 0.8

190 tly enhanced their balance and lowered their thigh muscle activity by up to 30%.

191 -106.0+/-7.5% and 95.3+/-4.5-105.0+/-5.1% in thigh muscle and 97.5+/-5.1-105.0+/-7.5% and 95.3+/-5.4-

192 r TKA, an MRI was performed to determine mid-thigh muscle and adipose tissue volume.

193 Relaxation times of healthy thigh muscle and brain tissue were estimated by using mu

194 In vivo (39)K MR imaging of healthy human thigh muscle and brain was performed.

195 .5 x 9.5 x 9.5 mm(3) were achieved for human thigh muscle and brain, respectively.

196 The RT-induced increases in mid-thigh muscle area (from computed tomography scans) were

197 CT for measurement of thigh fat area (TFA), thigh muscle area (TMA), and thigh muscle density (TMD).

198 ved in all subjects, and the decrease in mid-thigh muscle area in the SED group, are physiological ac

199 Conversely, a decreasing thigh muscle area is also predictive of a decline in gai

200 Total body potassium, mid-thigh muscle area, type I and II muscle-fiber cross-sect

201 mL/min) were positioned perpendicular to the thigh muscle at 10 g contact weight.

202 We evaluated associations of thigh muscle composition, determined using computed tomo

203 fat area (TFA), thigh muscle area (TMA), and thigh muscle density (TMD).

204 n infection, and abscess-forming deep-seeded thigh muscle infection.

205 n vivo Luciferase gene expression in a mouse thigh muscle model.

206 Thigh muscle strength does not appear to predict inciden

207 centration (uncorrected for fat fraction) of thigh muscle tissue (112-124 mmol/L) lies within the exp

208 Results Adipose and thigh muscle tissue volumes of 20 subjects (18 women; ag

209 obin concentration, blood lactate level, and thigh muscle tSo2 level were poor predictors of cerebral

210 ol group, 6 mo of n-3 PUFA therapy increased thigh muscle volume (3.6%; 95% CI: 0.2%, 7.0%), handgrip

211 hod to quantify abdominal adipose tissue and thigh muscle volume and hepatic proton density fat fract

212 Thigh muscle volume, handgrip strength, one-repetition m

213 for estimating abdominal adipose tissue and thigh muscle volumes and hepatic PDFF.

214 speed, whereas every 16.92-cm(2) decrease in thigh muscle was associated with a 0.01 +/- 0.00-m/s dec

215 In 8 anesthetized dogs, the skin over the thigh muscle was incised and raised, forming a cradle su

216 n rabbits with Vx2 tumors within superficial thigh muscle were randomly assigned into three treatment

217 Abdominal adipose tissue and thigh muscle were segmented, and their volumes were esti

218 changes in thigh intermuscular fat and total thigh muscle were the only body-composition measures tha

219 Mice were infected in thigh muscle with a strain of S. pyogenes that expresses

220 ptake values were normalized against healthy thigh muscle, representing nontargeted tissue.

221 The vastus lateralis, a large thigh muscle, undergoes extensive neuromuscular remodell

222 mass (r = 0.32; P = .003) and the change in thigh muscle:intermuscular fat ratio (r = 0.27; P = .02)

223 Subcutaneous- and intraabdominal-fat areas, thigh-muscle area and strength, and sexual function were

224 Lean mass and thigh-muscle area decreased in men receiving placebo and

225 The anterior thigh muscles are particularly susceptible to muscle los

226 d a grade of zero to four for all pelvic and thigh muscles by using T1-weighted nonquantitative MR im

227 erved that mu-calpain activity in breast and thigh muscles declined very rapidly at 48 h and 24 h, re

228 ly and functionally distinct chick embryonic thigh muscles from E6 to E18.

229 ervated and surgically reinnervated residual thigh muscles in a patient who had undergone knee amputa

230 nt neural drive to synergistically activated thigh muscles in humans.

231 the livers and kidneys of 10 rabbits and the thigh muscles of 10 rats were randomly assigned to one o

232 tion of CFU from bacteria extracted from the thigh muscles of the mice correlated well with the biolu

233 scle involvement with fat deposition in most thigh muscles, but sparing of the adductors and semitend

234 e presence of ample tenderness of breast and thigh muscles.

235 inguinal and intra-abdominal lymph nodes and thigh muscles.

236 3), lung (n = 4), adrenal gland (n = 1), and thigh (n = 1).

237 alf (n = 85 [15.3%]), middle third of medial thigh (n = 73 [13.2%]), and middle third of posterior ca

238 ent of -6.3/13.1 mm Hg) contrary to ankle or thigh noninvasive blood pressure (mean bias of 3.1 +/- 7

239 oninvasive blood pressure but also ankle and thigh noninvasive blood pressure allowed a reliable dete

240 7], and 0.93 [0.85-0.98] for arm, ankle, and thigh noninvasive blood pressure, respectively); and 2)

241 mplication of this procedure was mild medial thigh numbness in two patients.

242 ake was lowest in the infection/inflammation thigh of mice infected with E. coli 2537, this finding w

243 The right thighs of C57BL/6 mice (n = 25) were injected s.c. with

244 Recently, a variant involving the lateral thighs of equestrians has been described.

245 us fat biopsies were obtained from the upper thighs of six lean and six obese nondiabetic subjects.

246 Murine glioblastoma tumors were grown in the thighs of two sets of 25 mice each.

247 st 1 connective tissue nevus on the trunk or thighs; of these, 28 of 58 patients (48%) had a solitary

248 >3 millimeter) punch skin biopsies from each thigh on days 1 and 14.

249 n beginning focally or asymmetrically in the thigh or leg but usually progressing to involve the init

250 the sciatic nerve at the middle level of the thigh or on the tibial nerve at the lower level of the l

251 T was categorized by location in the pelvis, thigh, or calf.

252 vaginal extrusion and urinary tract erosion, thigh pain, and sexual dysfunction.

253 A prodrome of thigh pain, lack of trauma prior to the fracture, and sp

254 MBq), 3 successive whole-body (vertex to mid thigh) PET/CT scans at 3 time points (30, 60, and 120 mi

255 Whole-body (vertex to mid thigh) PET/CT scans were acquired at 6 time points, up t

256 Whole-body (vertex to mid thigh) PET/CT scans were acquired at 6 time points, up t

257 lization of FeO nanoparticles within porcine thigh preps was demonstrated by magnetic resonance imagi

258 (ie, waist and hips instead of upper arm or thigh) proved to be the most reliable.

259 nd 10 healthy controls underwent 3 mm distal thigh punch skin biopsies to create an intracutaneous ex

260 differences between the rescuer's wrist and thigh ranged from 0.28 to 14 V (mean 5.8+/-5.8 V).

261 HtR], waist-to-hip ratio [WHR], and waist-to-thigh ratio [WTR]).

262 Waist-to-thigh ratio was associated with the ridge-count differen

263 associations of the anthropometric waist-to-thigh ratio with 20 ridge-count differences.

264 at mass) and body fat distribution (waist-to-thigh ratio, waist circumference, visceral and subcutane

265 Key thigh residues are shielded from Ab in the bent integrin

266 on at the site of predominant lesion burden (thigh) revealed a significant increase of nerve proton s

267 etected in the extracts of blood, breast and thigh samples were 0.28-0.55, 1.91-2.05 and 1.38-1.52 Un

268 In women, thigh SAT area was positively associated with mobility l

269 tisol levels were positively associated with thigh SAT attenuation (r = 0.64 [P = .006] and r = 0.68

270 tissue (SAT), visceral adipose tissue (VAT), thigh SAT, and thigh intermuscular adipose tissue CSA an

271 riceps, biceps, subscapular, suprailiac, and thigh (SEE = 2.87), and for girls it was biceps, subscap

272 yses of 472 calf segments and 420 pelvic and thigh segments were performed.

273 istal leg more quickly than at more proximal thigh sites.

274 er DPPH scavenging activity than the chicken thigh skin hydrolysates.

275 r injection of either radiotracer, a head-to-thigh static scan with a 2-min acquisition per bed posit

276 hy of the calves and, subsequently, a pelvis-thigh stepping-table acquisition.

277 4), a 1.3-cm subcutaneous nodule in the left thigh (SUV 16), and two 2.7-cm liver lesions (SUV 14).

278 r uptake (P < 0.05) in the right (abscessed) thigh than in the contralateral thigh (and higher uptake

279 Following SC injection into the animal thigh, the LC-MEs had more prolonged release of (99m)Tc

280 ulation, showing a ratio of 2.3 for infected thigh to normal thigh and a ratio of 1.6 for inflamed th

281 At 3 h in vivo, the ratio of target thigh to normal thigh was significantly higher (P < or =

282 normal thigh and a ratio of 1.6 for inflamed thigh to normal thigh.

283 (3.67 +/- 1.79 [ratio of uptake in abscessed thigh to uptake in normal thigh, mean +/- SD] and 0.72 +

284 act disease in Mediterranean tortoises [spur-thighed tortoise (Testudo graeca) and Hermann's tortoise

285 hemic conditioning of a larger remote organ (thigh versus arm) would provide further myocardial prote

286 01% (interscapular site) and 74.1%+/-12.05% (thigh) viable beta cells in allogenic islet recipients.

287 nt pathway, a skin electrode on the rescuers thigh was connected to an electrode on the patient's sho

288 in vivo, the ratio of target thigh to normal thigh was significantly higher (P < or = 0.017) in the i

289 r size was 8 cm (range, 1 to 30 cm), and the thigh was the most common tumor location (n = 31).

290 h (STMD) at anterolateral thigh and anterior thigh were performed.

291 Two-minute static images of the thighs were acquired immediately after the 1- to 4-h who

292 Two-minute static images of the thighs were acquired immediately before each whole-body

293 and mean T2 of 18 muscles in the pelvis and thighs were analyzed to identify the most severely invol

294 ll-animal (18)F-FDG PET and MRI scans of the thighs were obtained and coregistered.

295 Subjects were scanned from head to mid thigh with 7 passes performed, with a total PET acquisit

296 rwent computed tomography of the abdomen and thigh with a calibration phantom.

297 ulated insulin release (P=0.028) in the left thigh with implant (17.58+/-3.13 mU/L) compared with the

298 rayon swabs and the forehead, upper arm, and thigh with separate sponges.

299 mplant (17.58+/-3.13 mU/L) compared with the thigh without implant (9.86+/-1.063 mU/L).

300 ctor CT (six upper extremity wounds and four thigh wounds).