ライフサイエンスコーパス: intraoperative

1 tors on human NSCLC metabolism in vivo using intraoperative (13)C-glucose infusions in nine NSCLC pat

2 0-167 units/patient) were transfused in the intraoperative (1581 units [39.5%]) and postoperative (2

3 Intraoperative (18)F-FDG CLI is a promising, low-risk te

4 Conclusion: Intraoperative (18)F-FDG CLI is a promising, low-risk te

5 d for number of tumors, bilobar disease, and intraoperative ablations.

6 We sought to assess the impact of intraoperative adverse events (iAEs) on 30-day postopera

7 October 2011 and March 2014 from the PIONEER intraoperative and perioperative OCT study were included

8 herence tomography (iOCT) in the Prospective Intraoperative and Perioperative Ophthalmic Imaging with

9 ine myelinolysis patients experienced higher intraoperative and perioperative serum Na/24 hr variatio

10 uge PPV was well tolerated with low rates of intraoperative and postoperative complications across va

11 Group differences in intraoperative and postoperative complications were anal

12 ange in visual acuity (VA) and occurrence of intraoperative and postoperative complications with a mi

13 Secondary end points included intraoperative and postoperative complications, circumfe

14 Outcomes evaluated were intraoperative and postoperative complications, conversi

15 Intraoperative and postoperative complications, device r

16 ms, clinical findings, surgical aspects, and intraoperative and postoperative complications.

17 cell density 12 months postoperatively; and intraoperative and postoperative complications.

18 on, in which there may be increased risk for intraoperative and postoperative complications.

19 ), operative time, patient satisfaction, and intraoperative and postoperative pain ratings.

20 is Review 16 recommendations specific to the intraoperative and postoperative periods.

21 Complications, intraoperative and postoperative, and visual outcomes we

22 sessment, and may represent a novel tool for intraoperative and postsurgical management of conjunctiv

23 The reference standard was the intraoperative and/or histologic diagnosis (in 80 cases)

24 d search terms included "Breast Cancer" AND "Intraoperative" AND "Margin." Only clinical studies with

25 Preoperative, intraoperative, and postoperative parameters of 300 eyes

26 Pretransplant, intraoperative, and posttransplant variables were record

27 easurements differ substantially from direct intraoperative assessment of the aortic annulus.

28 e potential to provide an objective and fast intraoperative assessment of the entire resection surfac

29 otential of Raman spectroscopy for objective intraoperative assessment of the resection margins.

30 G CLI is a promising, low-risk technique for intraoperative assessment of tumor margins in BCS.

31 valuate the feasibility of (18)F-FDG CLI for intraoperative assessment of tumor margins in BCS.

32 G CLI is a promising, low-risk technique for intraoperative assessment of tumor margins in BCS.

33 rinsic contrast could prove decisive for the intraoperative assessment of tumour margins.

34 y, enabling preoperative VR exploration, and intraoperative augmented reality (AR) navigation.

35 Pretransplant and intraoperative bariatric surgeries have been performed,

36 ater MELD scores, length of hospitalization, intraoperative base deficit, incidence of female donors,

37 Intraoperative behavioral responses were used as a secon

38 e variables as well as microbiology data for intraoperative bile and postoperative wound cultures wer

39 ype of microorganisms cultured from both the intraoperative bile and wound infection cultures (Strept

40 ale, multi-institutional study indicate that intraoperative bile cultures should be routinely obtaine

41 Microorganisms isolated in intraoperative bile cultures were similar to those ident

42 erwent cardiovascular magnetic resonance and intraoperative biopsies; 112 had cAS (75+/-6 years; 57%

43 (767 [88.7%]), by men (582 [67.3%]), and for intraoperative bleeding (544 [62.9%]).

44 of the ascending aorta or aortic arch) with intraoperative bleeding (blood volume between 60 and 250

45 Among patients with intraoperative bleeding during high-risk cardiac surgery

46 w neuroembolizing microsphere used to reduce intraoperative bleeding for head and neck tumours.

47 L in high-risk cardiac surgery patients with intraoperative bleeding reduces intraoperative blood los

48 artly restore coagulation defects and reduce intraoperative bleeding.

49 D) = 74 minutes, 95% CI = 29-118], but lower intraoperative blood loss (WMD = -385 mL, 95% CI = -616

50 tic gland texture, pancreatic duct diameter, intraoperative blood loss, pathologic findings of diseas

51 n no significant difference in the amount of intraoperative blood loss.

52 atients with intraoperative bleeding reduces intraoperative blood loss.

53 ypertension (OR 1.44, 95% CI 1.09-1.91), and intraoperative blood transfusion (OR 1.45, 95% CI 1.15-1

54 Laparoscopic DN decreased the need for intraoperative blood transfusion (P < 0.001) and reduced

55 rticosteroid bolus versus those receiving an intraoperative bolus only.

56 ents in arm 2 received no steroids after the intraoperative bolus.

57 emergency or semiurgent repair, and need for intraoperative bowel resection.

58 eed and accurate OCT attenuation mapping for intraoperative brain cancer detection.

59 alysis to clarify the diagnostic accuracy of intraoperative breast margin assessment (IMA) techniques

60 Intraoperative cancer imaging and fluorescence-guided su

61 bes for biomedical research, with a focus on intraoperative cancer imaging via Raman imaging.

62 n patients was also associated with impaired intraoperative cardiac contractility.

63 associations of baroreflex dysfunction with intraoperative cardiac function and outcomes were assess

64 ncreased preoperative assessment, additional intraoperative caution, and postoperative vigilance are

65 occurrence of both outcomes included greater intraoperative central venous pressure and greater trans

66 Historical data including intraoperative characteristics, images, treatment regime

67 equally distributed for all demographic and intraoperative characteristics.

68 ospectively evaluate NIR-C, VR-AR, and x-ray intraoperative cholangiography (IOC) during robotic chol

69 derwent vitrectomy without delamination, the intraoperative complication rate was 13.1% (95% CI, 10.2

70 Intraoperative complication rate was 2.3%, mainly bleedi

71 underwent vitrectomy with delamination, the intraoperative complication rate was 30.4% (95% CI, 26.6

72 iptions of the primary procedures performed, intraoperative complication rate, and proportion of eyes

73 Intraoperative complication rates decreased from 8.4% to

74 Intraoperative complication rates increased with higher

75 Overall rate of any intraoperative complication was 5.0%.

76 ion (P < 0.001) and reduced the incidence of intraoperative complications (P < 0.001) and hospital le

77 e a risk factor for cataract surgery-related intraoperative complications and endophthalmitis.

78 nce, LDN was associated with decreased donor intraoperative complications and hospital length of stay

79 There were no intraoperative complications and no case required conver

80 preoperative consultation, appears to reduce intraoperative complications and support safer surgical

81 There were more intraoperative complications for LRT + SBN (6 vs 0, P =

82 ification for phacoemulsification surgery on intraoperative complications in a teaching hospital.

83 Intraoperative complications included loss of suction (n

84 Intraoperative complications increased with increasing M

85 This study confirms that the risk of intraoperative complications increases with higher preop

86 No intraoperative complications or unexpected postoperative

87 resses and oversewing, and the occurrence of intraoperative complications were associated with a sign

88 Patients with intraoperative complications were excluded from analysis

89 No intraoperative complications were recorded.

90 Intraoperative complications were reported for 69 eyes (

91 Intraoperative complications were subconjunctival hemorr

92 eline features, intraoperative surgery time, intraoperative complications, and incidence of unplanned

93 e measures were intraoperative surgery time, intraoperative complications, postoperative complication

94 prespecified secondary end points, including intraoperative complications, postoperative complication

95 had abdominal aortic aneurysm-repair without intraoperative complications, postoperative surgical com

96 Patient outcomes were evaluated using intraoperative complications, short-term morbidity, long

97 e presence or absence of a specified list of intraoperative complications.

98 We simulated an intraoperative consultation for 25 patients with specime

99 cement of glioblastoma multiforme (GBM) with intraoperative contrast-enhanced ultrasonography (US) ve

100 ng et al. (2016) employ a novel technique of intraoperative cortical cooling in humans during speech

101 corticosteroids tapered over 10 days plus an intraoperative corticosteroid bolus versus those receivi

102 iximab, mycophenolate mofetil and 1 bolus of intraoperative corticosteroids (0-1000 mg) as per center

103 We retrospectively reviewed clinical and intraoperative data of 45 children with idiopathic EHPVT

104 Donor, recipient, and intraoperative data were investigated.

105 age functional MR imaging when compared with intraoperative DCS, and the included studies displayed s

106 No intraoperative deaths occurred.

107 More complex topics, including intraoperative decision making (mean, 9.70 vs 2.77 insta

108 for pancreatic cancer; however, in practice intraoperative delineation of resection margins is chall

109 Intraoperative DESI-MS analysis of tissue smears, ex viv

110 lts lay the foundation for implementation of intraoperative DESI-MS evaluation of tissue smears for r

111 Intraoperative DESI-MS measurements made at surgeon-defi

112 Intraoperative desorption electrospray ionization-mass s

113 These results open new opportunities for intraoperative detection and fluorescence-guided resecti

114 -PSMA) PET/CT, allowing for their successful intraoperative detection and resection during first-in-h

115 )-HBED-CC ((68)Ga-PSMA-11) to allow accurate intraoperative detection of PSMA-positive tumors.

116 anocept allows for PET imaging and real-time intraoperative detection of SLNs during robotic surgery.

117 Intraoperative detection of tumorous tissue is an import

118 This has led to the development of intraoperative detectors that can image radiotracers acc

119 The primary hypothesis tested was that intraoperative dexmedetomidine administration would redu

120 Intraoperative dexmedetomidine does not prevent postoper

121 ctive value (99%) to render it useful for an intraoperative diagnosis of cancer.

122 evaluate the capacity of SRH for use in the intraoperative diagnosis of pediatric type brain tumors.

123 od loss, pathologic findings of disease, and intraoperative drain placement.

124 Intraoperative dual-modality imaging can help the surgeo

125 rface fluid segmentation algorithm evaluated intraoperative dynamics of interface fluid before and af

126 for tailoring epilepsy surgery with repeated intraoperative ECoG measurements.

127 ces, and national regulations that influence intraoperative education have the potential to significa

128 Intraoperative electrocorticography (ECoG) can be used t

129 d by either stereo-electroencephalography or intraoperative electrocorticography.

130 ectrodiagnostic information, supplemented by intraoperative electrophysiological studies.

131 incidence of bowel intervention, defined as intraoperative enterotomy, suture repair of intestine, o

132 METHODS AND Intraoperative epicardial mapping (interelectrode distan

133 expertise is available, if preoperative and intraoperative evaluation demonstrates favorable anatomy

134 earch should consider these preoperative and intraoperative factors along with conventional ACS-NSQIP

135 Similarly, including intraoperative features (AUC = 0.82; 95% CI: 0.66-0.94)

136 By using intraoperative features, performance improved significan

137 nt in the operating room: optimizing faculty intraoperative feedback; policies and regulations affect

138 Discordance between preoperative 4D-CTs and intraoperative findings in the number and location of ab

139 discordance between preoperative 4D-CTs and intraoperative findings, followed by parathyroid lesion

140 2008-2015), in correlation with clinical and intraoperative findings.

141 discordance between preoperative 4D-CTs and intraoperative findings.

142 Mean intraoperative fluid (IOF) rate was 15.7 (IQR, 11.3-18.7

143 To investigate the association of intraoperative fluid administration and morbidity in pat

144 Intraoperative fluid administration is associated with a

145 Hospitals' approaches to intraoperative fluid administration vary widely, and the

146 We computed intraoperative fluid balance, accounting for patient mor

147 ss the variation in hospitals' approaches to intraoperative fluid management and their association wi

148 Morbidity associated with intraoperative fluid management calculated by the compre

149 ptake, pharmacokinetics, and feasibility for intraoperative fluorescence guidance were investigated i

150 specifically, small studies have shown that intraoperative fluorescence imaging is a safe and feasib

151 Intraoperative fluorescence imaging is emerging as a hig

152 f this study was to test the hypothesis that intraoperative frozen section (FS) and re-resection resu

153 In this study, we tested the hypothesis that intraoperative functional magnetic resonance imaging cou

154 g elective major abdominal surgery comparing intraoperative GDFT versus conventional fluid therapy.

155 ternal mammary artery and radial artery use; intraoperative graft assessment; minimally invasive proc

156 y probes combining preoperative imaging with intraoperative guidance is of high clinical relevance an

157 onsideration should be given to increase the intraoperative HA flow to prevent biliary strictures in

158 Intraoperative HAT (odds ratio, 62.63; 95% confidence in

159 o-recipient weight ratio of 1.1% or less and intraoperative HAT were independently associated with HA

160 al Hb trigger as transfusion of PRBCs for an intraoperative Hb level of 10 g/dL or greater or a posto

161 We show how archiving and mining of intraoperative hemodynamic data in orthotopic liver tran

162 We conclude that inclusion of intraoperative hemodynamic features significantly improv

163 s from clinical records and 41 features from intraoperative hemodynamic signals.

164 Cv-PC SBI animals had significantly reduced intraoperative hemorrhage and postoperative hematoma vol

165 blood cell transfusions were associated with intraoperative HF.

166 In patients having surgery, intraoperative high driving pressure and changes in the

167 l label-free imaging technique that provides intraoperative histologic images of fresh, unprocessed s

168 Current methods for intraoperative histology are time- and labor-intensive a

169 Intraoperative hypotension does not seem to be a clinica

170 assessed to be appropriate included pre- and intraoperative hypothermia (median temperature <34 degre

171 Unintentional intraoperative hypothermia is a well-described risk fact

172 patients (29%), the surgery was modified by intraoperative ICG-FI, which detected additional PM not

173 is novel hybrid peptide for preoperative and intraoperative imaging of NET.

174 mally because of a combination of iatrogenic intraoperative implant damage and incorrect implantation

175 The comparison of intraoperative implanted to a theoretical transcatheter

176 To evaluate whether an intraoperative infusion of dexmedetomidine reduces posto

177 e role of fluorescence imaging (FI) using an intraoperative injection of free indocyanine green (ICG)

178 rs that faculty and residents exhibit during intraoperative interactions, which support or inhibit pr

179 To correlate intraoperative interface fluid dynamics during Descemet

180 negative control patients, underwent direct intraoperative intracranial pressure measurement.

181 A single intraoperative IV dose of dexamethasone or placebo was a

182 uring cancer surgery, we designed an in situ intraoperative, label-free, optical cancer detection sys

183 ovel and feasible modality for supplementing intraoperative learning.

184 After placement and optimization of intraoperative lenticle adherence, iOCT revealed a signi

185 0.181-0.842); P = 0.017] and the absence of intraoperative lidocaine intravenous perfusion (odds rat

186 Intraoperative liver biopsies were categorized with NAFL

187 Intraoperative localization and histologic results were

188 common in patients who had longer periods of intraoperative low blood pressure.

189 liminated SAM and consequently decreased the intraoperative LVOT gradient (91 +/- 44 mm Hg to 12 +/-

190 Using real-time intraoperative magnetic resonance imaging-guided convect

191 tion related to preoperative organ function, intraoperative management, surgical approach, transfusio

192 Intraoperative mapping of the endo- and epicardial right

193 and the patient subsequently underwent awake intraoperative mapping using direct electrical stimulati

194 quipment make CLI a promising technology for intraoperative margin assessment.

195 The value was compared with the intraoperative measurement obtained with calipers.

196 AS-OCT measurements were within 1 mm of intraoperative measurements in 77% of all muscles.

197 For the control group, traditional intraoperative measurements were used without genioplast

198 y in repositioning the chin than traditional intraoperative measurements, and the computerized plan c

199 Agreement between preoperative AS-OCT and intraoperative measurements.

200 To determine if intraoperative molecular imaging (IMI) can improve detec

201 ynthesized into 123 unique pre- (n = 36) and intraoperative (n = 87) indications.

202 With regard to intraoperative navigation, a specific fluorescence signa

203 to improve surgical outcomes by facilitating intraoperative nerve identification, reducing accidental

204 Results No intraoperative neurologic complications (n = 10 [95% con

205 er chronic DBS that could be used to improve intraoperative neurophysiological target mapping during

206 ns with a powerful and versatile arsenal for intraoperative NIR imaging in real time.

207 The Intraoperative Norepinephrine to Control Arterial Pressu

208 d observations, a surgeon educator conducted intraoperative observations, which served as the basis f

209 Intraoperative ocular AEs included 119 (0.55%) cases of

210 t of a Raman portable fiber probe device for intraoperative optical biopsy, both to improve the surgi

211 mated endothelial keratoplasty (DSAEK) using intraoperative optical coherence tomography (iOCT) in th

212 Intraoperative optical coherence tomography (OCT) has ga

213 Our purpose was to analyse intraoperative optical coherence tomography data (iOCT)

214 modal ligand for noninvasive PET imaging and intraoperative optical imaging of GRPr-expressing malign

215 There were no life- or vision-threatening intraoperative or perioperative AEs.

216 g and suggest that XRD could be used for the intraoperative or postoperative classification of bulk t

217 models, sclerostomy decreased the odds of an intraoperative or postoperative complication by 80% (odd

218 l patients tolerated the surgery well and no intraoperative or postoperative complications were repor

219 ansfusion of greater than 4 units during the intraoperative or postoperative setting, were excluded.

220 ectively reviewed operative characteristics, intraoperative parameters, and postoperative outcomes.

221 For minimally invasive parathyroidectomy, intraoperative parathyroid hormone monitoring via a reli

222 An intraoperative pathological examination was performed an

223 mpared with preoperative Pe (P < 0.0001) and intraoperative Pe (P < 0.001) blood.

224 However, data regarding the use of intraoperative PEEP is conflicting.

225 Intraoperative perforation seems to be an important risk

226 e considered in selected patients at risk of intraoperative perforation.

227 ith donor weight of >/= 5 kg; P < .01), with intraoperative perfusional concern (10 of 21 vs seven of

228 Herein, we present a near-infrared virtual intraoperative photoacoustic optical coherence tomograph

229 Low portal vein area index and intraoperative portal blood inflow may be negative progn

230 Measured intraoperative portal blood inflow was the only signific

231 ute POE 0.53 (0.50-0.57; P < 0.001), whereas intraoperative posterior capsule rupture, combined surge

232 s association was no longer significant when intraoperative/postoperative prognostic variables were a

233 nalyzed on the preoperative characteristics, intraoperative procedures, and postoperative course.

234 nd precisely detect and remove MRD in simple intraoperative procedures.

235 ) in preoperative peripheral blood (PPB) and intraoperative pulmonary venous blood (IPVB) could predi

236 el for angle surgeries and the absence of an intraoperative quantification of surgical success.

237 7]); prediction was improved by inclusion of intraoperative (R 9.0%, c-statistic 0.69) and postoperat

238 FS analysis with intraoperative re-resection should be performed routinel

239 Additional determinants were: age, mild intraoperative residual MR, anterior leaflet prolapse, b

240 Incidence, prevalence, preoperative and intraoperative risk factors for enhancement, and outcome

241 vity analyses stratified by preoperative and intraoperative risk factors.

242 detachment surgery, and 11% of cases develop intraoperative scleral perforation or retinal redetachme

243 Intraoperative scleral perforation or retinal redetachme

244 CASE PRESENTATION: Intraoperative spectral domain optical coherent tomograp

245 hyrin IX fluorescence in vivo, together with intraoperative spectroscopic data obtained from both ani

246 For detection specificity, intraoperative spectroscopy allows the differentiation o

247 The results indicate that intraoperative spectroscopy is at least 3 orders of magn

248 udied non-motor decision making by recording intraoperative STN and prefrontal cortex (PFC) electroph

249 These results lay the foundation for future intraoperative studies.

250 The intraoperative subtraction pachymetry (the SP 100 Handy

251 eoperative astigmatism more than 3.00 D, and intraoperative suction loss were significant risk factor

252 operative astigmatism, and the occurrence of intraoperative suction loss.

253 Conclusion Intraoperative supine breast MR imaging, when performed

254 Purpose To use intraoperative supine magnetic resonance (MR) imaging to

255 tients underwent lumpectomy and postsurgical intraoperative supine MR imaging.

256 ent groups with regard to baseline features, intraoperative surgery time, intraoperative complication

257 Secondary outcome measures were intraoperative surgery time, intraoperative complication

258 ioactive signal might be clinically used for intraoperative surgery.

259 the quality, confidence, and consistency of intraoperative surgical decision making (DM) and using f

260 ibed methodology could be routinely used for intraoperative surgical margin assessment of pancreatic

261 this study was to investigate the effect of intraoperative targeted stretching micro breaks (TSMBs)

262 this study was to investigate the effect of intraoperative targeted stretching micro breaks (TSMBs)

263 digms designed to provide best practices for intraoperative teaching agree that effective teaching sp

264 e impact on trainee ratings of their faculty intraoperative teaching performance.

265 entify characteristics and themes related to intraoperative teaching that will better inform interven

266 riculum consisting of preoperative training, intraoperative teaching, postoperative feedback, and rep

267 w studies (n = 5) examined interventions for intraoperative teaching, these studies demonstrate the e

268 what patient outcomes were assessed, and how intraoperative technical performance affected patient ou

269 robust research is needed to directly assess intraoperative technical performance and its effect on p

270 Systematic review of the effect of intraoperative technical performance on patient outcomes

271 At present, all intraoperative techniques significantly increase surgica

272 explored, including temperature nadir, mean intraoperative temperature, percentage of time at the te

273 gitudinal tract imaging, in combination with intraoperative testing and neuropsychological evaluation

274 ye Center in the late 1980s; the first human intraoperative tests there and the subsequent 8 years of

275 iOCT images were also captured at multiple intraoperative time points for 2 different DSAEK techniq

276 trometry (REIMS) technology allows real time intraoperative tissue classification and the characteriz

277 the RS group), and in estimated blood loss, intraoperative transfusion, length of stay, and postoper

278 ation technique in preoperative planning and intraoperative troubleshooting.

279 Intraoperative TSMB may represent a practical, effective

280 Intraoperative TSMB may represent a practical, effective

281 (n = 9); cytology = 91%, 95%, 0.98 (n = 11); intraoperative ultrasound = 59%, 81%, 0.78 (n = 4); spec

282 Intraoperative ultrasound biomicroscopy performed at the

283 A further application scenario would be intraoperative ultrasound examination displaying the ima

284 with use of fusion imaging between real-time intraoperative US and preoperative MR imaging.

285 ents underwent tumor excision with navigated intraoperative US guidance with use of fusion imaging be

286 hieved in less than 15 minutes for potential intraoperative use in guiding breast-conserving surgerie

287 However, intraoperative use of dexmedetomidine for prevention of

288 Intraoperative use of higher inhalational anesthetic dos

289 In particular, the intraoperative use of quantitative OCT is able to provid

290 We hypothesized that direct intraoperative valve sizing results in smaller aortic an

291 toperative LOS, controlling for preoperative/intraoperative variables (eg, age, comorbidities, ASA, w

292 The accuracy of E-PASS using intraoperative variables and its modified form that can

293 aphics, transfer status, type of repair, and intraoperative variables were recorded.

294 nonvascular surgery procedures that required intraoperative vascular surgery assistance between Janua

295 Exposures: Intraoperative vascular surgery assistance stratified by

296 ibe the broad spectrum of cases that require intraoperative vascular surgery assistance.

297 e level of PEEP, and driving pressure during intraoperative ventilation with the development of posto

298 A) induced protoporphyrin IX (PpIX) provides intraoperative visual contrast between normal and malign

299 ion system (GAINS) that can provide accurate intraoperative visualization of tumors and sentinel lymp

300 ed miniature needle probes that could enable intraoperative volume imaging with optical coherence tom