ライフサイエンスコーパス: oximetry

1 eremia with magnetic resonance imaging-based oximetry.

2 linical application of multiwavelength pulse oximetry.

3 heter) and correlated with microdialysis and oximetry.

4 measured by electron paramagnetic resonance oximetry.

5 e analysis of cellular respiration using EPR oximetry.

6 ion to quantify related parameters using EPR oximetry.

7 bor to either "open" or "masked" fetal pulse oximetry.

8 monitored by electron paramagnetic resonance oximetry.

9 roscopy and of O2 consumption by fiber-optic oximetry.

10 ls and their mutants was investigated by EPR oximetry.

11 ith transcranial doppler and overnight pulse oximetry.

12 obin plus reduced hemoglobin) measured by co-oximetry.

13 ially detectable through screening via pulse oximetry.

14 rophysiological activity, pulse and cerebral oximetry.

15 or clinical acquisition of images in retinal oximetry.

16 n measurements using dual-wavelength retinal oximetry.

17 Test if a novel panel consisting of pulse oximetry, 12-lead electrocardiography, and serum troponi

18 .9; p<0.001), as was use of continuous pulse oximetry (78% vs. 58%, respectively; p=0.001).

19 nd favourable cost-effectiveness makes pulse oximetry a promising candidate for improving the prognos

20 nea using questionnaire plus nocturnal pulse oximetry against using polysomnography to identify patie

21 One-third of pulse oximetry alarm notifications were for clinically relevan

22 Provision of more reliable oximetry allows caregivers to act in a more efficient an

23 Cerebral oximetry allows real-time, noninvasive cerebral oxygenat

24 If we avoided oximetry altogether, then symptoms together with body ma

25 In-depth oximetry analysis demonstrated that functions of mitocho

26 e in vivo by electron paramagnetic resonance oximetry and (19)fluorine-MRI relaxometry.

27 itude underwent echocardiography, finger-tip oximetry and blood measurements of cardiac troponin I (c

28 Jugular oximetry and brain tissue oxygen pressure monitoring are

29 Cardiac monitoring, pulse oximetry and capnography are used, often without strong

30 (SaO(2)) and superior vena caval (SvO(2)) co-oximetry and cerebral oxygen saturation (ScO(2)) measure

31 tal admission, particularly the use of pulse oximetry and chest radiography.

32 ith the medium-throughput plate reader-based oximetry and EPR spin trapping as confirmatory assays, i

33 dissolved in hexafluorobenzene, for in vivo oximetry and imaging of oxygen concentration in tissues

34 y publications addressing knowledge of pulse oximetry and those warning against the use of transmissi

35 p apnea symptom questionnaire, and underwent oximetry and two-night polysomnography.

36 pected of bacterial pneumonia, bedside pulse oximetry and urinary antigen testing for Streptococcus p

37 electrocardiogram), oxygen saturation (pulse oximetry), and brachial artery blood flow and shear rate

38 and standard vital signs (heart rate, pulse oximetry, and body temperature) were monitored at regula

39 s the oxygen saturation as measured by pulse oximetry, and DLCO is the diffusing capacity for carbon

40 ery pressure, central venous pressure, pulse oximetry, and end-tidal CO(2) were continuously monitore

41 lower Glasgow Coma Scale score, lower pulse oximetry, and nursing home residence during out-of-hospi

42 UV-visible spectroscopy, electrode oximetry, and pH stat were used to study Fe(II) oxidatio

43 Blood pressure, electrocardiography, oximetry, and symptoms were monitored by a nurse with ex

44 Blood pressure, ECG, oximetry, and symptoms were monitored.

45 n arterial blood pressure, heart rate, pulse oximetry, and transcutaneous oxygen and carbon dioxide t

46 Simultaneous blood gas, pulse oximetry, and ventilator settings were collected.

47 Nadir oxygen saturation as measured by pulse oximetry, apnea-hypopnea index, and the fraction of even

48 sensors offer great potential for future EPR oximetry applications in preclinical research.

49 on to assess the impact of introducing pulse oximetry as a prognostic tool to distinguish severe from

50 We assessed the performance of pulse oximetry as a screening method for the detection of crit

51 The concept of using pulse oximetry as a screening method to detect undiagnosed cri

52 prospectively assessed the accuracy of pulse oximetry as a screening test for congenital heart defect

53 ncluding the introduction of universal pulse oximetry at a hospital in Chisinau, Moldova, where only

54 safety checklist and the provision of pulse oximetry at a referral hospital in Moldova, a lower-midd

55 e of 0.79 (95% CI, 0.67-0.93) for peripheral oximetry at the instant the vital sign first crossed thr

56 Determination of pulse co-oximetry-based hemoglobin in patients presenting with se

57 ing to the development of new types of pulse oximetry-based monitoring techniques.

58 estation >34 weeks) were screened with pulse oximetry before discharge.

59 recent years to expand the utility of pulse oximetry beyond the simple measurement of arterial oxyge

60 s can discern clinically relevant peripheral oximetry, blood pressure, and respiratory rate alerts fr

61 Oximetry by near infrared spectroscopy reflects the bala

62 Pulse oximetry can be used reliably to estimate the arterial o

63 Pulse oximetry can significantly increase the incidence of cor

64 acity of the lung for carbon monoxide, pulse oximetry, chest radiograph, and high-resolution thoracic

65 arrest while undergoing continuous cerebral oximetry, clearly demonstrated the ability of the INVOS

66 mination of the pulmonary circulation, pulse oximetry, complete blood count, and serum chemistries an

67 th two oximeters, one employing conventional oximetry (conventional pulse oximeter, CPO) and one usin

68 Pulse oximetry correlates well with cooximeter-measured satura

69 data, reproducing the shapes of experimental oximetry curves with high accuracy.

70 Pulse oximetry data from 54 countries suggested that around 77

71 ate and meaningful model to evaluate the EPR oximetry data on cellular respiration to quantify relate

72 onsumption calculated using combined CMR and oximetry data was 173 mL/min per m(2), higher than the a

73 lasting 2 minutes or longer per 100 hours of oximetry decreased from 11.5 to 6.4 (P < 0.002).

74 EPR oximetry demonstrated that the ischemic wound tissue had

75 sought to quantitatively define the error in oximetry-derived flow parameters using phase-contrast ca

76 epatopulmonary syndrome underwent home pulse-oximetry during sleep.

77 erial hemoglobin oxygen saturation (by pulse oximetry), end-tidal PCO2, and carotid artery blood flow

78 ir readiness and reported that all had pulse oximetry equipment onsite and 74.4% had access to same-d

79 ithm using questionnaire and nocturnal pulse oximetry excluded few patients from sleep studies, but i

80 us body mass index for everyone, followed by oximetry for a subset; and (5) oximetry for all.

81 , followed by oximetry for a subset; and (5) oximetry for all.

82 was the sensitivity and specificity of pulse oximetry for detection of critical congenital heart defe

83 The overall sensitivity of pulse oximetry for detection of critical congenital heart defe

84 studies that assessed the accuracy of pulse oximetry for the detection of critical congenital heart

85 llow-up group to 6.8 events per 100 hours of oximetry for the long-term follow-up group; P = .10).

86 o decrease (from 8.1 events per 100 hours of oximetry for the short-term follow-up group to 6.8 event

87 x conditions was combined with multispectral oximetry for two-dimensional oxygen saturation mapping.

88 his effort include the extension of cerebral oximetry from the operating room into the critical care

89 y group and 15 of 105 (14.3%) in the altered oximetry group (difference, 7% [95% CI, -0.3% to 0.2%];

90 medical visits for bronchiolitis in the true oximetry group and 15 of 105 (14.3%) in the altered oxim

91 Forty-four of 108 patients (41%) in the true oximetry group and 26 of 105 (25%) in the altered oximet

92 try group and 26 of 105 (25%) in the altered oximetry group were hospitalized within 72 hours (differ

93 nadir oxygen saturation as measured by pulse oximetry >82.5%) + (Fhypopneas >58.3%).

94 Routine use of pulse oximetry has been associated with changes in bronchiolit

95 Reliance on pulse oximetry has been associated with increased hospitalizat

96 Tissue oximetry has been suggested as a noninvasive tool to con

97 ssuming access to supplemental oxygen, pulse oximetry has the potential to avert up to 148,000 deaths

98 erimental sensors based on reflectance pulse oximetry have been developed for use in internal sites s

99 ission tomography (15O PET) and brain tissue oximetry have demonstrated increased oxygen diffusion gr

100 Recent advances in pulse oximetry have made it possible to noninvasively measure

101 from the green channel of a dual wavelength oximetry image.

102 al vessel calibre measurements obtained from oximetry images are in good agreement to those obtained

103 s for universal CCHD screening through pulse oximetry in birth hospitals.

104 vo by darkfield microscopy and multispectral oximetry in experimental murine models of ALI induced by

105 , which, as determined by magnetic resonance oximetry in live mice, was accompanied by a correspondin

106 ured by a clinical severity score, and pulse oximetry in room air was done.

107 luate the use of noninvasive cerebral tissue oximetry in the care of children with severe anemia.

108 To assess the accuracy of pulse oximetry in the diagnosis of hypoxemia in SCD, we compar

109 using electron paramagnetic resonance (EPR) oximetry in the forebrain of rats under isoflurane, keta

110 gh the increased cost of bronchodilators and oximetry in these patients may serve as target areas for

111 diabetic ketoacidosis and, along with pulse oximetry, in lung-function laboratories to estimate bloo

112 lls showed reduced mitochondrial function by oximetry, including a reduction in maximal respiratory c

113 the lower limit of autoregulation, cerebral oximetry index approaches 1, because cerebral blood flow

114 Monitoring cerebral oximetry index may provide a novel method for precisely

115 py signals to generate the variable cerebral oximetry index.

116 The integration of cerebral oximetry into cardiac arrest resuscitation provides a no

117 Cerebral oximetry is a complimentary monitoring modality during s

118 Magnetic resonance imaging-based oximetry is a new calibration-free technique taking adva

119 Measurement of the SMV %HbO2 with MR oximetry is a promising test for diagnosis of chronic me

120 Pulse oximetry is a safe, feasible test that adds value to exi

121 Pulse oximetry is a ubiquitous non-invasive medical sensing me

122 Routine screening for CCHD using pulse oximetry is being increasingly supported and was added t

123 Electron paramagnetic resonance (EPR) oximetry is being widely used to measure the oxygen cons

124 INTERPRETATION: Pulse oximetry is highly specific for detection of critical co

125 Given pulse oximetry is increasingly substituting for arterial blood

126 Pulse oximetry is ubiquitous but detailed understanding of the

127 ement of total hemoglobin, based on pulse co-oximetry, is a continuous and noninvasive method that ha

128 Along with pulse oximetry, it has reduced anesthesia-related morbidity an

129 Vital signs, pulse oximetry, laser Doppler flowmetry, and toe temperature w

130 re- and postprandial magnetic resonance (MR) oximetry measurements of the SMV %HbO2, with flow-indepe

131 EPR oximetry measurements show ketamine increases cortical P

132 mittent pulse oximetry monitoring (ie, pulse oximetry measurements were obtained along with a schedul

133 Pulse oximetry measurements with true saturation values displa

134 spin trapping with DEPMPO together with EPR oximetry methods can be used to provide sensitive and sp

135 to undergo continuous or intermittent pulse oximetry monitoring (ie, pulse oximetry measurements wer

136 Our results suggest that intermittent pulse oximetry monitoring can be routinely considered in the m

137 Continuous pulse oximetry monitoring is recommended to improve safety dur

138 Intermittent pulse oximetry monitoring of nonhypoxemic patients with bronch

139 length of stay did not differ based on pulse oximetry monitoring strategy (48.9 hours [95% CI, 41.3-5

140 Comparison with brain tissue oximetry monitoring suggested that the threshold for inc

141 orted routine use of blood pressure or pulse oximetry monitoring, and 75% reported daily rounds were

142 Side effects were monitored by pulse oximetry, nasal end-tidal capnography, and serial blood

143 ression model was used to estimate the pulse oximetry need for countries that did not provide data.

144 aturation measurements using dual-wavelength oximetry, noncontact tonometry, and manual sphygmomanome

145 tient clinics lack capacity to conduct pulse oximetry, nutritional assessment, or HIV testing, then w

146 ansplantation underwent endobronchial tissue oximetry of native and donor bronchi at 0, 3, and 30 day

147 systemic hypoxia (85 % O2 saturation; pulse oximetry of the earlobe).

148 were no differences in laser Doppler, pulse oximetry, or toe temperature measurements during or afte

149 Oximetry overestimated systemic blood flow (Qs) by an av

150 ore, respiratory rate, heart rate, and pulse oximetry oxygen saturation values were recorded at basel

151 , metered dose inhalers (p = .01), and pulse oximetry (p = .02).

152 arterial blood gas monitoring, chemistry, co-oximetry panels, parathyroid hormone assays, and coagula

153 Cerebral microdialysis, brain tissue oximetry (PbO2), and oxygen-15 positron emission tomogra

154 H(2)O(2) as oxidant was studied by electrode oximetry, pH-stat, UV-visible spectrophotometry, and ele

155 Electrode oximetry/pH stat was used to study iron oxidation and hy

156 agnosis (biomarkers and intraoperative renal oximetry), prevention (statin therapy, acetylsalicylic a

157 ong with the use of a biocompatible charcoal oximetry-probe suspension, enabled 3D spatial imaging of

158 ls show great potential as intracellular EPR oximetry probes and imaging agents.

159 ylmethyl (TAM) radicals are commonly used as oximetry probes for electron paramagnetic resonance imag

160 Cerebral oximetry provided real-time information regarding the qu

161 ses were done on all babies for whom a pulse oximetry reading was obtained.

162 s, those with an artificially elevated pulse oximetry reading were less likely to be hospitalized wit

163 obtaining intermittent or "spot check" pulse oximetry readings for those who show clinical improvemen

164 flow showed no perfusion in the infarct, and oximetry readings were between 60 and 65.

165 In the second case, oximetry readings were obtained in a patient with a righ

166 more than 6 hours than those with unaltered oximetry readings.

167 ta (heart rate, respiratory rate, peripheral oximetry) recorded on all admissions at 1/20 Hz, and non

168 of 100 Hz we decomposed the raw signal in an oximetry recording (<1 Hz) and LFP recording (>1 Hz), de

169 ta collected included all preoperative pulse oximetry recordings, all values from preoperative arteri

170 weak areas in ICU monitoring, such as pulse oximetry reliability.

171 ults: Of 128 children included in the study, oximetry results in 8 cases were excluded owing to motio

172 Results of pulse co-oximetry revealed that the mean carboxyhemoglobin level

173 spectrometry, UV spectrometry, and electrode oximetry revealed that the mineral core forms by at leas

174 (3) usually, an associated decline in pulse oximetry saturation.

175 access to postdischarge newborn care, pulse oximetry screening for congenital heart disease, and cir

176 Pulse oximetry screening for cyanotic congenital heart disease

177 f clinicians felt the case for routine pulse oximetry screening had not been proven.

178 Pulse oximetry screening is a highly specific, moderately sens

179 Pulse oximetry screening should be routine and performed at th

180 reporting the test accuracy of routine pulse oximetry screening, and involving over 150 ,000 babies,

181 Reflectance oximetry sensors are distinct and their application rath

182 s the development of novel reflectance pulse oximetry sensors for the esophagus and bowel, and presen

183 The use of novel reflectance pulse oximetry sensors has been successfully demonstrated.

184 Furthermore, electron paramagnetic resonance oximetry showed a gradual but significant reduction in c

185 Measurements using spin label oximetry showed a substantial difference in the level of

186 Pulse oximetry showed oxygen desaturations below 90% in 101 (3

187 Pulse oximetry significantly underestimates true arterial satu

188 Pulse oximetry slightly overestimated oxyhemoglobin percentage

189 aturation of hemoglobin as measured by pulse oximetry (Spo(2)) were monitored continuously throughout

190 rcise oxygen saturation as measured by pulse oximetry [Spo(2)] = 86.5 +/- 2.9%) participated.

191 m score, multi-slice CT, perfusion CT, pulse oximetry (SpO2%), and hemoglobin concentration (Hb).

192 s study, blood oxygen saturation using pulse oximetry (SpO2) and pulse rate were measured daily on a

193 when oxygen saturation as measured by pulse oximetry (SpO2) dropped to less than 84%, or after 60 mi

194 arget oxygen saturation as measured by pulse oximetry (SpO2) of 88-92% (n = 52) or a liberal oxygenat

195 ration (arterial [SaO2] or measured by pulse oximetry [SpO2]) </= 90%.

196 xyhemoglobin saturation as measured by pulse oximetry [Spo2], 89 to 93%).

197 gies including continuous superior vena cava oximetry (SvO2), phenoxybenzamine (POB), strategies to m

198 EPR (ESR) is a suitable noninvasive oximetry technique.

199 act on clinical care of improved, innovative oximetry technology.

200 itoring, advances in intrapartum fetal pulse oximetry, thresholds of acidosis associated with fetal i

201 ity, and positive predictive value of tissue oximetry to detect systemic hypoperfusion, multisite NIR

202 mating cardiac output; b) the standard pulse oximetry to screen for pulmonary problems; c) transcutan

203 s to titrate arterial O(2) saturation (pulse oximetry) to 80%, while remaining normocapnic via a rebr

204 Jugular venous bulb oximetry, transcranial Doppler ultrasonography, electroe

205 The cardiac index, pulse oximetry, transcutaneous oxygen tension, transcutaneous

206 Oximetry underestimated CMR-measured pulmonary blood flo

207 in from sublingual mucosa correlated with co-oximetry values of blood withdrawn from a central venous

208 and routinely assessed in patients by pulse oximetry, variability at the single-cell level has not b

209 With the exception of pulse oximetry vital sign days, the readings in most vital sig

210 arterial blood pressure, cerebral perfusion/oximetry, VT characteristics, and ablation outcomes.

211 Sensitivity of pulse oximetry was 75.00% (95% CI 53.29-90.23) for critical ca

212 congenital heart disease (CCHD) using pulse oximetry was added to the recommended uniform screening

213 ects was particularly low when newborn pulse oximetry was done after 24 h from birth than when it was

214 Neuromonitoring using cerebral oximetry was performed to evaluate a cerebral desaturati

215 label electron paramagnetic resonance (EPR) oximetry was used to measure the oxygen consumption from

216 caval (SsvcO2), and pulmonary venous (SpvO2) oximetry was used to test whether SaO2 accurately predic

217 not be done with reasonable accuracy unless oximetry was used.

218 inhibition.Oxyhaemoglobin saturation (pulse oximetry) was decreased (P<0.001) with hypoxia (63 +/- 2

219 The mean hemoglobin concentration, by co-oximetry, was 5.014 mmol x L(-1), coefficient of variati

220 Using electron paramagnetic resonance oximetry, we have observed an initial fast decrease of p

221 To estimate availability of pulse oximetry, we sent surveys to anaesthesia providers in 72

222 oxygen extraction fraction, and brain tissue oximetry were measured in patients during [18F]FMISO and

223 e Louise AMS score, and Sao2 level (by pulse oximetry) were measured.

224 This strategy was comparable in accuracy to oximetry, which had a negative likelihood ratio of 0.12,

225 res and quantified the availability of pulse oximetry, which is an essential monitoring device during

226 Oxygen saturation was monitored by pulse oximetry, which recorded the number of times saturation

227 ygen saturation (SaO2) was measured by pulse oximetry while children were awake and asleep.

228 se contrast angiography and pre-ductal pulse oximetry, while regional cerebral oxygen saturation was

229 developments and applications of reflectance oximetry with an emphasis on the potential clinical and

230 We also found that the combination of pulse oximetry with integrated management of childhood illness