ライフサイエンスコーパス: arterial blood

1 ohemoglobin was higher in venous compared to arterial blood.

2 .72), or partial carbon-dioxide pressure in arterial blood (-0.3 mm Hg; 95% CI, -0.8 to 0.2 mm Hg; P

3 Brain injury was induced by autologous arterial blood (30 mul) or thrombin (5 U) injection into

4 ICH was induced by injecting autologous arterial blood (30mul) into a mouse brain.

5 s that die after successful reperfusion with arterial blood actually are killed by changes initiated

6 cirrhosis itself and how they may relate to arterial blood ammonia concentration and cerebral metabo

7 Arterial blood ammonia concentration decreased 20% after

8 Samples were taken from arterial blood and urine, and the occurrence of radioact

9 ned with arterial blood as input and without arterial blood as input (cerebellum as reference).

10 R) measurements (35-90 min), determined with arterial blood as input and without arterial blood as in

11 the infarct area started to exceed those of arterial blood at 5-10 min after contrast injection, and

12 Arterial blood CO2 tension when increased by 25 mm Hg ca

13 heral venous Abeta concentration compared to arterial blood concentration.

14 whose activities are regulated by changes in arterial blood content, including oxygen.

15 With arterial blood data, brain uptake was quantified with co

16 stimulate breathing when oxygenation of the arterial blood decreases; and pulmonary arterial smooth

17 by the level of impaired O2 extraction from arterial blood during peak exercise.

18 trated by observations of faster recovery of arterial blood flow and large numbers of newly formed ar

19 serelaxin for 120 min increased total renal arterial blood flow by 65% (95% CI 40%, 95%; p < 0.001)

20 There was no significant difference in arterial blood flow measured with Bayesian multipoint ve

21 The arterial blood flow that underlies the stigmata rarely i

22 e the tumor, while maintaining uninterrupted arterial blood flow to the uninvolved kidney.

23 In IUGR baboons there was increased carotid arterial blood flow velocity during late systole and dia

24 , deep-tissue and ultrafast imaging of mouse arterial blood flow with an unprecedented frame rate of

25 adhesion to disrupted vascular surface under arterial blood flow.

26 uced portal pressure and superior mesenteric arterial blood flow.

27 nce of vascular WNT signaling in maintaining arterial blood flow.

28 Thrombus aspirates and arterial blood from patients with ST-segment-elevation m

29 nd-tidal alveolar dead space fraction (first arterial blood gas after intubation) (per 0.1 unit incre

30 The results of arterial blood gas analyses at t = 4 minutes and t = 13

31 In total, 295,079 arterial blood gas analyses, including the PaO2, between

32 on within 24 hours prior to ICU arrival, and arterial blood gas analysis performed within 24 hours fo

33 cardiac arrest preceding PICU admission and arterial blood gas analysis taken within 1 hour of PICU

34 examination, pulmonary function testing and arterial blood gas analysis, and echocardiographic, imag

35 Secondary outcomes included changes in arterial blood gas and respiratory parameters, weaning d

36 limited incremental cycle exercise test with arterial blood gas collection.

37 We analyzed arterial blood gas data during 0 to 24 hours after the r

38 However, in some practice settings, daily arterial blood gas data required to calculate the respir

39 exercise maintained alveolar ventilation and arterial blood gas homeostasis but at the expense of ear

40 echanically ventilated patients may not have arterial blood gas measurements available at relevant ti

41 try recordings, all values from preoperative arterial blood gas measurements, and BAS procedure data.

42 Perioperative POCT includes arterial blood gas monitoring, chemistry, co-oximetry pa

43 se oximetry is increasingly substituting for arterial blood gas monitoring, noninvasive surrogate mar

44 ive care unit arrival, and postresuscitation arterial blood gas obtained.

45 Arterial blood gas parameters, clinical symptoms, health

46 Severity criteria often depend on arterial blood gas results.

47 Arterial blood gas testing, chest radiographs, and RBC t

48 efined a priori based on PaO(2) on the first arterial blood gas values obtained in the ICU.

49 O2 and VCO2), heart rate, cardiac output and arterial blood gas variables at peak exercise on a cycle

50 ompared with the baseline period, unadjusted arterial blood gas, chest radiograph, and RBC utilizatio

51 ased provider financial incentives targeting arterial blood gas, chest radiograph, and RBC utilizatio

52 tion were recorded at the time of a clinical arterial blood gas.

53 dead space marker, was calculated with each arterial blood gas.

54 A total of 409 patients with arterial blood gases analyzed at least once and with a c

55 rcised at approximately 85% of maximum while arterial blood gases and work of breathing were assessed

56 Arterial blood gases are critical in regulation of cereb

57 We studied 1,034 arterial blood gases from 703 patients; 650 arterial blo

58 We performed direct field measurements of arterial blood gases in climbers breathing ambient air o

59 UBJECTS AND INTERVENTIONS: Whole-lung CT and arterial blood gases were acquired simultaneously in 77

60 arterial blood gases from 703 patients; 650 arterial blood gases were associated with SpO2 less than

61 Fick cardiac outputs, filling pressures, and arterial blood gases were measured at 1-minute intervals

62 Arterial blood gases were measured every 30 minutes intr

63 Arterial blood gases were within the normal range and ef

64 dmissions of ventilated TBI patients who had arterial blood gases within 24 h of admission to the ICU

65 e intervention was associated with 128 fewer arterial blood gases, 73 fewer chest radiographs, and 16

66 imate diaphragm energy expenditure (effort), arterial blood gases, airway pressure, tidal volume and

67 ntaris muscles while monitoring respiration, arterial blood gases, and blood glucose in mice exposed

68 Mean arterial pressure, cardiac output, arterial blood gases, and lactate were measured concurre

69 the last minutes of each phase, we measured arterial blood gases, changes in end-expiratory lung vol

70 t program designed to decrease the avoidable arterial blood gases, chest radiographs, and RBC utiliza

71 primary outcome was the number of orders for arterial blood gases, chest radiographs, and RBCs per pa

72 f thoracoscopy in neonates on intraoperative arterial blood gases, compared with open surgery.

73 Toward the end of each phase, we measured arterial blood gases, inspiratory effort, and work of br

74 We also collected ventilation variables and arterial blood gases.

75 Although it is well established that arterial blood generally has higher concentrations of gl

76 rinsulinemic (4x basal) hyperglycemic clamp (arterial blood glucose 146 +/- 2 mg/dL) with portal GLC

77 from hepatic vein, portal vein, and systemic arterial blood in seven patients undergoing transplantat

78 od leaving the CNS capillary bed compared to arterial blood, indicating efflux from the CNS into the

79 were performed on the Focus-220 scanner with arterial blood input function measurement.

80 presents transfer of contrast agent from the arterial blood into the extravascular extracellular spac

81 fter percutaneous coronary intervention, and arterial blood lactate at admission >5 mmol/l.

82 pressure and cardiac output were reduced and arterial blood lactate was increased in relationship to

83 otid body (CB) is a polymodal chemosensor of arterial blood located next to the internal carotid arte

84 We suggest that the rapid rise pattern of arterial blood nicotine concentration stimulates and the

85 arotid body is a sensory organ for detecting arterial blood O2 levels and reflexly mediates systemic

86 carotid body, a sensory organ that monitors arterial blood O2 levels and stimulates breathing in res

87 sensing method for measuring pulse rate and arterial blood oxygenation.

88 dyspnoea, and partial pressure of oxygen in arterial blood (PaO(2)) more than 7.3 kPa.

89 Arterial blood PaO2 and PaCO2 during the first 24 hours

90 Hypercapnia is clinically defined as an arterial blood partial pressure of CO2 of above 40 mmHg

91 etting by low systolic (</=90 mm Hg) or mean arterial blood pressure (</=65 mm Hg) accompanied by sig

92 increases sympathetic nerve activity (SNA), arterial blood pressure (ABP) and breathing.

93 er 9th, 2014), with continuous monitoring of arterial blood pressure (ABP) and intracranial pressure

94 arotid sinus nerve denervation (CSD) reduces arterial blood pressure (ABP) in SHR.

95 pertonic NaCl produces a greater increase in arterial blood pressure (ABP) than equi-osmotic mannitol

96 lin is a ubiquitous peptide that can elevate arterial blood pressure (ABP) yet understanding of the m

97 In four groups of anaesthetized rats, arterial blood pressure (ABP), femoral blood flow (FBF)

98 n of central chemoreceptors by CO2 increases arterial blood pressure (ABP), sympathetic nerve activit

99 ally maintains exercise-induced increases in arterial blood pressure (BP) and muscle sympathetic nerv

100 ozone) and heat resulted in perturbation of arterial blood pressure (BP) in persons with type 2 diab

101 The kidney is an important organ for arterial blood pressure (BP) maintenance.

102 temporal pattern of heart rate (HR) and mean arterial blood pressure (BP) responses to selective caro

103 minute ventilation (VI), heart rate (HR) and arterial blood pressure (BP).

104 P=0.007), but with only modest falls in mean arterial blood pressure (by 4 mm Hg; P=0.004).

105 e, but not female, offspring had higher mean arterial blood pressure (effect size, +16 [9-21] mm Hg;

106 a intrathecal fentanyl: (a) reduced the mean arterial blood pressure (MAP), heart rate and ventilator

107 Mean arterial blood pressure (MAP), P(ETCO2), middle cerebral

108 as associated significantly with higher mean arterial blood pressure (P > .001 for trend).

109 transient tachycardia and a biphasic caudal arterial blood pressure (PCA) response that are in direc

110 larger concurrent CRVE, whereas higher mean arterial blood pressure (per 5 mmHg: beta = -0.36; 95% C

111 vessels to appropriately react to changes in arterial blood pressure (pressure reactivity) is impaire

112 ent [sbeta] = -0.311; P < .001), higher mean arterial blood pressure (sbeta = -0.085; P < .001), a mo

113 No cases of sustained resumption of arterial blood pressure activity were recorded, and no i

114 lective compound 85 showed no effect on mean arterial blood pressure and affected the heart rate duri

115 In 19 young men, MSNA (microneurography), arterial blood pressure and brachial artery blood flow (

116 Fetuses were first instrumented to measure arterial blood pressure and carotid artery blood flow an

117 assessed via the phase relationship between arterial blood pressure and cerebral blood flow velocity

118 Epinephrine increases arterial blood pressure and coronary perfusion during CP

119 if cardiopulmonary resuscitation-targeted to arterial blood pressure and coronary perfusion pressure

120 n system (RAS) is a principal determinant of arterial blood pressure and fluid and electrolyte balanc

121 Food intake, arterial blood pressure and heart rate were not altered

122 [OH]D) concentration is associated with high arterial blood pressure and hypertension risk, but wheth

123 gical or biochemical measure, including mean arterial blood pressure and inotrope use during the 48 h

124 on of AIP into the PVN significantly reduced arterial blood pressure and lumbar sympathetic nerve dis

125 he association of systolic and mean invasive arterial blood pressure and noninvasive blood pressure w

126 ison between concurrent measures of invasive arterial blood pressure and noninvasive blood pressure.

127 arson's correlation coefficient between mean arterial blood pressure and processed near-infrared spec

128 cursor contribute to CNS-mediated control of arterial blood pressure and salt and water balance and m

129 , biomarkers of endothelial cell activation, arterial blood pressure and subclinical atherosclerosis

130 by hemorrhagic hypotension (2 mL/100 g, mean arterial blood pressure approximately 35-40 mm Hg) for 9

131 lood volume and subsequent titration of mean arterial blood pressure approximately 40 mm Hg).

132 imit of autoregulation and not absolute mean arterial blood pressure are independently associated wit

133 diopulmonary bypass did not differ, the mean arterial blood pressure at the limit of autoregulation a

134 The longest period of cessation of arterial blood pressure before resumption was 89 seconds

135 Excursions of mean arterial blood pressure below the limit of autoregulatio

136 Excursions of mean arterial blood pressure below the lower limit of autoreg

137 Arterial blood pressure can often fall too low during de

138 essure by calculating an area above the mean arterial blood pressure curve.

139 Mean velocity index based on arterial blood pressure did not reach statistical signif

140 Although the average mean arterial blood pressure during cardiopulmonary bypass di

141 e beneficial epinephrine-induced increase in arterial blood pressure during CPR.

142 ood pressure overestimated systolic invasive arterial blood pressure during hypotension.

143 nsurvivors." The minimum value for diastolic arterial blood pressure during the first 24 hours was in

144 m Hg and subsequent maintenance of this mean arterial blood pressure for another 15 minutes.

145 01 to 0.37 +/- 0.01 mm (P < 0.001), and mean arterial blood pressure from 83 +/- 1 to 78 +/- 2 mmHg (

146 The apelin-apelin receptor system affects arterial blood pressure homeostasis; however, the centra

147 (100 mg/kg i.p.) significantly lowered mean arterial blood pressure in normotensive and hypertensive

148 mortality (p < 0.001) than systolic invasive arterial blood pressure in the same range (</=70 mm Hg).

149 Arterial blood pressure is a major determinant of region

150 When mean arterial blood pressure is below the lower limit of auto

151 Arterial blood pressure is controlled by vasodilatory fa

152 EY POINTS: Dysfunctions in CNS regulation of arterial blood pressure lead to an increase in sympathet

153 Orthostatic intraocular pressure and mean arterial blood pressure may be a helpful early screening

154 Noninvasive blood pressure and invasive arterial blood pressure mean arterial pressures showed b

155 Mean arterial blood pressure measured in anesthetized rats in

156 vasive blood pressure measurement with intra-arterial blood pressure measurement in critically ill pa

157 aging other critical illnesses suggest intra-arterial blood pressure measurement is preferred over au

158 nstitution and others in preference to intra-arterial blood pressure measurement remained prevalent.

159 st compressions for >/=1 minute and invasive arterial blood pressure monitoring before and during CPR

160 l hemorrhage over 15 minutes to reach a mean arterial blood pressure of 35-40 mm Hg and subsequent ma

161 ered and animals were resuscitated to a mean arterial blood pressure of 70 mm Hg until t=420 mins.

162 ensitivity was defined as a decrease in mean arterial blood pressure of more than 5 mm Hg during low-

163 increase cardiac output but reduce systemic arterial blood pressure only modestly.

164 trated no significant changes in either mean arterial blood pressure or heart rate in telemeterized r

165 Neither losartan nor divalinal affected arterial blood pressure or significantly altered the amy

166 Sympathetic nerve activity and arterial blood pressure responses to static hindlimb mus

167 In four subjects, arterial blood pressure resumed following cessation of a

168 de a novel method for precisely guiding mean arterial blood pressure targets during cardiopulmonary b

169 PH would require less volume to restore mean arterial blood pressure than lactated Ringer's or Hexten

170 venous occlusion plethysmography) and intra-arterial blood pressure to quantify local vasodilatation

171 PNPH but not Hextend improved mean arterial blood pressure vs. lactated Ringer's (p<.05).

172 s of an ICU admission, the minimum diastolic arterial blood pressure was a hemodynamic variable that

173 on and the duration and degree to which mean arterial blood pressure was below the autoregulation thr

174 Mean arterial blood pressure was lower in all treatment group

175 he middle cerebral artery, during which mean arterial blood pressure was maintained at normotension (

176 Mean arterial blood pressure was normal in the NA group; seve

177 However, arterial blood pressure was preserved and left ventricul

178 Arterial blood pressure was recorded chronically in cons

179 Mean arterial blood pressure was reduced during the early rep

180 Surface ECG and peripheral arterial blood pressure waveform via arterial line were

181 Intracranial pressure and arterial blood pressure waveforms were low-pass filtered

182 Absence of slow arterial blood pressure waves (odds ratio, 2.7; p < 0.00

183 Higher systolic blood pressure and mean arterial blood pressure were associated with a higher pr

184 muscle sympathetic nerve activity (MSNA) and arterial blood pressure were measured in 19 healthy subj

185 tput, systemic vascular resistance, and mean arterial blood pressure were unchanged.

186 vity, adrenal sympathetic nerve activity and arterial blood pressure whereas equi-osmotic mannitol/so

187 ed vasoactive drugs to achieve a target mean arterial blood pressure with 82 centers (68.9%) employin

188 his study are to compare real-world invasive arterial blood pressure with noninvasive blood pressure,

189 by peak exercise cardiac power output (mean arterial blood pressure x cardiac output) and functional

190 Mice were resuscitated (mean arterial blood pressure>50 mm Hg for 30 min) with lactat

191 ls as inputs (intracranial pressure and mean arterial blood pressure) is an additional asset.

192 femoral vascular conductance (FVC, FBF/mean arterial blood pressure), as well as calf muscle blood f

193 ody mass index, waist-height ratio, and mean arterial blood pressure).

194 orrelated with diastolic, systolic, and mean arterial blood pressure, a surrogate marker for arterial

195 lness was characterized by a decline in mean arterial blood pressure, an increase in pulse and respir

196 e ionotropy, angiogenesis, reduction of mean arterial blood pressure, and apoptosis.

197 No differences were found in temperature, arterial blood pressure, and oxygenation between alpha-s

198 Cerebral blood flow (CBF) is controlled by arterial blood pressure, arterial CO2, arterial O2, and

199 reductions in intraocular pressure and mean arterial blood pressure, as might be expected with a lac

200 Waveforms of intracranial pressure and arterial blood pressure, baseline Glasgow Coma Scale and

201 orts, MA caused a transient increase in mean arterial blood pressure, body temperature and respirator

202 ct brain perfusion in the face of changes in arterial blood pressure, but little is known about indiv

203 Arterial blood pressure, cardiac output, tissue oxygen t

204 art rate variability, intracranial pressure, arterial blood pressure, cerebral perfusion pressure, an

205 included vital signs, left atrial pressure, arterial blood pressure, cerebral perfusion/oximetry, VT

206 mass index, change in body mass index, mean arterial blood pressure, change in mean blood pressure,

207 hAT expression in CD4(+) cells have elevated arterial blood pressure, compared to littermate controls

208 erial baroreflexes, and leads to lability of arterial blood pressure, damage to cardiac myocytes, and

209 microneurography at the peroneal nerve, and arterial blood pressure, electrocardiogram, and central

210 Invasive arterial blood pressure, electrocardiogram, and oxygen s

211 ide (ETCO2), oxygen saturation (SaO2), intra-arterial blood pressure, electrocardiography (EKG), and

212 Measurement of blood gases, mean arterial blood pressure, functional capillary density, a

213 observed in controls; normalization of mean arterial blood pressure, heart rate, and increased survi

214 Mean arterial blood pressure, heart rate, and survival were m

215 Mean arterial blood pressure, heart rate, intracranial pressu

216 All patients had continuous monitoring of arterial blood pressure, intracranial pressure, and cere

217 For every period, mean values (+/- SDs) of arterial blood pressure, intracranial pressure, pressure

218 nce on the effects of periodontal therapy on arterial blood pressure, leucocyte counts, fibrinogen, t

219 tion as a promising novel mechanism to lower arterial blood pressure.

220 uctuations of cerebral perfusion pressure or arterial blood pressure.

221 ttenuated high-fat diet-induced elevation in arterial blood pressure.

222 usly with continuous recording of peripheral arterial blood pressure.

223 ctivity continued after the disappearance of arterial blood pressure.

224 ion, alpha-MSH reduced gastric tone and mean arterial blood pressure.

225 eathing, central sympathetic outflow and the arterial blood pressure.

226 th cirrhosis into BALB/C mice decreased mean arterial blood pressure.

227 ges in femoral vascular conductance and mean arterial blood pressure.

228 s of 27,022 simultaneously measured invasive arterial blood pressure/noninvasive blood pressure pairs

229 22 vs. 378 +/- 15 beats min(1)) and carotid arterial blood pressures (76 +/- 3 vs. 76 +/- 1 mmHg) we

230 c blood pressure, and high systolic and mean arterial blood pressures are associated with a higher pr

231 ered (strain B) or decreased (strain C) mean arterial blood pressures compared to their corresponding

232 Mean arterial blood pressures were 90.1 +/- 18.5 mm Hg supine

233 Mean arterial blood pressures, resuscitation volumes, blood g

234 t model together with a metabolite-corrected arterial blood sampler input function (BSIF).

235 ty-shear rate relationship was obtained from arterial blood samples analyzed using a standard viscosi

236 Arterial blood samples and PET images were obtained at f

237 Subjects were imaged for 3.5 h, with arterial blood samples obtained throughout.

238 Arterial blood samples were collected to calculate the m

239 In all animals, arterial blood samples were drawn and corrected for meta

240 Arterial blood samples were drawn for arterial input fun

241 Discrete arterial blood samples were taken during (11)C-HED scans

242 Manual arterial blood samples were used for calibration and cor

243 Arterial blood samples, collected at 7 time points, were

244 Full tracer kinetic models require arterial blood sampling and dynamic image acquisition.

245 A 90-min dynamic PET scan with arterial blood sampling and metabolite analysis was acqu

246 Methods: A 90-min dynamic PET scan with arterial blood sampling and metabolite analysis was acqu

247 Arterial blood sampling and metabolite analysis were per

248 ders) underwent (18)F-DPA-714 PET scans with arterial blood sampling and metabolite analysis.

249 and time activity curve were assessed using arterial blood sampling and served as measures for recep

250 netic analysis of a 90-min dynamic scan with arterial blood sampling is recommended for the quantific

251 standardized uptake values, suggesting that arterial blood sampling may not be necessary for modelin

252 Continuous arterial blood sampling over the first 15 min was follow

253 culation, a dynamic (18)F-FHNP PET scan with arterial blood sampling was acquired from rats treated w

254 1)C-PBR28 or (R)-(11)C-PK11195 PET scan with arterial blood sampling was obtained.

255 Dynamic PET imaging with arterial blood sampling was performed in 3 baboons, with

256 Arterial blood sampling was performed with chromatograph

257 Small-animal PET scans with arterial blood sampling were obtained for 4 groups of is

258 Input functions were obtained through arterial blood sampling with metabolite analysis.

259 a input functions were obtained using online arterial blood sampling with metabolite corrections deri

260 n = 13) (555 MBq [15 mCi], 90-min scan, and arterial blood sampling).

261 a simplified analytic approach requiring no arterial blood sampling, and correlated with standardize

262 The need for arterial blood sampling, however, limits clinical applic

263 min after bolus injection of (18)F-T807 with arterial blood sampling.

264 a method to eliminate the need for invasive arterial blood sampling.

265 th static whole-body PET scans not requiring arterial blood sampling.

266 d Yorkshire x Landrace pigs, concurrent with arterial blood sampling.

267 ) underwent 150-min dynamic SPECT scans with arterial blood sampling.

268 underwent 180-min PET with (18)F-AV-1451 and arterial blood sampling.

269 underwent 180-min PET with (18)F-AV-1451 and arterial blood sampling.

270 min after bolus injection of (18)F-T807 with arterial blood sampling.

271 subjects underwent two PET measurements with arterial blood sampling.

272 n dynamic (11)C-HED PET/CT scans with online arterial blood sampling.

273 put functions were obtained using continuous arterial blood-sampling as well as using image-derived m

274 sohemoglobin levels are higher in venous vs. arterial blood (suggesting systemic S-nitrosohemoglobin

275 responding to pH 6.7 develops when hindlimb arterial blood supply is deficient under ischaemic condi

276 derwood septa, and laceration of the lateral arterial blood supply to the maxillary sinus) were obtai

277 se pressor reflex in rats with a compromised arterial blood supply to the working muscles.

278 onally accumulated in watershed areas of low arterial blood supply.

279 ncer classification because of its exclusive arterial blood supply.

280 The human circulatory system consists of arterial blood that delivers nutrients to tissues, and v

281 ohimbine with 90-min dynamic PET and sampled arterial blood to measure intact (11)C-yohimbine in plas

282 in PET for 2 h and serial sampling of radial arterial blood to measure parent radioligand concentrati

283 Global CBF, intra-cranial arterial blood velocities, extra-cranial blood flows, an

284 nature and span a wide range of scales, from arterial blood vessels and bronchial mucus transport in

285 ociated with increased mineralization of the arterial blood vessels and cardiac valves.

286 inal ganglion cell layer and in the edges of arterial blood vessels in the transgenic mice.

287 Less permeable arterial blood vessels maintain haematopoietic stem cell

288 Sufficient blood flow to tissues relies on arterial blood vessels, but the mechanisms regulating th

289 ctopic tissue mineralization in the skin and arterial blood vessels.

290 ic mineralization in the skin, eyes, and the arterial blood vessels.

291 L/hour) was used as a surrogate of effective arterial blood volume.

292 s associated with an impairment of effective arterial blood volume.

293 he bolus at the infusion rate = 60 min), and arterial blood was collected for data quantification.

294 Arterial blood was collected for invasive kinetic modeli

295 For 3 of the brain SPECT studies, arterial blood was collected for invasive modeling.

296 Over the course of scanning, arterial blood was collected to derive the input functio

297 During all PET scans, arterial blood was monitored continuously.

298 istal protection/aspiration device, coronary arterial blood was retrieved before and during stenting

299 Arterial blood was sampled for measurement of blood radi

300 In all scans, arterial blood was sampled to measure the parent radioli

301 Sampling of arterial blood with metabolite analysis was performed th