ライフサイエンスコーパス: blood volume

1 nancy to support rapid expansion of maternal blood volume.

2 acers with high temporal resolution in small blood volume.

3 ging in small animals because of their small blood volume.

4 d errors, but it requires calibration of the blood volume.

5 op diuretics, resulting in an improvement in blood volume.

6 rrelated to regional differences in cerebral blood volume.

7 the paper filter extracted contains a fixed blood volume.

8 rho in inner retina was linked to changes in blood volume.

9 clotting under flow, while requiring a small blood volume.

10 ic shock by acutely withdrawing 50% of their blood volume.

11 as used as a surrogate of effective arterial blood volume.

12 imaging was used to measure tumor fractional blood volume.

13 ejected in a single day exceeds their entire blood volume.

14 ted with an impairment of effective arterial blood volume.

15 SV (P = 0.021) and was proportional to total blood volume.

16 with diverse changes in CO, SVR, and central blood volume.

17 receptor-A (NPRA) lowers blood pressure and blood volume.

18 erstitial fluid without excessively reducing blood volume.

19 k both water and minerals (salts) to recover blood volume.

20 on devices by increasing the processed whole blood volume.

21 associated with a parallel increase in tumor blood volume.

22 ametocyte densities were quantified in large blood volumes.

23 The assay was very sensitive with increased blood volumes.

24 n this study, we investigated the effects of blood volume (0.8, 1.0, and 1.2 ml), tube shaking (gentl

25 1) mainly as a result of decreased capillary blood volume (133.9+/-5.1 to 111.7+/-7.7 AU; P<0.05) wit

26 vs 14 [range, 6-22] mL/100 mL/min), cerebral blood volume (2.4 [range, 1.6- 4.2] vs 3.9 [range, 3.4-4

27 lozin persisted, resulting in a reduction in blood volume (-208 mL [interquartile range, -536 to 153

28 values were 0.93 for FMBV fractional moving blood volume (95% CI confidence interval : 0.82, 0.97) v

29 values were 0.95 for FMBV fractional moving blood volume (95% confidence interval [ CI confidence in

30 -e(-betat)) to quantify functional capillary blood volume (A), microvascular flow velocity (beta), an

31 criteria to select donors with an estimated blood volume above 3.5 l.

32 ability to collect CTCs from a large patient blood volume allows this technique to be used experiment

33 the brain experiences large fluctuations in blood volume and altered coupling between neural and vas

34 logic (Gaussian normalized relative cerebral blood volume and apparent diffusion coefficient) paramet

35 ntially linking together hormonal control of blood volume and blood glucose levels, and thus adding t

36 tational pooling excessively reduces central blood volume and cardiac output.

37 thod was used to simultaneously estimate the blood volume and correct the signal change caused by ion

38 Blood volume and flow-extraction product derived at DCE

39 reased Gaussian-normalized relative cerebral blood volume and Gaussian-normalized relative cerebral b

40 as induced in rats by withdrawing 60% of the blood volume and maintaining a hypotensive state.

41 t LC-MS/MS method to simultaneously estimate blood volume and NOAC concentrations on DBS cards.

42 ulature rather than reduction in circulating blood volume and oxygen delivery.

43 However, the BOLD signal reflects changes in blood volume and oxygenation rather than neuronal activi

44 ofluorescence and are affected by changes in blood volume and oxygenation.

45 omic, and behavioral responses that maintain blood volume and perfusion pressure at levels optimal fo

46 E-MRI (n = 8) experienced decreases in tumor blood volume and permeability (P < .01).

47 oved vessel features by assessing fractional blood volume and permeability*surface area product, T(1)

48 There were negative correlations between blood volume and pimonidazole staining (r = -0.48, P = .

49 ggest that Ang II, in addition to regulating blood volume and pressure, may be a master regulator of

50 le electrolyte and water transport and hence blood volume and pressure.

51 right position, leading to increased central blood volume and reduced venous pooling.

52 Further, under hyperoxia, the baseline blood volume and saturation of all vascular compartments

53 Animals tightly regulate blood volume and solute concentrations.

54 4 hours of hemorrhage (removal of 40% of the blood volume and subsequent blood removal/retransfusion

55 t 4 hrs of hemorrhage (removal of 40% of the blood volume and subsequent blood removal/retransfusion

56 agic shock (removal of 30% of the calculated blood volume and subsequent titration of mean arterial b

57 to construct a calibration curve between the blood volume and the extent of ion suppression.

58 However, in mice, limited blood volume and the rarity of CTCs in the bloodstream p

59 dies in rodents because of their small total blood volume and the related difficulties in withdrawing

60 decongestive treatment, reduces circulating blood volume and thereby reduces intravascular congestio

61 This study identified blood volume and tube shaking as novel preanalytical sou

62 Three-dimensional FMBV fractional moving blood volume and VFI vascularization flow index produced

63 had greater vessel density, greater cerebral blood volumes and performed better on a neuromotor task

64 ost optimizations (construction materials or blood volume) and optimization of efficient flow via min

65 maging hemoglobin absorption (i.e., cerebral blood volume); and a laser speckle contrast (LSC) channe

66 lationship between the PA:A ratio, pulmonary blood volume, and cardiac function.

67 ayer-specific measurements of BOLD, cerebral blood volume, and cerebral blood flow in regions of posi

68 eceived a lower transfusion volume per liter blood volume, and experienced a smaller posttransfusion

69 ion with moderate confidence for blood flow, blood volume, and hepatic arterial fraction in tumors an

70 to assess spectrometric results, fractional blood volume, and immunohistochemical evaluation.

71 coefficients, cerebral blood flow, cerebral blood volume, and intratumoral susceptibility signals.

72 and 1.9%, for cerebral blood flow, cerebral blood volume, and mean transit time, respectively.

73 level of cerebral hemoglobin concentration, blood volume, and oxygen saturation.

74 because of their expense, the large required blood volumes, and labour-intensive technologies.

75 sculature by increasing muscle microvascular blood volume ( approximately 2-fold, P < 0.05) and incre

76 g platelet function and coagulation with low blood volumes ( approximately 100 mul) over a wide range

77 alterations in vessel calibre or fractional blood volume as assessed using susceptibility contrast M

78 han Andeans, resulting in a comparable total blood volume at a lower hemoglobin concentration.

79 that harbors a large proportion of the total blood volume at any given time.

80 average 80% decrease in normalized cerebral blood volume at the core of the lesion (P < 0.0001).

81 .001), suggesting an increase in unstressed blood volume at the lowest dose of norepinephrine.

82 mechanical inspiratory breaths redistributed blood volume away from well-ventilated areas, worsening

83 r aortic arch) with intraoperative bleeding (blood volume between 60 and 250 mL suctioned from the th

84 em to hone in on depth information regarding blood volume, blood flow velocity and direction, vascula

85 ate mononuclear cells from almost the entire blood volume, but such large numbers and concentrations

86 data such as in vivo tumor blood flow (BF), blood volume (BV) and intravascular oxygen saturation (H

87 Blood volume (BV) was measured using the optimized carbo

88 >0.91) for blood flow (BF), high (>0.84) for blood volume (BV), and lower (>0.30 and >0.39) for mean

89 usion parameters [including Blood Flow (BF), Blood Volume (BV), Mean Transit Time (MTT)] and permeabi

90 Aldosterone synthase (AS) regulates blood volume by synthesizing the mineralocorticoid aldos

91 t only the quantitative measurement of total blood volume can help identify the heterogeneity in plas

92 n level-dependent (BOLD) signal and cerebral blood volume (CBV) and blood flow (CBF), which in turn w

93 ng voluntary behaviors by measuring cerebral blood volume (CBV) and neural activity in the somatosens

94 ultaneously, we measured changes in cerebral blood volume (CBV) as a proxy of drug effects on neurona

95 genation level-dependent (BOLD) and cerebral blood volume (CBV) fMRI signal.

96 (18)F-FDG uptake, permeability, and cerebral blood volume (CBV) in children with pediatric brain tumo

97 ring neural activity and changes in cerebral blood volume (CBV) in the somatosensory cortex of awake,

98 baseline hippocampal activity using cerebral blood volume (CBV) mapping was measured.

99 versus white matter (WM), (2) GM/WM cerebral blood volume (CBV) ratio close to the histologically est

100 nsulin to increase skeletal muscle capillary blood volume (CBV) reduces glucose uptake in insulin res

101 Perihematomal cerebral blood volume (CBV) was inversely associated with HG (B =

102 Cerebral blood volume (CBV), cerebral blood flow (CBF), and mean

103 microvascular blood flow (MBF) and capillary blood volume (CBV).

104 hresholds for mean transit time and cerebral blood volume (CBV).

105 eceptor occupancy and hemodynamics [cerebral blood volume (CBV)] in the domains of space, time, and d

106 d-oxygen-level-dependent (BOLD) and cerebral-blood-volume (CBV)-based laminar fMRI and used these to

107 d-oxygen-level-dependent (BOLD) and cerebral-blood-volume (CBV)-fMRI from individual venules and arte

108 lood [T/B] ratio), vascularization (cerebral blood volume [CBV]), and vascular permeability (contrast

109 Cerebral blood flow, cerebral blood volume, cerebral oxygen metabolism (CMRO2), oxygen

110 ely attributable to the significantly larger blood volume changes that occur in the perimysial space.

111 Blood volume changes were identical (P = 0.867), but the

112 a hemodynamic response of oxygen supply and blood volume closely coupled to the up-regulation of CCO

113 Blood volume (CO rebreathing) and LV mass (cardiac magne

114 -based sampling procedure to enable accurate blood volume collection on commercially available DBS ca

115 e, left ventricular mass and compliance, and blood volume compared to similarly aged or even younger

116 We also studied the diagnostic value of blood volume contraction indices and B-type natriuretic

117 fits, and the 2-tissue model with estimated blood volume correction (2Tv) performed best, particular

118 A fixed blood volume correction was applied.

119 Normalized blood volume decreased in inspiration in the nondependen

120 nfluence the osmotic (plasma osmolality) and blood volume-dependent compensatory thresholds for antid

121 (vascularization index and fractional moving blood volume) derived from UMI images provide significan

122 tivity of the DBS eluate can be used for the blood volume determination by using C(4)D in a nonsepara

123 Blood volume did not significantly change the proportion

124 For calibration of errors caused by the blood volume difference, 75% of the test metabolites sho

125 Determine the intra-tidal regional gas and blood volume distributions at different levels of atelec

126 t does not mitigate the reduction in central blood volume during a simulated haemorrhagic challenge c

127 is able to assess local changes in cerebral blood volume during cognitive tasks, with sufficient tem

128 Artificial colloids substitute blood volume during surgery; with the administration of

129 ed agent using only a small (2 uL) amount of blood volume, enabling additional end-point measurements

130 There was no difference in the blood volume-expanding properties of the 2 preparations

131 Based on a combination of blood volume expansion and increasing platelet counts, t

132 70%), echocardiography led to the absence of blood volume expansion in the remaining 14 patients who

133 methods for estimating placental fractional blood volume (FBV) are of great interest for characteriz

134 es to quantify and evaluate tumor fractional blood volume (fBV) as a noninvasive imaging biomarker of

135 tion rate R (2)* (second(-1)) and fractional blood volume (fBV, %) were sensitive imaging biomarkers

136 iabetes mellitus (T2DM) patients using small blood volumes (fingerprick ~100 muL).

137 tely detected lower blood velocities and low blood volume flow in the carotid arteries after ligation

138 een three-dimensional (3D) fractional moving blood volume (FMBV) and fluorescent microspheres indicat

139 und Three-dimensional (3D) fractional moving blood volume (FMBV) derived from 3D power Doppler US has

140 es of hippocampal dysfunction-focal cerebral blood volume, focal atrophy, and evidence of elevated gl

141 heresis of mononuclear cells from very large blood volumes, followed by rapid flow, high-gradient mag

142 LV(EV), distal pulmonary venous blood volume for vessels smaller than 5 mm(2) in cross s

143 We also find that targeting blood volume fraction (a parameter of the model) through

144 in terms of bone-remodeling activity (BRA), blood volume fraction (BVF), and hypoxia.

145 Whole tumor and regional rate constants and blood volume fraction (VB) were computed by using compar

146 ue oxygen saturation, mean transit time, and blood volume fraction in the cortex and caudoputamen; 2)

147 ospective clinical translation, we calculate blood volume fraction parameter values from in vivo cont

148 sue reversible compartment model with fitted blood volume fraction seems to be the most preferred mod

149 Mean transit time and blood volume fraction were comparable between the four g

150 in oxygen saturation, mean transit time, and blood volume fraction were subsequently measured using a

151 Brain perfusion (mean transit time and blood volume fraction) was comparable between the three

152 aps of the microvascular architecture (i.e., blood volume fraction, vessel diameter) and function (bl

153 a reversible 2-tissue-compartment model with blood volume fraction.

154 tadiaphragmatic slice were obtained, gas and blood volume fractions within three gravitational region

155 ry rate, CO-Modelflow algorithm, and central blood volume from impedance cardiography; 10-minute data

156 ivo CTC isolation technologies rely on small blood volumes from a single venipuncture limiting the nu

157 We use blood-volume functional MRI to monitor longitudinally th

158 eep, mice showed large increases in cerebral blood volume ([HbT]) and arteriole diameter relative to

159 By day 4, hepatic blood volume (HBV) in the responder group decreased by 2

160 h congenital heart defects (CHD), changes in blood volume, heart rate, respiration, and edema during

161 e baboons were subjected to 40% to 55% total blood volume hemorrhage to achieve profound hypotension

162 (i) is sensitive; (ii) requires only a small blood volume; (iii) is faster, less labor intensive, and

163 a progressive decline of the renal relative blood volume in all models.

164 Heat stress reduced blood volume in all regions (ranging from 7 to 16%), whi

165 While normothermic,LBNP reduced blood volume in all regions (torso: 22 +/- 8%; heart: 18

166 The loss of blood volume in distal pulmonary vessels is associated w

167 Blood volume in dried blood spot (DBS) analysis is assum

168 LBNP while heat stressed, the reductions in blood volume in each region were markedly greater when c

169 assessed hemoglobin mass, plasma volume and blood volume in lowlanders at sea level, lowlanders accl

170 flow and greater expansion of microvascular blood volume in MAPC-treated mice than in controls.

171 Limited blood volume in mice precludes repeated sampling, render

172 al maps of changes in tissue oxygenation and blood volume in response to mechanical whisker stimulati

173 e biomarker of subsequent reduction in tumor blood volume in response to sunitinib, and acquired resi

174 ng variables were calculated: VB (fractional blood volume in target area), K(1) and k(2) (kinetic mem

175 for the simultaneous determination of exact blood volume in the DBS punch and the quantitation of ta

176 Both the increase in normalized blood volume in the dependent region and fractional atel

177 The capillary blood volume in the eluate is calculated from the concen

178 However, these significant changes in blood volume in the endomysium produce a change of only

179 (15)O-CO PET showed decreased blood volume in the femoral artery after the injury.

180 However, blood volume in the punch is dependent on several factor

181 ded RBCs may be proposed as reporters of the blood volume in the tumor region.

182 ethods are suitable for the determination of blood volume in unknown DBS samples by punching out the

183 w levels of antibodies accurately from small blood volumes in a fully automated system.

184 ) of a colloid solution) normalizes regional blood volumes in the torso, but does not mitigate the re

185 liliters per 100 milliliters per minute) and blood volume (in milliliters per 100 milliliters) were d

186 Response to hemorrhage (20% loss of blood volume), including plasma renin activity, was asse

187 The blood volume increased even more sharply when the animal

188 ericardium restrains LV filling when central blood volume increases.

189 ivity, 59% specificity), change in pulmonary blood volume index (77% sensitivity, 82% specificity), a

190 sensitivity, 98% specificity) and pulmonary blood volume index (92% sensitivity, 68% specificity), a

191 dex (r = 0.17; p = .001), baseline pulmonary blood volume index (r = 0.15; p = .001), change in pulmo

192 ex (r = 0.15; p = .001), change in pulmonary blood volume index (r = 0.16; p < .001), and change in P

193 Baseline cardiac index and pulmonary blood volume index were higher, whereas change in cardia

194 change in cardiac index, change in pulmonary blood volume index, and change in PaO2/FIO2 ratio indivi

195 change in cardiac index, change in pulmonary blood volume index, and change in PaO2/FIO2 ratio were l

196 ry dilution such as cardiac index, pulmonary blood volume index, and extravascular lung water.

197 s baseline cardiac index, baseline pulmonary blood volume index, the change in cardiac index, change

198 r premature neonates who have a very limited blood volume is a particular challenge.

199 sessment of leukocyte function in microlitre blood volumes is feasible and that it provides significa

200 These data suggest that blood volume loading during passive heat stress (via 11

201 adjustment for age, sex, race, and estimated blood volume, lower eGFR was associated with reduced 25(

202 VLCBV was defined as cerebral blood volume<2.5th percentile of brain contralateral to

203 e virtual nonenhanced, iodine, perfused lung blood volume, lung vessel, automated bone removal, and r

204 ntrast magnetic resonance perfusion cerebral blood volume maps were co-registered, segmented when cer

205 t the hypotheses that pulmonary aeration and blood volume matching is reduced during inspiration in t

206 d leg blood flow (LBF), muscle microvascular blood volume (MBV) and muscle protein turnover under pos

207 on sex differences in myocardial perfusion, blood volume (MBV), and extracellular volume (ECV) in he

208 Muscle microvascular blood volume (MBV), microvascular blood flow velocity (M

209 Blood flow, blood volume, mean transit time (MTT), permeability-surf

210 ric modeling to determine tissue blood flow, blood volume, mean transit time, permeability, and hepat

211 allows bedside plasma separation from whole blood, volume metering, depletion of albumin, protein di

212 redominately exhibit a reduction of cerebral blood volume mirrored by suppression of cortical delta o

213 Blood volume (mL kg(-1) ) and LV mass index (g m(-2) ) w

214 etween Gaussian-normalized relative cerebral blood volume (nrCBV) and Gaussian-normalized relative ce

215 olume, Gaussian-normalized relative cerebral blood volume (nrCBV), Gaussian-normalized relative blood

216 FC allows sampling of the entire circulating blood volume of a mouse in under 10 minutes, while maint

217 ely 10-fold more myeloid DCs than the entire blood volume of an average individual.

218 associated with increasing relative cerebral blood volume of NER (rCBVNER), which was higher with dee

219 it was determined that perfusion with three blood volumes of heparinized saline is optimal, achievin

220 tamate/glutamine and elevated focal cerebral blood volume on functional magnetic resonance imaging, b

221 on suppression zone in the chromatogram, the blood volume on the DBS cards can be calculated and furt

222 e calibration curve was used to estimate the blood volume on the DBS cards collected from 6 volunteer

223 hese peptides may not necessarily track with blood volume or invasive hemodynamic measurements in ind

224 ewed as a homeostatic response to changes in blood volume or tonicity.

225 Nonspecific uptake is reversible (e.g., blood volume) or irreversible (due to (89)Zr-residualiza

226 (4)D, which are linearly proportional to the blood volume originally sampled onto the DBS card.

227 systole and diastole, and change in vascular blood volume over a cardiac cycle.

228 de of chest tube bleeding (median chest tube blood volume over the entire extracorporeal membrane oxy

229 Changes in blood volume (P = 0.867), strong ion difference (P = 0.2

230 ble 2-tissue model with 4 rate constants and blood volume parameter was preferred in 84% of cases.

231 ersible single-tissue-compartment model with blood volume parameter was the preferred plasma input mo

232 using an irreversible compartment model with blood volume parameter.

233 tissue-compartment models with and without a blood volume parameter.

234 irreversible 2-tissue-compartment model with blood volume parameter.

235 cost, multiplexed assay requiring ultrasmall blood volumes, paving the way for the implementation of

236 We introduced dual-energy CT (DECT) perfused blood volume (PBV) as a PBF surrogate to evaluate whethe

237 tative and quantitative analysis of perfused blood volume (PBV) maps recorded: i) perfusion defect 'p

238 FMBV fractional moving blood volume performed better than VFI vascularization f

239 Blood volume, permeability-surface area product, and v(e

240 g a potential link between the regulation of blood volume/pressure/osmolality and blood glucose.

241 ion flow index versus FMBV fractional moving blood volume produced an R(2) value of 0.211 and was sig

242 Peripheral hemodynamics, measured via the blood volume pulse and vasomotion, provide a valuable wa

243 ion of Evans Blue Dye) and in renal relative blood volume quantified using in vivo microcomputed tomo

244 t effect is to decrease myocardial capillary blood volume rather than microvascular flow velocity, su

245 s highly accurate quantification of relative blood volume (rBV) and highly detailed three-dimensional

246 time-intensity curve, time to peak, relative blood volume (rBV), relative blood flow, and blood flow

247 ty curve [AUC], time to peak [TTP], relative blood volume [rBV], relative blood flow [rBF], and blood

248 Relative cerebral blood volume (rCBV) (maximum rCBV [rCBV(max)] and mean r

249 physiologic MRI, including relative cerebral blood volume (rCBV) and apparent diffusion coefficient (

250 rrent study evaluated both relative cerebral blood volume (rCBV) and VSI(MRI) in eleven patients with

251 imaging-based whole-tumor relative cerebral blood volume (rCBV) histograms.

252 erences were noted in age, relative cerebral blood volume (rCBV) in contrast-enhanced regions (cutoff

253 Relative cerebral blood volume (rCBV) ratio is one of the best noninvasive

254 oefficient (ADC) with high relative cerebral blood volume (rCBV) represented elevated choline (Cho)-t

255 (PWI), especially maps of regional cerebral blood volume (rCBV), may provide similar diagnostic info

256 hanced perfusion-weighted (relative cerebral blood volume [rCBV]) imaging were evaluated in these 28

257 antly higher fMRI signals [relative cerebral blood volumes (rCBVs)] and atrophy were observed in both

258 These include macronutrient metabolism, blood volume regulation, immune system support, endocrin

259 We used an in vitro technique to investigate blood volumes required to detect bacteremia and fungemia

260 n analogue stimulation assay, with its lower blood volume requirement, could be a valuable method for

261 Due to blood volume requirements as well as ethical and practic

262 e mass (normalized gas volume and normalized blood volume, respectively).

263 ive RV flow, oxygen extraction fraction, and blood volume, respectively, from which RV MVO2 was calcu

264 ersible single-tissue-compartment model with blood volume seems to be a good candidate model for quan

265 he hemodynamic stress of increased effective blood volume, setting in motion untoward molecular and b

266 ulation of TH(VTA) neurons enhanced cerebral blood volume signals in striatal target regions in a dop

267 of hemorrhagic shock (removal of 30% of the blood volume, subsequent titration of mean arterial pres

268 ood loss, expressed as a percentage of total blood volume (TBV), mean arterial pressure, and heart ra

269 richment, permitting interrogation of larger blood volumes than classic phlebotomy specimens over a p

270 After accounting for tumor blood volume, the extravasated nanoparticles were quanti

271 als led to ramp-like decreases in mean local blood volume; these reversed with ramp-like increases du

272 t alter the extent of the reduction in these blood volumes to LBNP relative to heat stress alone (tor

273 The mean (+/-SD) total blood volume transfused per child was 314+/-228 ml in th

274 Patients with major burns have major (>1 blood volume) transfusion requirements.

275 g technique that detects changes of cerebral blood volume triggered by brain activation.

276 reduce errors from variations in the spotted blood volume/unit area.

277 our of hypovolemia resuscitation with 35% of blood volume using a high-molecular-weight hydroxyethyl

278 3D three-dimensional FMBV fractional moving blood volume value +/- standard deviation was 11.78% +/-

279 nalysis showed higher FMBV fractional moving blood volume values than VFI vascularization flow index

280 lesion was present, and normalized cerebral blood volume values were analysed using a Food and Drug

281 IS method was used to estimate and calibrate blood volume variation and also to quantify the voricona

282 te method for estimating and calibrating the blood volume variation on DBS cards, which greatly facil

283 ry (LC-ESI-MS) for estimating and correcting blood volume variations on the DBS cards.

284 Renal dopamine regulates blood pressure and blood volume via a natriuretic effect.

285 Very low cerebral blood volume (VLCBV), diffusion, and hypoperfusion lesio

286 uantification of proliferating cells, and BM blood volume was estimated by measuring the changes in t

287 Three-dimensional FMBV fractional moving blood volume was measured on the vasculature from the ut

288 Cardiac fractional microvascular blood volume was not greater in anaemic fetuses, suggest

289 Measurement of fractional blood volume was similar in all tumors (2.6 AU +/- 0.5 x

290 hemodynamic changes using BOLD and cerebral blood volume-weighted (CBVw) fMRI.

291 In addition, we use cerebral blood volume-weighted functional magnetic resonance imag

292 nges in normalized gas volume and normalized blood volume were negatively correlated in fractional at

293 t (Q(peak)), haemoglobin mass (Hb(mass)) and blood volumes were assessed prior to and following ET.

294 scular blood flux rate whereas microvascular blood volumes were not different between groups at basel

295 the use of dual-energy X-ray absorptiometry, blood volume with the use of a carbon monoxide (CO)-rebr

296 en a low-volume resuscitation (LVR) (10%-20% blood volume) with saline or various cell impermeants (s

297 ressure-targeted hemorrhagic shock, the mean blood volume withdrawn was significantly lower in the an

298 % of cardiac capillaries and halves perfused blood volume within the affected region.

299 ctin potently increased muscle microvascular blood volume without altering microvascular blood flow v

300 for leukocyte characterization using smaller blood volumes would thus be useful in diagnostic setting