... anemia is Page 17 of 22 (page number not for citation purposes) Critical Care 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 Vol 13 No Kramer and Zygun associated with increased ... 44:14 05- 1411 French CJ, Bellomo R, Finfer SR, Lipman J, Chapman M, Boyce NW: Appropriateness of redbloodcell transfusion in Australasian intensive care practice Med J Aust 2002, 177 :54 8 -55 1 Hebert ... regeneration of redcell 2,3-diphosphoglycerate following transfusion of DPGdepleted AS-1, AS-3 and CPDA-1 red cells Br J Haematol 1989, 71:131-136 75 Marik PE, Sibbald WJ: Effect of stored -blood transfusion...
... Interquartile range 0. 25 to 0. 35 0. 25 to 0. 35 Median 0.4 0. 35 Interquartile range 0.27 to 0. 65 0.27 to 0 .54 Transfused blood Duration of storage (days) Number of redbloodcell units 0.9 85 Demographic ... 36 to 46 35 to 43 0.297 1.4 1.3 -1.2 to 4.3 -1.3 to 3.8 4.7 4.6 3.7 to 5. 6 3 .5 to 5. 3 1.4 1.4 1.2 to 1.6 1.2 to 1.6 1.8 1.9 1.2 to 2.3 1 .5 to 2 .5 142 141 127 to 168 121 to 1 65 5.3 5. 6 4.7 to ... blood (14.4% vs 3 .5% ; P = 0.011) The ARF rate was 5. 2% in patients receiving older blood and 0.8% in patients receiving newer blood (P = 0. 154 ), and the rate of infectious complications was 5. 5%...
... 35 r = 0.674 p < 0.001 30 25 20 15 10 15 20 25 30 35 40 45 RBC AGGREGATION INDEX (3% DEXTRAN 70) 50 Figure 1 .5: Relationship between the extents of redbloodcell aggregation for human redblood ... heterogeneity of redblood cells distribution in the network by triggering the effects of redbloodcell screening (103) and plasma skimming (53 , 122) shown in Fig 1.10 CELL SCREENING Cell- cell interactions ... SKIMMING Cell- free layer Side branch Figure 1.10: Redbloodcell screening and plasma skimming at an arteriolar bifurcation The black ellipsoid represents a redbloodcellRedbloodcell screening...
... µm, 48.9 -52 .5 µm and 98.7-102 .5 µm for microtubes of ID 30 µm, 50 µm and 100 µm respectively The length of microtubes was measured by vernier caliper and ranged between 49 .5 and 50 .5 mm The ratio ... of normal aggregating blood at normal arteriolar pseudoshear rate of approximate 200 s-1 were 2. 95 ± 0. 15 Pa, 3.91 ± 0.32 Pa and 5. 55 ± 0 .59 Pa in microtubes of ID 30 µm, 50 µm and 100 µm respectively, ... disease aggregating blood (2. 15 ± 0.23) was significantly lower than that in normal aggregating blood (2 .59 ± 0.19, P < 0. 05) and that in non-aggregating blood (2.60 ± 0.20, P < 0. 05) It was noted...
... independent methods bloodcell count RBCs (n =5) (cells/µL) cytometer white blood cells platelets (cells/µL) (cells/µL) 6600000±2000 n.d.* n.d.* FACS 6300000± 152 0 n.d.* n.d.* blood slide 6400000±120 ... spectrometry Journal of Proteome Research 20 05; 4:748- 757 Shelby MD A simplified and rapid method for scoring micronucleated erythrocytes in human blood Mutat.Res 2002 ;51 5:1 Dertinger SD, Camphausen K, Macgregor ... with radioiodine for thyroid cancer Mutat.Res 20 05; 583:12- 25 Miller JL A genome-based approach for the study of erythroid biology and disease Blood Cells.Mol.Dis 2004;32:341-343 Denis MM, Tolley...
... GlcNAc -5, GlcNAc -5 , galactose (Gal)-6, Gal-6¢ and Gal-8 appear in the range 4.40–4. 75 p.p.m (Table S1) Specifically, the anomeric proton of GlcNAc-2 appears at 4.62 p.p.m.; the GlcNAc -5 and GlcNAc -5 ... GlcNAc -5 anomeric protons appear at 4 .56 –4 .59 p.p.m The signal at 4 .54 p.p.m can be attributed to the anomeric proton of GlcNAc-7; however, the absence of a signal at 5. 56 p.p.m (which would be assigned ... was largely 52 1704 50 48 46 44 F2 (p.p.m.) Fig HSQC-spectra of N-glycans from cRBCs The spectrum shows the cross peaks between the anomeric protons (5. 25 4.30 p.p.m.) and carbon (89–1 05 p.p.m.)...
... Homocysteine and redblood cells 2.1 Redblood cells oxidative-reducing balance Redblood cells are responsible for oxygen transport from lung to tissues Their function depends on reduced state ... Model 155 Terry E Moschandreou VI Contents Section Measurement of RBC Deformability and Microfluidics Technology for Cell Separation 1 65 Chapter 10 Measurement Techniques for RedBloodCell Deformability: ... http://dx.doi.org/10 .57 72/4 859 3 Introduction The only identifiable function of RedBlood Cells (RBC) is the delivery of Oxygen In mammals, RBC is a unique cell because: It does not have cellular organelles...