Consequences of hemolysis: Pro-inflammatory cytokine response to erythrophagocytosis.

Red blood cells (RBCs) can be cleared from the circulation either intravascularly or extravascularly. In the setting of an IgG-mediated delayed hemolytic transfusion reaction (HTR), most RBC clearance is typically extravascular, presumably by phagocytosis by liver and splenic macrophages. Animal models of HTRs suggest that this RBC clearance is associated with a pro-inflammatory cytokine response. Although IgG-mediated HTRs are typically benign, they can lead to vaso-occlusive crises and further complications, such as hyperhemolysis, in patients with sickle cell disease (SCD). Why the manifestations of HTRs are more severe in the setting of SCD has yet to be determined; however, in this symposium paper, we provide a review of the evidence that robust RBC phagocytosis results in a pro-inflammatory cytokine response, which may induce vaso-occlusive crises and further complications in the setting of SCD.

Automated cell counts on CSF samples: A multicenter performance evaluation of the GloCyte system.

OBJECTIVES: Automated cell counters have replaced manual enumeration of cells in blood and most body fluids. However, due to the unreliability of automated methods at very low cell counts, most laboratories continue to perform labor-intensive manual counts on many or all cerebrospinal fluid (CSF) samples. This multicenter clinical trial investigated if the GloCyte System (Advanced Instruments, Norwood, MA), a recently FDA-approved automated cell counter, which concentrates and enumerates red blood cells (RBCs) and total nucleated cells (TNCs), is sufficiently accurate and precise at very low cell counts to replace all manual CSF counts. METHODS: The GloCyte System concentrates CSF and stains RBCs with fluorochrome-labeled antibodies and TNCs with nucleic acid dyes. RBCs and TNCs are then counted by digital image analysis. Residual adult and pediatric CSF samples obtained for clinical analysis at five different medical centers were used for the study. Cell counts were performed by the manual hemocytometer method and with the GloCyte System following the same protocol at all sites. The limits of the blank, detection, and quantitation, as well as precision and accuracy of the GloCyte, were determined. RESULTS: The GloCyte detected as few as 1 TNC/µL and 1 RBC/µL, and reliably counted as low as 3 TNCs/µL and 2 RBCs/µL. The total coefficient of variation was less than 20%. Comparison with cell counts obtained with a hemocytometer showed good correlation (>97%) between the GloCyte and the hemocytometer, including at very low cell counts. CONCLUSIONS: The GloCyte instrument is a precise, accurate, and stable system to obtain red cell and nucleated cell counts in CSF samples. It allows for the automated enumeration of even very low cell numbers, which is crucial for CSF analysis. These results suggest that GloCyte is an acceptable alternative to the manual method for all CSF samples, including those with normal cell counts.

Analysis of 24-h recovery of transfused stored RBCs in recipient mice of distinct genetic backgrounds.

BACKGROUND AND OBJECTIVES: Human studies have demonstrated substantial donor-to-donor variation in refrigerated RBC storage with respect to several variables, including 24-h post-transfusion RBC recovery. However, the human studies leading to these observations are mostly performed using autologous transfusions of stored RBCs, thereby avoiding issues of infectious disease transmission and alloimmunization. Accordingly, one cannot distinguish whether variability in 24-h RBC recovery is due to alterations in RBC storage, differences in phagocytic activity of the recipient's reticuloendothelial system or both. Similar to humans, genetically distinct inbred mouse strains have substantial differences in RBC storage biology, including 24-h post-transfusion RBC recovery. MATERIALS AND METHODS: In this report, we juxtaposed 24-h recoveries in 15 distinct inbred strains of mice, holding the RBC donor constant to isolate transfusion recipient variation as an independent variable. Strains were chosen for differences in baseline reticulocyte count and haemoglobin, which may correlate to RBC life span and turnover. RESULTS: Unlike large differences observed in storage of RBCs obtained from different strains of mice, only subtle strain-to-strain differences were observed regarding 24-h post-transfusion RBC recoveries. CONCLUSIONS: These findings indicate that the murine strains examined are not likely to be useful in sorting out mechanisms of clearance of stored RBCs, and suggest that such mechanisms may be generally conserved in the strains of mice analysed.

CD59 signaling and membrane pores drive Syk-dependent erythrocyte necroptosis.

Mature erythrocytes (red blood cells (RBCs)) undergo the programmed cell death (PCD) pathway of necroptosis in response to bacterial pore-forming toxins (PFTs) that target human CD59 (hCD59) but not hCD59-independent PFTs. Here, we investigate the biochemical mechanism of RBC necroptosis with a focus on the mechanism of induction and the minimal requirements for such RBC death. Binding or crosslinking of the hCD59 receptor led to Syk-dependent induction of vesiculated morphology (echinocytes) that was associated with phosphorylation of Band 3 and was required for Fas ligand (FasL) release. FasL-dependent phosphorylation of receptor-interacting protein kinase 1 (RIP1) in combination with plasma membrane pore formation was required for execution of RBC necroptosis. RIP1 phosphorylation led to the phosphorylation of RIP3, which was also critical for RBC necroptosis. Notably, RBC necroptosis was mediated by FasL and not by other candidate inducers, including tumor necrosis factor alpha (TNF-α) and TNF-related apoptosis-inducing ligand (TRAIL). Other types of RBC damage, such as eryptotic damage, failed to induce necroptosis when combined with hCD59 crosslinking. This work sheds light on the requirements for this recently discovered PCD in RBCs and provides a clear picture of the biochemical mechanism of induction of RBC necroptosis.

Glucose-6-phosphate dehydrogenase deficiency in transfusion medicine: the unknown risks.

The hallmark of glucose-6-phosphate dehydrogenase (G6PD) deficiency is red blood cell (RBC) destruction in response to oxidative stress. Patients requiring RBC transfusions may simultaneously receive oxidative medications or have concurrent infections, both of which can induce haemolysis in G6PD-deficient RBCs. Although it is not routine practice to screen healthy blood donors for G6PD deficiency, case reports identified transfusion of G6PD-deficient RBCs as causing haemolysis and other adverse events. In addition, some patient populations may be more at risk for complications associated with transfusions of G6PD-deficient RBCs because they receive RBCs from donors who are more likely to have G6PD deficiency. This review discusses G6PD deficiency, its importance in transfusion medicine, changes in the RBC antioxidant system (of which G6PD is essential) during refrigerated storage and mechanisms of haemolysis. In addition, as yet unanswered questions that could be addressed by translational and clinical studies are identified and discussed.

Transfusion of 28-day-old leucoreduced or non-leucoreduced stored red blood cells induces an inflammatory response in healthy dogs.

BACKGROUND AND OBJECTIVES: Studies in mice suggest that rapid transfusions of red blood cells (RBCs), refrigerator stored for longer durations, induce a pro-inflammatory cytokine response. Studies in human neonates confirm these findings; however, to date, adult human studies have failed to replicate these findings. We used healthy research dogs to begin to examine the factors affecting the cytokine response to transfusion. MATERIALS AND METHODS: In a prospective study, healthy dogs were randomized for two autologous packed RBC transfusions after 7 (i.e. 'fresh') and 28 (i.e. 'old') days of storage, or after 28 and 7 days of storage, with or without prestorage leucoreduction (LR). RESULTS: No significant differences were observed between LR and non-LR transfusions for all circulating analytes measured following transfusion. A pro-inflammatory cytokine response, exemplified by monocyte chemoattractant protein-1, was observed 6 h after only old RBC transfusions, irrespective of infusion rate (P < 0·001). This response was accompanied by increased neutrophil counts (P < 0·001) and decreased platelet counts (P < 0·001). CONCLUSION: In healthy dogs, old RBC transfusions induce inflammation, which is unaffected by infusion rate.

Stored red blood cell transfusions: Iron, inflammation, immunity, and infection.

The potential adverse effects of transfusion of red blood cells after prolonged storage have been hotly debated. During refrigerated storage, red blood cells are damaged, a process known as the red blood cell "storage lesion." We hypothesized that the delivery of a bolus of iron derived from these rapidly cleared, damaged, red blood cells is responsible for some of the adverse effects of transfusion. Iron may play a role in producing a pro-inflammatory response to transfused red blood cells, potentially through the effects of reactive oxygen species on stress pathways and inflammasome activation. Furthermore, the excess iron may impair the host's ability to combat infection by its innate iron-withholding pathways. This symposium paper summarizes the background for the "iron hypothesis" as it relates to transfusion of red blood cells after prolonged refrigerated storage. It also includes a summary of the data from recent murine and human studies, and concludes with a discussion of several unresolved questions arising from these published studies.

Use of mouse models to study the mechanisms and consequences of RBC clearance.

Mice provide tractable animal models for studying the pathophysiology of various human disorders. This review discusses the use of mouse models for understanding red-blood-cell (RBC) clearance. These models provide important insights into the pathophysiology of various clinically relevant entities, such as autoimmune haemolytic anaemia, haemolytic transfusion reactions, other complications of RBC transfusions and immunomodulation by Rh immune globulin therapy. Mouse models of both antibody- and non-antibody-mediated RBC clearance are reviewed. Approaches for exploring unanswered questions in transfusion medicine using these models are also discussed.