The pro-inflammatory potential of microparticles in red blood cell units.

BACKGROUND: Microparticles (MPs) are submicron size cell fragments that are released from cells. OBJECTIVES: We hypothesise that MPs increase during red blood cell (RBC) storage and are part of the pro-inflammatory activity, which accumulates in the RBC supernatant. METHODS/MATERIALS: RBC units were separated from whole blood of eight healthy donors: 5 U were split, with 50% undergoing leucoreduction (LR) and the remaining left as unmodified controls. The remaining 3 U were leucoreduced. Samples were obtained at days (D) 1 and 42 and cell-free supernatants separated and stored. The supernatants were centrifuged at 17 000 × g (60 min) or 100 000 × g (120 min) into microparticle-rich (MPR) and microparticle-poor (MPP) portions, resuspended in albumin, incubated with antibodies to CD235 (RBCs), CD45 [white blood cells (WBCs)] and CD41a [platelets (Plts)], and analysed by flow cytometry. Isolated neutrophils were incubated with these samples, and priming activity measured. RESULTS: Total MPs increased during storage; however, MPs that marked for precursor cell types did not. Significant priming accumulated in the MPP fraction during storage with some activity present in the MPR fraction from D1 and D42 LR-RBCs. CONCLUSION: Most of the pro-inflammatory priming activity from stored RBCs resides in the MPP supernatant, although the MPR fraction from D42 LR-RBCs does contain some priming activity.

Antibodies to the HLA-A2 antigen prime neutrophils and serve as the second event in an in vitro model of transfusion-related acute lung injury.

BACKGROUND: Transfusion-related acute lung injury (TRALI) is the most common cause of transfusion-related mortality and has been linked to the infusion of donor antibodies directed against recipient HLA class I antigens. We hypothesize that antibodies against HLA class I antigens bind to the antigens on the neutrophil (PMN) surface and induce priming and PMN cytotoxicity as the second event in a two-event in vitro model of PMN-mediated cytotoxicity. METHODS: Isolated PMNs from HLA-A2 homozygotes, heterozygotes and null donors were incubated with a monoclonal antibody to HLA-A2 and a human polyclonal IgG to HLA-A2 and priming of the oxidase was measured. The monoclonal antibodies and PMNs from these three groups were then used in a two-event model of PMN cytotoxicity. RESULTS: The antibodies to HLA-A2 both primed PMNs from HLA-A2 homozygotes but not from heterozygotes or nulls. Antibodies to HLA-A2 also served as the second event in a two-event model to induce PMN cytotoxicity of HLA-A2 homozygous PMNs. CONCLUSION: Antibodies to HLA class I antigens may directly prime/activate PMNs through the ligation of the antigen on the cell surface, and the antigen density appears to be important for these changes in PMN physiology.

Proteomic analysis of the supernatant of red blood cell units: the effects of storage and leucoreduction.

BACKGROUND: Red blood cell (RBC) transfusion is a life-saving intervention for critically ill patients; however, it has been linked to increased morbidity and mortality. We hypothesize that a number of important proteins accumulate during routine storage of RBCs, which may explain some of the adverse effects seen in transfused patients. STUDY DESIGN: Five RBC units were drawn and divided (half prestorage leucoreduced (LR-RBC) and half left as an unmodified control (RBC). The supernatant was separated on days 1 and 42 of storage and proteomic analyses completed with in-gel tryptic digestion and nano-liquid chromatography tandem mass spectrometry. RESULTS: In RBC supernatants, 401 proteins were identified: 203 increased with storage, 114 decreased, and 84 were unchanged. In LR-RBC supernatant, 231 proteins were identified: 84 increased with storage, 30 decreased, and 117 were unchanged. Prestorage leucoreduction removed many platelet- and leucocyte-derived structural proteins; however, a number of intracellular proteins accumulated including peroxiredoxins (Prdx) 6 and latexin. The increases were confirmed by immunoblotting, including the T-phosphorylation of Prdx-6, indicating that it may be functioning as an active phospholipase. Active matrix metalloproteinase-9 also increased with a coinciding decrease in the metalloproteinase inhibitor 1 and cystatin C. CONCLUSION: We conclude that a number of proteins increase with RBC storage, which is partially ameliorated with leucoreduction, and transfusion of stored RBCs may introduce mediators that result in adverse events in the transfused host.

The pro-inflammatory effects of platelet contamination in plasma and mitigation strategies for avoidance.

BACKGROUND AND OBJECTIVES: Plasma and platelet concentrates are disproportionately implicated in transfusion-related acute lung injury (TRALI). Platelet-derived pro-inflammatory mediators, including soluble CD40 ligand (sCD40L), accumulate during storage. We hypothesized that platelet contamination induces sCD40L generation that causes neutrophil [polymorphonuclear leucocyte (PMN)] priming and PMN-mediated cytotoxicity. MATERIALS AND METHODS: Plasma was untreated, centrifuged (12,500 g) or separated from leucoreduced whole blood (WBLR) prior to freezing. Platelet counts and sCD40L concentrations were measured 1-5 days post-thaw. The plasma was assayed for PMN priming activity and was used in a two-event in vitro model of PMN-mediated human pulmonary microvascular endothelial cell (HMVEC) cytotoxicity. RESULTS: Untreated plasma contained 42±4·2×10(3)/µl platelets, which generated sCD40L accumulation (1·6-eight-fold vs. controls). Priming activity and HMVEC cytotoxicity were directly proportional to sCD40L concentration. WBLR and centrifugation reduced platelet and sCD40L contamination, abrogating the pro-inflammatory potential. CONCLUSION: Platelet contamination causes sCD40L accumulation in stored plasma that may contribute to TRALI. Platelet reduction is potentially the first TRALI mitigation effort in plasma manufacturing.

Mirasol Pathogen Reduction Technology treatment does not affect acute lung injury in a two-event in vivo model caused by stored blood components.

INTRODUCTION: Mirasol Pathogen Reduction Technology (PRT) treatment uses riboflavin and UV light to inactivate pathogens in blood components. Neutrophil [polymorphonuclear cells (PMN)] priming activity accumulates during routine storage of cellular blood components, and this activity has been implicated in transfusion-related acute lung injury (TRALI). We hypothesize that PRT-treatment of blood components affects the priming activity generated during storage of packed RBCs (PRBCs) or platelet concentrates (PCs), which can elicit ALI in vivo. METHODS: Plasma, PRBCs and PCs were isolated from healthy donor's whole blood or by apheresis. Half of a collected unit was treated with PRT treatment and the remainder was left as an unmodified control. Supernatant was collected during storage of PCs and PRBCs and assayed for PMN priming activity and used as the second event in a two-event in vivo model of TRALI. RESULTS: PRT treatment did not induce priming activity in plasma or affect the priming activity generated during storage of PCs or PRBCs as compared with the unmodified controls. The supernatants from stored, but not fresh, PCs and PRBCs did cause ALI as the second event in a two-event animal model of TRALI, which was unaffected by PRT treatment. We conclude that the PRT treatment does not induce priming activity in plasma nor does it affect the priming activity generated during storage of PCs or PRBCs or their ability to cause ALI as the second event in a two-event in vivo model of TRALI. Moreover, the amount of priming activity in TRIMA-isolated PCs was significantly less than SPECTRA-isolated PCs.

Hypotension and acute pulmonary insufficiency following transfusion of autologous red blood cells during surgery: a case report and review of the literature.

Transfusion of autologous blood is associated with fewer complications, although all untoward events of transfusion may not be negated with this strategy. We report a case of acute pulmonary insufficiency and hypotension following transfusion of autologous packed red blood cells (PRBCs) in a patient, who was undergoing major surgery. Anti-HLA class-I and class-II and anti-granulocyte antibodies were measured in the unit and in the recipient. Neutrophil (PMN)-priming activity was measured as the augmentation of the formyl-Met-Leu-Phe-activated respiratory burst. No immunoglobulins were identified; however, significant lipid-priming activity was present in the implicated, autologous PRBC unit that primed PMNs from both healthy people and the recipient. In addition, lipids, identical to those that accumulate during PRBC storage, caused significant hypotension when infused into rats at similar concentrations found in stored PRBCs. We conclude that the observed transfusion-related acute lung injury reaction with significant hypotension may be the result of two independent events: the first is related to inherent host factors, in this case major surgery, and the second is the infusion of lipids that accumulate during the routine storage of PRBCs.