The transfusion of neutrophil‐specific antibodies causes leukopenia and a broad spectrum of pulmonary reactions

Self Cite

288

192

The beginning of the modern era of blood transfusion coincided with World War II and the resultant need for massive blood replacement. Soon thereafter, the hazards of transfusion, particularly hepatitis and hemolytic transfusion reactions, became increasingly evident. The past half century has seen the near eradication of transfusion-associated hepatitis as well as the emergence of multiple new pathogens, most notably HIV. Specific donor screening assays and other interventions have minimized, but not eliminated, infectious disease transmission. Other transfusion hazards persist, including human error resulting in the inadvertent transfusion of incompatible blood, acute and delayed transfusion reactions, transfusion-related acute lung injury (TRALI), transfusion-associated graft-versus-host disease (TA-GVHD), and transfusion-induced immunomodulation. These infectious and noninfectious hazards are reviewed briefly in the context of their historical evolution.

Section: Transfusion-related Acute Lung Injurymentioning

confidence: 99%

The hazards of blood transfusion in historical perspective

Alter

Klein

2008

Self Cite

288

192

“…6,10,14 These data are to be expected if one examines human alloimmune neutropenia in which maternal antibodies cross the placenta and immunodeplete the PMNs in the fetus or following transfusion of donor antibodies that bind to the PMNs of the recipient and cause immunodepletion, termed transfusion-related alloimmune neutropenia (TRAIN). [53][54][55] Alloimmune neutropenia is dependent upon the type of the antibody or the antigen recognized. Antibodies that prime PMNs through antigen recognition (eg, induce a proinflammatory change) may lead to TRALI and not antibody-mediated clearance, as shown in the presented model.…”

mentioning

confidence: 99%

Plasma from stored packed red blood cells and MHC class I antibodies causes acute lung injury in a 2-event in vivo rat model

Kelher

Masuno

Moore

et al. 2009

141

276

Transfusion-related acute lung injury (TRALI) is the leading cause of transfusion death. We hypothesize that TRALI requires 2 events: (1) the clinical condition of the patient and (2) the infusion of antibodies against MHC class I antigens or the plasma from stored blood. A 2-event rat model was developed with saline (NS) or endotoxin (LPS) as the first event and the infusion of plasma from packed red blood cells (PRBCs) or antibodies (OX18 and OX27) against MHC class I antigens as the second event. ALI was determined by Evans blue dye leak from the plasma to the bronchoalveolar lavage fluid (BALF), protein and CINC-1 concentrations in the BALF, and the lung histology. NS-treated rats did not evidence ALI with any second events, and LPS did not cause ALI. LPS-treated animals demonstrated ALI in response to plasma from stored PRBCs, both prestorage leukoreduced and unmodified, and to OX18 and OX27, all in a concentration-dependent fashion. ALI was neutrophil (PMN) dependent, and OX18/OX27 localized to the PMN surface in vivo and primed the oxidase of rat PMNs. We conclude that TRALI is the result of 2 events with the second events consisting of the plasma from stored blood and antibodies that prime PMNs. IntroductionTransfusion-related acute lung injury (TRALI) is the leading cause of transfusion mortality in the United States. 1,2 TRALI is the acute onset of noncardiogenic pulmonary edema as documented by chest radiograph and profound hypoxemia, in accordance with the definition of acute lung injury (ALI), that occurs within 6 hours of transfusion. 3,4 TRALI may occur with or without conditions that predispose the patient to ALI, and may be the worsening of pulmonary function in patients with preexisting ALI. 3,4 All blood products have been implicated in TRALI, but components that contain large amounts of plasma are mainly responsible. 5,6 The current incidence of TRALI has been estimated as 1/7900 to 1/1330 in the United Kingdom and the United States with lesser incidences in Europe. [5][6][7][8] Current mortality rates vary from 5% to 35% with the lesser mortality rates predominating. [5][6][7][8] The pathophysiology of TRALI has not been elucidated despite numerous studies. [9][10][11][12][13][14] The first mechanism proposed was the infusion of donor antibodies directed against the HLA class I or granulocyte-specific antigens on the recipient's leukocytes with animal models composed of an in vivo murine model and an isolated, perfused rabbit lung that provided physiologic relevance. [9][10][11][12]14 In addition, the neutrophil (PMN) was proposed to be the effector cell, identical to other forms of ALI and the acute respiratory distress syndrome (ARDS). [9][10][11][12]14 However, look-back studies of donors with specific antibodies directed against HLA or granulocyte antigens demonstrated that the infusion of donor antibodies into a recipient that expressed the cognate antigen resulted in TRALI in a minority of these patients, implying that the clinical condition of the recipient may be important for the d...

“…7,20,21 The higher fatality association was demonstrated in a study by Reil et al, who reported 36 TRALI cases, 12 of which were attributable to HNA antibodies (Table 1). 7 Of these, 10 were attributable to HNA-3a antibodies, and 6 of the 10 cases were fatal.…”

Section: Hna-3a Antibodies and Tralimentioning

confidence: 82%

Spotlight on pathogenesis of TRALI: HNA-3a (CTL2) antibodies

Storch

Hillyer

Shaz

2014

Human neutrophil antigen-3a (HNA-3a) antibodies contained in donor plasma can result in severe, sometimes fatal transfusion-related acute lung injury (TRALI). Recent developments in TRALI secondary to antibodies to HNA-3a antigen span diagnosis, pathophysiology, treatment, and prevention resulting in improved understanding, potential treatments, and mitigation strategies. First, on the molecular level, characterization of HNA-3 antigen has allowed for genotyping methods that clarify population prevalence. Related work has led to generation of multiple antibody detection assays. These assays aid in determining potential populations at risk and potential mitigation strategies. Second, the development of TRALI requires a hit from the patient and from the product. Anti-HNA-3a is one of the product-derived factors and appears to result in TRALI by binding directly to pulmonary endothelium as well as to neutrophils expressing the corresponding antigen. Finally, potential mitigation strategies include red blood cell product filtration to remove anti-HNA-3a as well as other antibodies.