P48Molecular Characterisation of the Variable Domains of an ΑIIbβ3 Specific IgM κ Platelet Cold Agglutinin in a Follicular Lymphoma Patient with Treatment Refractory Thrombocytopenia

Cold agglutinins (CA) were originally defined as IgM κ antibodies capable of agglutinating erythrocytes at temperatures below 37°C and cold haemagglutinin disease may ensue in patients with high titre cold agglutinins at low environmental temperature. Platelet CA are rare and have been poorly characterised. We present the first molecular characterisation of a pathological, platelet reactive, CA. This antibody was identified in a patient with follicular lymphoma (FL) who had profound, refractory, thrombocytopenia that resolved in response to Rituximab. Serological and molecular studies of this IgM κ that recognises αIIbβ3 shows that binding is temperature dependent but independent of the integrin activation state. The VH1-02 and Vλ3-20 encoded variable domains of the heavy and light chains have characteristics typical of a low affinity autoantibody. Maldi-Tof analysis of the platelet reactive IgM showed unequivocally that the IgM was derived from the FL clone. Interestingly we observed idiotypic cross-reactivity between this IgM paraprotein, several other FL idiotypes and our β3-leucine 33 (HPA-1a) specific human recombinant antibody. Our results suggest that binding of the latter and other αIIbβ3 specific monoclonal antibodies induces a subtle conformational change that enhances platelet binding of the patient IgM.     

Heterogeneity of HPA-3 alloantibodies: consequences for the diagnosis of alloimmune thrombocytopenic syndromes

BACKGROUND: Immunization against the human platelet alloantigen (HPA)-3a residing on alphaIIbbeta3 integrin accounts for approximately 2 percent of fetal and neonatal alloimmune thrombocytopenia (FNAIT). Anti-HPA-3a alloantibodies are sometimes difficult to detect and can be overlooked by standard antigen capture assays. STUDY DESIGN AND METHODS: The reactivity of 12 anti-HPA-3a and 2 anti-HPA-3b alloantibodies from patients with FNAIT and posttransfusion purpura was analyzed by serologic (monoclonal antibody-specific immobilization of platelet antigens [MAIPA] assay, flow cytometry) and immunochemical (immunoprecipitation, immunoblotting) techniques. The influence of platelet (PLT) age, storage conditions, recombinant antigens from Chinese hamster ovary (CHO) cells, and sialic acids (treatment with neuraminidase) were analyzed. RESULTS: The most sensitive anti-HPA-3 alloantibody detection in MAIPA assay could be achieved with fresh homozygous PLTs. During a PLT storage period of 14 days before use, three types of anti-HPA-3 alloantibodies were found: 1) complete loss of reactivity (n = 6), 2) considerably weakened reaction (> or =50% reduction; n = 3), and 3) minor reduction of reactivity (< or =40% decrease; n = 5). When cryopreserved PLTs were used, 10 of 12 anti-HPA-3a and all anti-HPA-3b alloantibodies reacted positive. Only 6 of 10 serum samples reacted with recombinant HPA-3a on CHO cells. Neuraminidase treatment of PLTs showed that some anti-HPA-3a alloantibodies require the presence of sialic acids. The storage lesion seems to be related to cleavage of sialic acids. Immunochemical analysis revealed evidence that most anti-HPA-3a alloantibodies require an intact three-dimensional alphaIIbbeta3 integrin structure. CONCLUSIONS: Anti-HPA-3 alloantibodies show considerable heterogeneity, which may hamper the serologic diagnosis of FNAIT. Preservation of the alphaIIbbeta3 integrin and protection from enzymatic degradation seem to be important during PLT storage.     

Quantitation of coated platelet potential during collection, storage, and transfusion of apheresis platelets

BACKGROUND: Coated platelets (PLTs), a subpopulation of PLTs observed upon dual agonist stimulation with collagen and thrombin, are known to retain several procoagulant α‐granule proteins on their surface. By formation of a highly active membrane‐bound prothrombinase complex, these PLTs represent an important step in the coagulation cascade as a consequence of their ability to generate thrombin at the site of vascular injury. Various clinical observations suggest that higher levels of coated PLTs are associated with thrombosis while a deficiency of coated PLTs results in a bleeding diathesis. Current quality control guidelines for in vitro PLT storage measure PLT viability but no routine evaluation of the hemostatic function of stored PLTs and particularly no estimation of coated PLT potential is performed. Our primary objective was to evaluate if the process of apheresis and storage of PLT units alters the levels of coated PLTs. In addition, we sought to determine how transfusion of stored PLTs into patients with thrombocytopenia affects the patient's coated PLT levels. STUDY DESIGN AND METHODS: Coated PLT levels were analyzed in 13 voluntary PLT donors before donation, in the fresh apheresis product (Trima, CaridianBCT) and in the stored apheresis product just before transfusion. In addition, 10 patients with thrombocytopenia were analyzed for coated PLTs before and after transfusion of a stored PLT product. RESULTS: Coated PLT levels were significantly decreased after the process of apheresis (17% relative decline; p < 0.01) and with prolonged storage (1 to 5 days; 53% relative decline; p < 0.001). Transfusion of stored PLT units did not result in significant increment of coated PLT levels in patients with thrombocytopenia as expected considering the low level of coated PLTs in stored PLT units. Furthermore, there was no suggestion of regeneration of coated PLT potential upon reinfusion. CONCLUSIONS: Isolation and storage of apheresis PLTs by standard blood bank procedures results in a significant decline in coated PLT potential. Reinfusion of stored apheresis PLTs into patients with thrombocytopenia resulted in a predictable change in coated PLT potential with no suggestion of regeneration of lost coated PLT potential.     

Severe neonatal alloimmune thrombocytopenia caused by antibodies to human platelet antigen 3a (Baka) detectable only in whole platelet assays

BACKGROUND: Maternal antibodies that cause neonatal alloimmune thrombocytopenia are commonly identified by solid-phase assays that detect the causative antibodies on the basis of their reactions with specific PLT glycoproteins. Two cases of severe neonatal alloimmune thrombocytopenia caused by maternal antibodies specific for human PLT antigen 3a (HPA-3a [Baka]) that failed to give the expected reactions in some solid-phase assays were recently encountered. STUDY DESIGN AND METHODS: PLT-reactive antibodies were characterized by three different solid-phase assays and by flow cytometry. RESULTS: The two maternal antibodies gave negative reactions in the antigen capture ELISA, modified antigen capture ELISA, and MoAb immobilization of PLT antigens tests but reacted strongly in flow cytometry with intact PLTs that were HPA-3a+. Other sera samples specific for HPA-3a reacted equally well in all assays. CONCLUSIONS: The two antibodies appear to recognize an epitope on the HPA-3a+ form of glycoprotein IIb that is lost when PLTs are solubilized in detergent, as required for solid-phase assays. The diagnosis was made in these cases because no HLA antibodies were present, allowing an HPA-3a-specific reaction to be identified with intact PLTs as targets. Such antibodies are likely to be overlooked when HLA antibodies are also present.     

IgA cold agglutinins recognize Pr and Sa antigens expressed on glycophorins

Three cases of IgA kappa cold agglutinins (CAs) were studied. One had anti-Pr1 specificity, one had anti-Pra, and one had anti-Sa. The CAs recognize O-glycans of glycophorins. The findings supplement previous data on anti-Pr1 specificities of four IgA kappa CAs. Because all IgA kappa CAs described recognize O-glycans of glycophorins, a close association between the CA IgA isotype and specificities for O-glycans becomes apparent. It is unlikely, however, that the striking association reflects interrelations between IgA CA structure and specificity, because anti-Sa specificity and all anti-Pr subspecificities were originally defined with IgM CAs.     

Increased local procoagulant action: a mechanism contributing to the favorable hemostatic effect of recombinant FVIIa in PLT disorders

BACKGROUND: Recombinant FVIIa (rFVIIa) has been shown to improve hemostasis in patients with thrombocytopenia and to prevent or control bleeding episodes in patients with inherited deficiencies of major PLT glycoproteins, but the mechanism of action is not well understood. STUDY DESIGN AND METHODS: Effects of rFVIIa on hemostasis were explored with an in vitro perfusion technique. Blood samples, from healthy donors or from patients with congenital defects of PLT glycoprotein IIb-IIIa (GPIIb-IIIa), were anticoagulated with low-molecular-weight heparin. Experimental thrombocytopenia (<6000 PLTs/microL) was induced by a filtration procedure. rFVIIa was added to blood samples at therapeutic concentrations. A severe GPIIb-IIIa impairment was also induced by exposure of normal blood samples to a specific antibody. Perfusion studies were performed through annular chambers containing damaged vascular segments. The presence of fibrin and PLTs on the perfused subendothelium was morphometrically quantified. RESULTS: Under conditions of experimental thrombocytopenia, addition of rFVIIa enhanced fibrin formation in a dose-dependent manner (p < 0.05). Improvements in local fibrin generation and partial restoration of PLT interactions were also observed after incubation of blood from patients with Glanzmann's thrombasthenia with rFVIIa at 5 microg per mL (180 microg/kg). Similar improvements were observed in blood samples incubated with antibodies to GPIIb-IIIa. rFVIIa in whole normal blood also enhanced fibrin formation but PLT deposition was unaffected. Evaluation of prothrombin fragments 1 and 2 in the perfusates confirmed that rFVIIa increased thrombin generation in all cases. CONCLUSION: Our data indicate that rFVIIa promotes a procoagulant activity at sites of vascular damage. This mechanism could explain the beneficial hemostatic effect of rFVIIa in patients with thrombocytopenia or with Glanzmann's thrombasthenia.     

Toward a prophylaxis against fetal and neonatal alloimmune thrombocytopenia: induction of antibody-mediated immune suppression and prevention of severe clinical complications in a murine model

BACKGROUND: Fetal and neonatal alloimmune thrombocytopenia (FNAIT) is a severe bleeding disorder caused by maternal antibody–mediated destruction of fetal or neonatal platelets (PLTs). Results from our recent large screening study suggest that the pathophysiology of FNAIT is more similar to hemolytic disease of the fetus and newborn (HDFN) than previously thought. Immunization against HPA‐1a might therefore be preventable by a prophylactic regimen of inducing antibody‐mediated immune suppression (AMIS), which has been documented to be a useful prophylaxis against HDFN. This preclinical proof‐of‐concept study investigated whether passive administration of anti‐β3 integrin could induce AMIS and thereby prevent clinical complications of FNAIT. STUDY DESIGN AND METHODS: A murine model of FNAIT using β3 integrin (GPIIIa)‐deficient (β3?/?) mice was employed for this study. AMIS in β3?/? mice was induced by intravenous administration of human anti‐HPA‐1a immunoglobulin G or murine anti‐β3 antisera given as prophylaxis after transfusion of HPA‐1a–positive human PLTs or murine wild‐type PLTs, respectively. RESULTS: AMIS against both human and murine PLT antigens was induced using this prophylactic approach, reducing the amount of maternal PLT antibodies by up to 90%. Neonatal PLT counts were significantly increased and pregnancy outcome was improved in a dose‐dependent manner. The incidence of intracranial hemorrhage, miscarriage, and dead‐born pups in mice receiving high‐dose prophylaxis was reduced to that of normal controls. We also observed that the severity of thrombocytopenia inversely correlated with birth weight. CONCLUSION: This work conceptually proves that prophylactic administration of PLT antibodies induces AMIS and prevents poor pregnancy outcome in FNAIT.     

Relevance of the HPA-15 (Gov) polymorphism on CD109 in alloimmune thrombocytopenic syndromes

BACKGROUND: Alloantibodies against the human platelet (PLT) alloantigen (HPA)-15 system residing on CD109 can cause fetal and neonatal alloimmune thrombocytopenia (FNAIT), posttransfusion purpura, and PLT transfusion refractoriness. The detection of antibodies against HPA-15, however, is hampered by the variable low expression and instability of the CD109 molecule during preparation and storage. STUDY DESIGN AND METHODS: This study analyzed the occurrence of HPA-15 alloantibodies in 1403 patients: 930 FNAIT and 473 polytransfused (PT) patients by modified monoclonal antibody specific immobilization of PLT antigens (MAIPA) assay with well-defined phenotyped PLTs. A DNA typing technique was developed to confirm the phenotypes of PLT donors. B-cell lines were established as sources of reference DNA. RESULTS: Genotyping of 407 unrelated blood donors revealed the gene frequencies 0.512 and 0.488 for HPA-15a and -15b, respectively. Based on the selection of PLTs expressing high amounts of CD109 on the surface (mean fluorescence intensity ratio 4-5 on expression peak on Days 2-4 after apheresis) antibody screening by the MAIPA assay was performed. In total, 16 (1.1%) HPA-15 alloantibodies were found comprising four anti-HPA-15a and 12 anti-HPA-15b. Anti-HPA-15b without other PLT-reactive antibodies were detectable in three serum samples of PT patients. The incidence of HPA-15 alloimmunization in PT patients was significantly higher than in mothers with FNAIT (3.0% vs. 0.22%). In relation to all detected HPA-specific antibodies, HPA-15 is responsible for 6.2 percent of alloimmunizations. CONCLUSION: These observations indicate that alloimmunization against HPA-15 should be considered as a cause for immune thrombocytopenia, particularly in patients receiving multiple PLT transfusions.     

Primary and secondary hemostatic functionalities of rehydrated, lyophilized platelets

BACKGROUND: The rehydrated, lyophilized (RL) platelet (PLT) is being developed as a hemostatic infusion agent for the control of active bleeding. The key to the method for preparing RL PLTs is a mild aldehyde stabilization that allows for freezing and lyophilizing without cellular rupture. RL PLTs have been shown to be effective at rapidly controlling bleeding in animal models of cardiopulmonary bypass induced PLT dysfunction and washout thrombocytopenia, yet the rehydrated cells have proved to be safe with respect to induction of pathologic intravascular coagulation. STUDY DESIGN AND METHODS: In vitro and in vivo studies were performed to better understand the differential effect of the RL PLT manufacturing method on primary and secondary hemostatic processes. The functionality of the von Willebrand factor (VWF) receptor (glycoprotein Ib) complex, the PAR receptors, integrin-mediated aggregation (inside-out signaling), and surface membrane prothrombin to thrombin conversion systems were investigated. RESULTS: RL PLTs were found to retain native VWF-mediated adhesion and surface thrombin generation functions. In contrast, the coupling of thrombin receptors to integrin inside-out signaling was largely inhibited. CONCLUSION: These results suggest that RL PLTs may stop bleeding by forming primary hemostatic plugs and providing a localized source of thrombin for secondary hemostatic processes, yet do not build up occlusive pathologic clots possibly because integrin functions for forming PLT-PLT aggregates are partially inhibited.     

Serologic analysis of three cases of neonatal alloimmune thrombocytopenia associated with HLA antibodies

BACKGROUND: Neonatal alloimmune thrombocytopenia (NAIT) is caused when maternal alloantibodies react with paternally inherited antigens present on the fetal PLTs, a reaction mainly due to antibodies against human PLT antigens. Cases in which NAIT has been caused by HLA antibodies are relatively rare. In this study, three cases of NAIT associated with HLA antibodies that occurred in a 1-year period are reported. STUDY DESIGN AND METHODS: The presence of HLA antibodies in these three NAIT case studies was elucidated by examining reactions of the neonatal and maternal sera with lymphocytes, PLTs, and beads from an HLA antibody screening test (FlowPRA, One Lambda Inc.). Absorption and elution tests with paternal cells were also conducted. In addition, the influence of titer and specificity of HLA antibodies on NAIT was analyzed in light of 24 other documented cases in Japan. RESULTS: In the three case studies presented herein, antibodies against human PLT antigens were found in neither the maternal nor neonatal sera, while specific HLA antibodies were identified in both sera. Absorption of maternal serum with paternal PLTs eliminated the reactivity against paternal PLTs and lymphocytes. CONCLUSION: Transplacental passage of maternal HLA antibodies was observed in the three neonates cited in the present study.     

Mechanisms underlying acquired von Willebrand syndrome associated with an IgM paraprotein

Acquired von Willebrand (vW) syndrome is a rare bleeding disorder which is frequently associated with immunological, malignant or cardiovascular disorders. The underlying pathomechanisms, particularly in patients with IgM monoclonal gammopathies, often remain unknown. We report a patient with indolent small B-cell lymphoma (immunocytoma) and plasmacytic differentiation with an IgM κ paraprotein who was admitted with retroperitoneal haematoma. Medical history and coagulation testing were consistent with acquired vW syndrome. vW immunohistochemistry showed normal cytoplasmic labelling of endothelial cells and megakaryocytes, whereas the lymphomatous infiltrate was negative. Acquired vW syndrome due to adsorption of vW factor on malignant cells was thus excluded. In the multimeric analysis, all multimers were present similar to that in type 1 vW syndrome, but the triplet structures were blurred. The bands on serum immunofixation electrophoresis were also atypically broadened, which suggested complex formation between the IgM and vW factor. Immunoprecipitation studies showed that the 176-kDa proteolytic fragment of vW factor co-precipitated with the IgM paraprotein in the patient but not in the controls, suggesting a specific interaction between vW factor and the paraprotein in the patient. The patient required surgery and was successfully managed by chemotherapy consisting of rituximab and fludarabin as well as plasma exchange.     

Platelets photochemically treated with amotosalen HCl and ultraviolet A light correct prolonged bleeding times in patients with thrombocytopenia

BACKGROUND: Photochemical treatment (PCT) with amotosalen HCl with ultraviolet A illumination inactivates pathogens and white blood cells in platelet (PLT) concentrates. STUDY DESIGN AND METHODS: In a Phase II crossover study, 32 patients with thrombocytopenia received one transfusion of PCT and/or one transfusion of untreated (reference) apheresis PLTs. Hemostatic efficacy was assessed with the cutaneous template bleeding time and clinical observations. RESULTS: Paired bleeding time data for PCT and reference transfusions were available for 10 patients. Mean pretransfusion bleeding times were 29.2 +/- 1.6 minutes in the PCT group and 28.7 +/- 2.5 minutes in the reference group. After transfusion of a dose of PLTs of at least 6.0 x 10(11), mean 1-hour posttransfusion template bleeding times corrected to 19.3 +/- 9.5 minutes in the PCT group and 14.3 +/- 6.5 minutes in the reference group (p = 0.25). In 29 patients receiving paired PCT and reference transfusions, mean 1-hour posttransfusion PLT count increments were 41.9 x 10(9) +/- 20.8 x 10(9) and 52.3 x 10(9) +/- 18.3 x 10(9) per L for PCT and reference, respectively (p = 0.007), and mean 1-hour posttransfusion PLT corrected count increments (CCIs) were 10.4 x 10(3) +/- 4.9 x 10(3) and 13.6 x 10(3) +/- 4.3 x 10(3) for PCT and reference, respectively (p < 0.001). The time to next PLT transfusion was 2.9 +/- 1.2 days after PCT transfusions versus 3.4 +/- 1.3 days after reference transfusions (p = 0.18). Clinical hemostasis was not significantly different after PCT and reference transfusions. CONCLUSION: PCT PLTs provided correction of prolonged bleeding times and transfusion intervals not significantly different than reference PLTs despite significantly lower PLT count increments and CCIs.     

Recipient‐derived HPA‐1a antibodies: a cause of prolonged thrombocytopenia after unrelated donor stem cell transplantation

BACKGROUND: Patients with human platelet antigen (HPA) specific antibodies in cases of neonatal alloimmune thrombocytopenia and platelet (PLT) refractoriness derive clinical benefit from the use of HPA‐selected PLTs. STUDY DESIGN AND METHODS: This study describes three patients with underlying diagnoses of acute myeloid leukemia, chronic lymphocytic leukemia, and myelodysplasia, respectively, who underwent allogeneic bone marrow transplantation (BMT) with unrelated donors matched at the HLA‐A, B, C, Dr, and DQ loci but who failed to achieve an adequate PLT count. Investigation using PLT immunofluorescence test, monoclonal antibody immobilization of PLT antigens assay, and genotyping revealed the presence of recipient‐derived HPA‐1a antibodies. RESULTS: In two patients, anti‐HPA‐1a was detected post‐BMT and in the third patient, anti‐HPA‐1a was detected during pre‐BMT chemotherapy. Despite apparent 100% engraftment of donor cells, the patients' PLT counts failed to recover 9‐10 months posttransplant. The patients remained PLT‐transfusion dependent and failed to achieve satisfactory increments following random donor or HLA‐matched PLT transfusions. After the identification of HPA‐1a antibodies, the patients were supported by HPA‐1a(‐) PLTs and satisfactory posttransfusion PLT increments were obtained. These cases illustrate that HPA‐1a antibodies may remain detectable for 10 months following apparently successful donor engraftment and the disappearance of recipient‐derived HLA antibodies. The prolonged persistence of recipient‐derived PLT‐specific antibodies following BMT has to our knowledge not been described previously. CONCLUSION: HPA‐1a antibodies were associated with protracted PLT‐transfusion dependence and significant hemorrhagic complications. Appropriate and timely laboratory investigation for HPA‐specific antibodiesfollowed by transfusion support with HPA‐selected PLTs provided the cornerstone of the hemostatic management in these cases.     

Function of platelets in apheresis platelet concentrates and in patient blood after transfusion as assessed by Impact‐R

BACKGROUND: Platelet (PLT) transfusion is a mainstream therapy for preventing or treating bleeding episodes in patients with thrombocytopenia. The efficacy is usually estimated from the corrected count increment of PLTs after transfusion, which does not assess PLT function. We therefore evaluated PLT function in blood samples of patients with thrombocytopenia before and after transfusion. STUDY DESIGN AND METHODS: PLT function was assessed in 24 chemotherapy‐treated patients and in the PLT concentrates (PCs) by the Impact‐R (DiaMed). This device evaluates PLT adhesion and aggregation recorded as surface coverage (%) and size of aggregates (AS µm²). P‐selectin expression was determined by flow cytometry. RESULTS: The PCs were stored for a median of 70 hours before transfusion. An analysis stratified by the median storage of PCs (<70 hr or >70 hr) showed no differences in the SC, the AS, and P‐selectin expression between these concentrates' groups. Transfusion resulted in an increase of adhering PLTs in the patients after transfusion. There were no differences in the AS and in P‐selectin expression before and after transfusion, but the AS increased after transfusion upon ex vivo exposure to adenosine 5′‐diphosphate. P‐selectin expression was significantly lower in the patient group receiving PCs stored for more than 70 hours. CONCLUSION: The current trial shows the feasibility of using the Impact‐R to assess the function of transfused PLTs in the patient's blood stream.     

Blockade of maternal anti-HPA-1a–mediated platelet clearance by an HPA-1a epitope–specific F(ab')2 in an in vivo mouse model of alloimmune thrombocytopenia

BACKGROUND: Neonatal alloimmune thrombocytopenia (NAIT) is most commonly caused by transplacental passage of maternal human platelet-specific alloantigen (HPA)-1a antibodies that bind to fetal platelets (PLTs) and mediate their clearance. SZ21, a monoclonal antibody (MoAb) directed against PLT glycoprotein IIIa, competitively inhibits the binding of anti-HPA-1a alloantibodies to PLTs in vitro. The purpose of this investigation was to determine whether SZ21 F(ab')₂ fragments might be therapeutically effective in inhibiting or displacing maternal HPA-1a antibodies from the fetal PLT surface and preventing their clearance from circulation.
STUDY DESIGN AND METHODS: Resting human PLTs from HPA-1ab heterozygous donors were injected into nonobese diabetic/severe combined immunodeficient (NOD/SCID) mice. Purified F(ab')₂ fragments of SZ21 or control immunoglobulin G (IgG) were injected intraperitoneally 30 minutes before introduction of HPA-1a antibodies. Blood samples were taken periodically and analyzed by flow cytometry to determine the percentage of circulating human PLTs.
RESULTS: Anti-HPA-1a IgG from NAIT cases were able to efficiently clear HPA-1a–positive PLTs from murine circulation. Administration of SZ21 F(ab')₂ fragments not only inhibited binding of HPA-1a antibodies to circulating human PLTs, preventing their clearance, but also displaced bound HPA-1a antibodies from the PLT surface.
CONCLUSION: F(ab')₂ fragments of HPA-1a–selective MoAb SZ21 effectively inhibit anti-HPA-1a–mediated clearance of human PLT circulating in an in vivo NOD/SCID mouse model. These results suggest that agents that inhibit binding of anti-HPA-1a to PLTs may have therapeutic potential in the treatment of NAIT.     

Platelet dose consistency and its effect on the number of platelet transfusions for support of thrombocytopenia: an analysis of the SPRINT trial of platelets photochemically treated with amotosalen HCl and ultraviolet A light

BACKGROUND: The SPRINT trial examined efficacy and safety of photochemically treated (PCT) platelets (PLTs). PCT PLTs were equivalent to untreated (control) PLTs for prevention of bleeding. Transfused PLT dose and corrected count increments (CIs), however, were lower and transfusion intervals were shorter for PCT PLTs, resulting in more PCT than control transfusions. PLT dose was analyzed to determine the impact of the number of PLTs transfused on transfusion requirements. STUDY DESIGN AND METHODS: Transfusion response was compared for patients with all doses of >or=3.0 x 10(11) and the complementary subset of patients with any dose of fewer than 3.0 x 10(11). Analyses included comparison of bleeding, number of PLT and red blood cell (RBC) transfusions, transfusion intervals, and CIs between PCT and control groups within each PLT dose subset. RESULTS: Mean PLT dose per transfusion in the PCT group was lower than in the control group (3.7 x 10(11) vs. 4.0 x 10(11); p<0.001). More PCT patients received PLT doses of fewer than 3.0 x 10(11) (n=190) than control patients (n=118; p<0.01). Comparisons of patients receiving comparable PLT doses showed no significant differences between PCT and control groups for bleeding or number of PLT or RBC transfusions; however, transfusion intervals and CIs were significantly better for the control group. CONCLUSIONS: When patients were supported with comparable doses of PCT or conventional PLTs, the mean number of PLT transfusions was similar. Lower CIs and shorter transfusion intervals for PCT PLTs suggest that some PLT injury may occur during PCT. This injury does not result in a detectable increase in bleeding, however.     

The clinical impact of platelet refractoriness: correlation with bleeding and survival

BACKGROUND: Despite supportive care with platelet (PLT) transfusions, bleeding complications occur in a substantial number of patients with thrombocytopenia due to cytotoxic therapy. Moreover, refractoriness to PLT transfusions remains a frequently encountered problem. The clinical impact of PLT transfusion failure was investigated in 117 patients, part of a randomized PLT transfusion trial, which excluded patients with HLA and/or HPA alloantibodies. STUDY DESIGN AND METHODS: Between October 2003 and April 2005, a multicenter randomized controlled trial, testing the clinical efficacy of PLTs stored in plasma compared to PLT additive solution (PAS II), was performed. Using multiple regression analysis of observational data of patients randomized in one of the participating centers, the occurrence of PLT transfusion refractoriness was analyzed for a relation with bleeding complications and patient survival. RESULTS: PLT transfusion failure occurred at least once in 49.6 percent of the patients. Mild to moderate bleeding complications occurred in 19 percent of the patients. PLT transfusion failure was, independently from thrombocytopenia, positively associated with bleeding complications (odds ratio, 3.4; 95% confidence interval, 1.1‐11). Moreover, patients experiencing one or more 24‐hour PLT transfusion failures had, compared to patients always showing a sufficient 24‐hour increment, a significantly reduced median survival of 491 days (interquartile range [IQR], 156‐858 days) versus 825 days (IQR, 355‐996 days), respectively. In a Cox regression model, the effect on survival was independent of therapy, diagnosis, and age. CONCLUSION: Our results suggest that PLT transfusion failure might be a sensitive clinical marker for the occurrence of bleeding and impaired patient survival. PLT transfusion failure, bleeding complications, and decreased survival could be manifestations of a more severe degree of endothelial damage.     

Epitope‐based matching for HLA‐alloimmunized platelet refractoriness in patients with hematologic diseases

BACKGROUND: For HLA‐alloimmunized patients, platelet (PLT) concentrations are provided either at matched HLA‐A and HLA‐B loci or by serologic cross‐reactivity groups (CREG) matching strategy. However, this method has some limitations. STUDY DESIGN AND METHODS: In this study, the epitope‐based matching (EBM) method was evaluated for selecting proper HLA‐typed PLTs for patients with PLT transfusion refractoriness. Bead‐based single‐antigen HLA antibody detection method and HLAMatchmaker software were used to define the epitopes recognized by HLA‐specific antibodies and to select compatible PLTs for nine patients with alloimmunized refractoriness. Corrected count increments (CCIs) were prospectively determined to compare successful transfusion rates among different matching methods in 142 PLT transfusions. In addition, HLA antibodies were serially detected to see whether any emerging antibodies appeared after receiving the EBM‐matched PLTs. RESULTS: The transfusion success rates evaluated with 1‐hour CCIs for perfect matching or lacking any mismatching at HLA‐A and ‐B locus (A/BU)‐matched, CREG‐matched, and EBM‐matched PLTs were 85.2, 63.2, and 83.7%, respectively. Compared to CREG‐matched PLTs, EBM‐matched PLTs showed better transfusion results (p = 0.035). In the follow‐up study (7 months; range, 3‐13 months), no emerging HLA‐specific antibodies were detected after receiving EBM‐matched PLTs. CONCLUSIONS: EBM performed on the basis of bead‐based single‐antigen HLA antibody detection coupled with the HLAMatchmaker program is recommended in choosing proper PLTs for refractory patients when A/BU‐matched PLTs were not available.     

Storing apheresis platelets without agitation with simulated shipping conditions during two separate periods: immediately after collection and subsequently between Day 2 and Day 3

BACKGROUND: Apheresis platelet (PLT) units are not routinely agitated during transit. Our study compared the in vitro properties of apheresis PLT units that were stored with continuous agitation (CA) and without continuous agitation (WCA) during two separate periods, immediately after collection and between Day 2 and Day 3 of storage. STUDY DESIGN AND METHODS: Two identical apheresis PLTs units were prepared from collections with Amicus (n = 11, Fenwal, Inc.) and Trima (n = 10, CaridianBCT) cell separators. One apheresis PLT unit was continuously agitated, starting routinely within 30 minutes of collection, and an identical apheresis PLT unit was held without agitation initially for 7 to 8 hours and subsequently for 24 hours between Day 2 and Day 3 of storage. The apheresis PLT units were maintained WCA at 20 to 24°C in a shipping box. In vitro PLT properties were evaluated on Day 1 (day after collection), after 5 and 7 days of storage. RESULTS: With both Amicus and Trima apheresis PLT units, the mean PLT content and concentration of CA and WCA were comparable and essentially constant throughout storage. Mean pH levels (±1 SD) after 5 days for Amicus apheresis PLT units were 6.97 ± 0.20 (WCA) and 7.13 ± 0.16 (p < 0.001, CA) and for Trima apheresis PLT units 6.97 ± 0.21 (WCA) and 7.22 ± 0.17 (p < 0.001, CA). In vitro variables, including percentage of disc PLTs, extent of shape change, and hypotonic stress levels, after 5 days of storage, showed mean differences between WCA and CA that were less than 15%. CONCLUSION: The in vitro results show that apheresis PLT units can be stored without agitation for 7 to 8 hours immediately after collection and also subsequently during storage for 24 hours with minimal influence on in vitro PLT properties compared to continuously agitated PLTs.     

A randomized controlled clinical trial evaluating the performance and safety of platelets treated with MIRASOL pathogen reduction technology

BACKGROUND: Pathogen reduction of platelets (PRT‐PLTs) using riboflavin and ultraviolet light treatment has undergone Phase 1 and 2 studies examining efficacy and safety. This randomized controlled clinical trial (RCT) assessed the efficacy and safety of PRT‐PLTs using the 1‐hour corrected count increment (CCI_1hour) as the primary outcome. STUDY DESIGN AND METHODS: A noninferiority RCT was performed where patients with chemotherapy‐induced thrombocytopenia (six centers) were randomly allocated to receive PRT‐PLTs (Mirasol PRT, CaridianBCT Biotechnologies) or reference platelet (PLT) products. The treatment period was 28 days followed by a 28‐day follow‐up (safety) period. The primary outcome was the CCI_1hour determined using up to the first eight on‐protocol PLT transfusions given during the treatment period. RESULTS: A total of 118 patients were randomly assigned (60 to PRT‐PLTs; 58 to reference). Four patients per group did not require PLT transfusions leaving 110 patients in the analysis (56 PRT‐PLTs; 54 reference). A total of 541 on‐protocol PLT transfusions were given (303 PRT‐PLTs; 238 reference). The least square mean CCI was 11,725 (standard error [SE], 1.140) for PRT‐PLTs and 16,939 (SE, 1.149) for the reference group (difference, ?5214; 95% confidence interval, ?7542 to ?2887; p < 0.0001 for a test of the null hypothesis of no difference between the two groups). CONCLUSION: The study failed to show noninferiority of PRT‐PLTs based on predefined CCI criteria. PLT and red blood cell utilization in the two groups was not significantly different suggesting that the slightly lower CCIs (PRT‐PLTs) did not increase blood product utilization. Safety data showed similar findings in the two groups. Further studies are required to determine if the lower CCI observed with PRT‐PLTs translates into an increased risk of bleeding.