Prevention of alloimmunization in patients with acute leukemia by use of white cell-reduced blood components—a randomized trial

Platelet refractoriness arising from HLA alloimmunization is a serious complication of transfusion therapy. In a prospective randomized trial, white cell (WBC)-reduced blood components were compared to standard platelet and red cell concentrates with respect to alloimmunization, refractoriness, and platelet increments after transfusion. Sixteen of 31 adult acute leukemia patients received only WBC-reduced platelet concentrates (PCs) and red cells (RBCs), with fewer than 10(6) WBCs per unit. Fifteen control patients received standard blood components with a mean of 0.1 x 10(9) (PCs) and 1 x 10(9) (RBCs) WBCs per unit. Platelet loss during cotton-wool filtration averaged 14 percent (range, 3-32%) from fresh PCs and 24 percent (range, 9-62%) from stored PCs. Filtration did not change corrected increments (CI) measured after transfusion of fresh PCs. The Cl 1 hour after filtration of stored PCs diminished by 27 percent, but the difference was smaller after 18 hours, which suggests better survival of WBC-reduced platelets. The number of platelet units transfused did not differ in the two groups. No patient in the WBC-reduced group developed permanent platelet refractoriness; transient HLA antibodies of low titer developed in two patients. In the control group, one patient became refractory because of immunization and two developed transient HLA antibodies. It can be concluded that the reduction of WBCs in blood components can effectively prevent alloimmunization.     

Ultraviolet-B irradiation of platelets: a preliminary trial of efficacy

Prior studies established that ultraviolet-B light (UVB) irradiation of platelet concentrates (PCs) at appropriate doses can eliminate the mixed lymphocyte culture-stimulating and -responding capacity of lymphocytes in the PCs without adversely affecting in vitro platelet function. The in vivo recovery and survival and in vitro characteristics of UVB-irradiated platelets were investigated in paired studies. PCs were stored for 1 day and then exposed to UVB. Platelet recovery, survival, and function were comparable to those of nonirradiated platelets. Recovery and survival of platelets stored for 5 days before UVB exposure were decreased relative to controls, although they were considered clinically acceptable. Paired transfusion studies were also performed in seven thrombocytopenic patients by using platelets obtained by apheresis. Comparable posttransfusion platelet increments and bleeding time corrections were obtained with both irradiated and control (nonirradiated) platelets. It can be concluded that platelets survive and function relatively normally in vivo after UVB irradiation sufficient to abolish lymphocyte reactivity in mixed lymphocyte culture. Long-term studies of UVB-irradiated PCs are needed to assess their potential in reducing recipient alloimmunization.     

Platelet refractoriness and alloimmunization in pediatric oncology and bone marrow transplant patients

BACKGROUND: The purposes of this study were to determine the overall incidence of platelet refractoriness and alloimmunization among multiply transfused children on a medical oncology and bone marrow transplant service and to evaluate the effect of routine white cell reduction in blood components on that incidence. STUDY DESIGN AND METHODS : The platelet transfusion records of 128 consecutive children admitted to the hospital and requiring blood component support for the treatment of disease were evaluated retrospectively. Mean corrected count increments (CCIs) for each patient were calculated for all random- donor platelet transfusions given within 7 days of the routine weekly testings of the patient's serum for lymphocytotoxic antibodies (LCTAbs). Mean CCIs for HLA-matched platelet transfusions were calculated separately for the patients receiving them. RESULTS : Thirty- one patients (24%) had or developed persistently positive LCTAbs (patient's serum reacted with > or = 3/10 panel lymphocytes); 22 (71%) of these patients had a mean CCI < 7.5 to random-donor platelet transfusions. In contrast, of the 97 patients with negative or transiently positive LCTAbs, only 25 (26%) had a mean CCI < 7.5. The overall incidence of platelet refractoriness (CCI < 7.5) was 37 percent. Patients with acute myelogenous leukemia had a significantly (p < 0.01) reduced incidence (17%) of low CCIs, with or without positive LCTAbs, as compared to patients with other malignant or nonmalignant disorders (41%). No difference in the incidence of LCTAbs or low CCIs was seen in patients undergoing allogeneic or autologous bone marrow transplant or receiving drug therapy only. Among the 24 patients who received HLA-matched platelets, only those with positive LCTAbs showed a significant improvement in CCIs over that achieved with random-donor platelet transfusions. Routine white cell reduction in red cell and platelet components with third-generation white cell filters was performed prior to transfusion in 73 of the patients. There was no significant difference between the incidence of LCTAbs and/or low CCIs in this group and that in the 55 children receiving unfiltered transfusions. CONCLUSION : Alloimmunization and platelet refractoriness occur in pediatric oncology and bone marrow transplant patients, but the incidence-particularly in children with acute myelogenous leukemia- -appears to be low. The detection of LCTAbs predicts a poor response to random-donor platelet transfusion, but most such patients show improved CCIs with HLA-matched platelets. Routine use of white cell-reduction filters has thus far failed to eliminate alloimmunization in children requiring prolonged blood component support.     

Storage of platelet concentrates after high-dose ultraviolet B irradiation

Ultraviolet B (UVB) irradiation of platelet concentrates (PCs) may prevent the development of posttransfusion HLA alloimmunization. As irradiation performed in a blood center or a hospital will probably be associated with a variable postirradiation delay before transfusion, the ability to store PCs after UVB irradiation becomes important. The effects have been studied of a UVB dose of 10,000 mJ per cm2, the dose used in our institution for UVB clinical trials, on PCs pooled and stored for up to 96 hours after irradiation. Results showed that after 96 hours of storage, though there were no changes in pH, platelet count, white cell count, percent discharge of lactate dehydrogenase, or beta-thromboglobulin, there were significant decreases in morphology score and osmotic recovery. These changes, however, were not evident after 24 hours of storage. Similarly, there was a 60-percent decrease in immunoreactive membrane glycoprotein (GP) Ib after 96 hours of storage, but these changes were not seen after 48 hours of storage. No changes were seen in levels of GPIIb/IIIa in either group during the 96 hours of storage. On computer-analyzed two-dimensional polyacrylamide gel electrophoresis, PCs irradiated at 10,000 mJ per cm2 and stored for 72 hours had changes in over 50 platelet proteins as compared to those proteins in nonirradiated age-matched control PCs. It can be concluded that UVB irradiation of PCs at 10,000 mJ per cm2 does not lead to significant platelet deterioration after short-term storage (24-48 hours) but is likely to be deleterious after long-term (72-96 hours) storage.(ABSTRACT TRUNCATED AT 250 WORDS)     

Clinical factors influencing posttransfusion platelet increment in patients undergoing hematopoietic progenitor cell transplantation—a prospective analysis

BACKGROUND: Platelet transfusion refractoriness remains problematic in the management of patients who have undergone hematopoietic progenitor cell transplantation. Bone marrow transplantation itself is reported to be a relevant factor hampering efficient platelet transfusions. However, a prospective analysis assessing factors affecting platelet transfusion efficacy in the setting of hematopoietic progenitor cell transplantation has yet to be conducted. STUDY DESIGN AND METHODS: To identify factors independently influencing platelet transfusion efficacy after hematopoietic progenitor cell transplantation, a prospective study was performed to determine the effectiveness of platelet transfusions by estimating posttransfusion (16-hour) corrected count increments (CCI) in 42 consecutive patients (26 who received allogeneic transplants and 16 who received autologous transplants) with 439 available platelet transfusions. RESULTS: The mean CCI and percentage of CCI <4500 for all transfusions were 6161.1 +/− 7775.2 per microL and 42.1 percent, respectively. Multiple linear regression analyses revealed high total bilirubin, total body irradiation, high serum tacrolimus, and high serum cyclosporin A to be major factors independently predicting a lower CCI. HLA antibodies with restricted specificity and platelet antibodies were detected transiently in 17 and 14 percent of the patients, respectively. The presence of these antibodies was not, however, associated with a poor response to platelet transfusions. CONCLUSION: Platelet transfusion efficacy in hematopoietic progenitor cell transplant recipients is markedly influenced by clinical factors specific to the procedure as well as those already recognized in other settings. Alloimmunization is not, however, a major factor associated with a poor response to platelet transfusions after this procedure.     

Guidelines for platelet transfusions

Recommendations for the optimal transfusion support of patients likely to receive repeated platelet transfusions. 1. Determine policy for prophylactic platelet support, and select the platelet count below which platelet transfusions will be used. 2. Consider using leucocyte depletion of red cell and platelet concentrates to prevent HLA alloimmunization from the outset. 3. Type patients for HLA-A and B antigens at an early stage. 4. Use random donor platelet concentrates for initial platelet support (either single or multiple donor, depending on availability). 5. If refractoriness occurs, determine whether clinical factors, which may be associated with non-immune consumption of platelets, are present and test the patient's serum for HLA antibodies. 6. Use HLA-matched platelet transfusions if HLA alloimmunization is the most likely cause of refractoriness. 7. If there is no improvement with HLA-matched transfusions, platelet crossmatching may identify the cause of the problem and help with the selection of compatible donors. 8. Discontinue prophylactic platelet support if a compatible donor cannot be found. Use platelet transfusions from random donors to control bleeding and increase the dose, if necessary.     

Management of patients refractory to platelet transfusion.

This article discusses the causes and management of platelet refractoriness. Improvements in the quality of platelets and leukoreduction have reduced the morbidity and mortality related to alloimmunization and refractoriness of patients to platelet transfusion. Alloimmunization can be distinguished from other causes of poor post-transfusion platelet increments by the measurement of platelet alloantibodies. Options for managing platelet refractoriness caused by alloimmunization include platelet transfusion from human leukocyte antigen-matched or donor-recipient cross-matched platelets. Prevention strategies include efforts to limit recipients' exposure to human leukocyte antigen specificities by using single-donor platelets, filtration to reduce the number of human leukocyte antigen-bearing leukocytes, and pretransfusion ultraviolet B irradiation to decrease their immunogenicity. For appropriate management of patients refractory to platelets, close cooperation and good communication are necessary between clinicians and blood centers.     

A prospective randomized study of three types of platelet concentrates in patients with haematological malignancy: corrected platelet count increments and frequency of nonhaemolytic febrile transfusion reactions

We prospectively randomized 51 patients with haematological malignancy requiring platelet concentrates (PCs) to receive either single donor plateletpheresis products (SD-PC), PCs made from pooled buffy coats (BC-PC) or pooled units of platelets made by the platelet-rich plasma method (PRP-PC). The leucocyte content of each type of PC was 0.33 (0.03–13.5), 5.68 (0.19–99.0) and 365 (65–910) × 10⁶; median (range), respectively; P  < 0.0001. All red cell transfusions were leucodepleted by filtration. Statistical comparison of the probability of the occurrence of a nonhaemolytic febrile transfusion reaction (NHFTR) following transfusion of PCs in patients in each group showed a significant decrease for the SD-PC and BC-PC groups (0.031 and 0.038, respectively) when compared with PRP-PC (0.171); P  =0.001. The actual corrected platelet count increments (CCI) at 1–6 and 18–24 h post-transfusion for all three types of PC did not differ significantly. We conclude that transfusion of PRP-PC is associated with a significant increase in NHFTR.     

Effect of storage and ultraviolet B irradiation on CD14-bearing antigen- presenting cells (monocytes) in platelet concentrates

BACKGROUND: Ultraviolet B (UVB) irradiation of platelet concentrate (PCs) reduces platelet alloimmunization, but the mechanism of the effect is unclear. Evidence suggests that UVB may downregulate the expression of surface adhesion molecules on passenger antigen- presenting cells in PCs. STUDY DESIGN AND METHODS: The effect of blood bank storage, platelet preparation from whole blood, and UVB irradiation on the quantitative expression of intercellular adhesion molecule-1 (ICAM-1, or CD54), HLA-DR, CD45, and CD11c on CD14-positive antigen-presenting cells (monocytes) was studied by using two-color flow cytometry. RESULTS: Blood bank storage for 4 days resulted in upregulation of ICAM-1 and HLA-DR and downregulation of CD14 but left the expression of CD11c and CD45 unchanged. Preparation of PCs from fresh whole blood was associated with a rapid increase in CD11c without upregulation of ICAM-1 and HLA-DR. UVB irradiation before storage inhibited the upregulation of ICAM-1 and HLA-DR, resulted in accelerated downregulation of CD14, and was associated with increased loss of monocytes. Agitation of the PC bag during irradiation was of critical importance, since omission of agitation resulted in largely uninhibited upregulation of ICAM-1 but was still associated with significantly higher cell loss than that seen in unirradiated controls. CONCLUSION: UVB exposure nonspecifically affects monocytes in PCs, resulting in downregulation of surface molecules that are important for antigen presentation, as well as in significant cell loss.     

Flow cytometric detection of platelet-reactive antibodies and application in platelet crossmatching

Background: Alloimmunization against HLA or platelet antigens can cause refractoriness to platelet transfusions in multiply transfused patients. Crossmatching of platelet concentrates is effective in overcoming this problem. Study Design and Methods: A flow cytometric assay was used for simultaneous detection of lymphocyte-reactive and platelet-reactive antibodies in a single sample using fluorescein isothiocyanate-labeled anti-IgG. This assay was compared with the monoclonal antibody-specific immobilization of platelet antigens (MAIPA) assay in selected sera containing HLA and platelet antibodies. In a further study, this assay was compared with lymphocytotoxicity test results from thrombocytopenic patients, for whom platelet concentrates were ordered. The results of both assays were then correlated with the 1-hour corrected count increment, with a corrected count increment greater then 7500 considered as an adequate transfusion response. Results: The results of the MAIPA and flow cytometric assay in detecting platelet-reactive antibodies correlated well (p<0.0001, r = 0.84). The sensitivity and specificity of the flow cytometric assay in detecting platelet-reactive antibodies were 94.7 and 96.3 percent, when the MAIPA assay was taken as a reference. In unselected sera from patients, the sensitivity and specificity of the flow cytometric assays were, respectively, 72.7 and 91.7 percent in detecting lymphocyte- reactive antibodies and 70.6 and 77.7 percent in detecting platelet- reactive antibodies, when the lymphocytotoxicity test was used as a reference. With regard to an adequate transfusion response, the sensitivities and efficiencies were 20.0 and 82.1 percent, 33.3 and 84.3 percent, and 70.0 and 88.6 percent for the lymphocytotoxicity test and the lymphocyte-reactive and platelet-reactive flow cytometric assays, respectively. Conclusion: Flow cytometric crossmatching appears to be an effective method of detecting platelet-reactive antibodies that may affect the success of platelet transfusions. This procedure is well-suited for routine conditions and can be performed within 2 hours.     

Filtration. A method to prepare white cell-poor platelet concentrates with optimal preservation of platelet viability

HLA alloimmunization is a major problem for thrombocytopenic patients receiving long-term platelet support. It is caused by white cells (WBCs) that are present as contaminants in platelet concentrates (PCs). Recent data have shown that filtration is an effective means to reduce WBC contamination, but it has little effect on the recovery of platelets. The present report evaluates two filters, a cellulose acetate (CA) filter requiring the inactivation of platelets with prostacyclin and a cotton wool (CW) filter requiring no platelet inactivation. The results show that, using fresh pooled PCs from six random donors, both filters reduce WBC contamination below 10(7) per PC, the likely threshold below which alloimmunization does not develop. With platelets stored for 2 to 3 days the efficacy of the CW filter decreases. Neither filter inflicts important damage to the platelets, as there is no considerable platelet activation or cell disruption. Moreover, PCs prepared by both filters show normal survival and effectively reduce the bleeding times. Thus, filtration of PCs results in platelets with optimal responsiveness both in vitro and in vivo.     

High-yield platelet concentrates attainable by continuous quality improvement reduce platelet transfusion cost and donor exposure

BACKGROUND: Donor exposure risk and cost in platelet transfusion practice can be limited by increasing the recovery of platelets from donor units. STUDY DESIGN AND METHODS: This study presents results of continuous quality improvement efforts in platelet production and compares the in vivo therapeutic efficacy of currently produced platelet concentrates (PCs) with that of apheresis platelets. Production quality improvement measures included optimization of instrument performance (rotor speed trials), process (massaging whole- blood units, using cup liners, limiting spin-expression time, and refining plasma expression technique), and staff (intensive training with observation and ongoing quality control data feedback). Corrected count increments and increments per kg were calculated for transfusions of 4 pooled PCs and apheresis platelets over a 30-day period. RESULTS: The mean number of platelets per PC increased from 5.5 × 10(10) in 1975 to 9.69 × 10(10) in 1994. The mean platelet dose was 3.78 × 10(11) for 4 PCs and 4.17 × 10(11) for apheresis platelets. A total of 34 pooled PCs and 17 apheresis platelets was transfused to 21 patients. The mean increment, the increment per kg, and the corrected count increment were, respectively, 31 × 10(3) per microL, 4.8 × 10(2) per microL, and 14,700 for 4 PCs and 35.4 × 10(3) per microL, 5.4 × 10(2) per microL, and 14,700 for apheresis platelets. Differences were not significant. CONCLUSION: Therapeutic efficacy comparable to that of apheresis platelets can be obtained with 4 high-yield PCs.     

Experimental animal model of refractoriness to donor platelets: the effect of plasma removal and the extent of white cell reduction on allogeneic alloimmunization

Platelet transfusion effectiveness may be limited in multiply transfused patients by the development of the refractory state. White cell (WBC)-reduction filters with variable efficiency (1-3 log10 reduction) are available and have been shown to be effective in reducing the incidence of platelet alloimmunization. However, the threshold number of WBCs below which alloimmunization would no longer occur is yet to be determined. A previously established animal model was used to examine the relative efficiency of second- and third- generation filters in reducing the frequency of refractoriness to allogeneic platelets. In this model, California Black rabbits are used as blood donors and New Zealand White rabbits as transfusion recipients. Eight weekly transfusions of either second-generation or third-generation WBC-reduced blood resulted in no difference between the two groups in mean platelet survival and rate of refractoriness to allogeneic platelets. To evaluate the possible incremental benefit of removing supernatant plasma to prevent platelet refractoriness, experiments were performed in which groups of animals were given transfusion(s) with red cell suspensions that had been WBC-reduced or both plasma-depleted and WBC-reduced. A significantly lower rate of allogeneic platelet refractoriness was seen in the rabbits that received WBC-reduced and plasma-depleted red cells than in those that received red cells that had been WBC-reduced only. These data provide evidence that the combined use of plasma depletion and WBC reduction can decrease still further the frequency of refractoriness produced by allogeneic blood transfusions.     

Lack of effect on platelet increments of granulocyte-macrophage-colony- stimulating factor following autologous bone marrow transplantation for malignant lymphoma

BACKGROUND: Recombinant growth factors are used increasingly often to stimulate bone marrow recovery after intensive chemotherapy and bone marrow transplantation. Their effects on the requirements for and responsiveness to coincident therapies, including transfusion, should be defined. STUDY DESIGN AND METHODS: To determine whether treatment with recombinant granulocyte-macrophage-colony-stimulating factor (GM- CSF) affects platelet transfusion responsiveness, the clinical and blood bank records were examined for 16 adult patients (8 controls, 8 receiving GM-CSF) participating in a double-blind study of GM-CSF administration (250 micrograms/m2 × 21 days) following autologous bone marrow transplantation for lymphoma. For each platelet transfusion, a corrected count increment was calculated, and note was made of the presence or absence of selected additional factors thought to decrease platelet responsiveness: fever, amphotericin treatment, HLA antibodies, platelet ABO incompatibility, and febrile transfusion reactions. RESULTS: The total number of platelet transfusions (GM-CSF patients, 145; controls, 145) and the mean number of transfusions per patient (GM- CSF, 18.3; controls, 18.0) were comparable in the two groups. GM-CSF patients received significantly more platelets that were ABO incompatible, that were given during a febrile period, or that were given while the patient was on amphotericin. Nevertheless, the corrected count increments in patients who received GM-CSF were at least as good as those in controls: for GM-CSF patients: mean was 8,574 +/− 5,868, median was 7,818, 49 percent were < 7,500 and 66 percent were < 10,000; for controls; mean was 7,618 +/− 7,536, median was 6,100, 59 percent were < 7,500, and 73 percent were < 10,000. CONCLUSION: In this group of patients, GM-CSF did not adversely affect the required number of, increments to, or incidence of refractoriness to platelet transfusions.     

White blood cell inactivation after treatment with riboflavin and ultraviolet light

Functional white blood cells (WBCs) in blood components may be responsible for a number of adverse transfusion effects, including transfusion‐associated graft‐versus‐host disease (TA‐GVHD), alloimmunization, and alloimmune platelet (PLT) refractoriness. TA‐GVHD occurs when functional lymphocytes are transfused into a patient who is unable to mount an immune response to the human leukocyte antigen (HLA) due to HLA compatibility or immunosuppression. Alloantibodies against HLA antigens on donor WBCs and PLTs are the major cause of refractoriness to PLT transfusions in patients receiving repeated blood transfusions. Attempts to reduce these undesirable effects have included leukoreduction filters and gamma irradiation. Studies have shown that exposure of PLT concentrates to riboflavin and light (Mirasol pathogen reduction technology [PRT], CaridianBCT Biotechnologies) causes irreparable modifications of nucleic acids that result in inactivation of a wide range of pathogens as well as inhibition of the immunologic responses mediated by WBCs present in PLT concentrates. This article summarizes these studies and also reports on additional findings from the Trial to Reduce Alloimmunization to Platelets (TRAP) and Mirasol Clinical Evaluation (MIRACLE) trials. Data from in vitro studies and this clinical trial suggest that PRT treatment may be as effective as gamma irradiation in preventing TA‐GVHD and more effective than leukoreduction in preventing alloimmunization.     

Human Leukocyte Antigen Alloimmunization and Alloimmune Platelet Refractoriness

Despite significant advancements in the production of platelet products, storage, and transfusion, transfusion refractoriness remains a significant clinical problem, affecting up to 14% of hematological patients receiving platelet transfusions. Human leukocyte antigen (HLA) alloimmunization is a major cause of immune platelet refractoriness, and its rate can be significantly reduced by implementation of leukoreduction. Despite promising preclinical results, pathogen reduction does not reduce HLA alloimmunization. Patients with HLA alloimmune refractoriness are usually managed with HLA-selected platelet transfusions. In this review, we describe the pathophysiology of HLA alloimmunization and alloimmune refractoriness, as well as options to prevent and treat these transfusion complications. We discuss the evidence supporting these options and point out the outstanding gaps. Finally, we review the possible future directions for prevention and treatment of alloimmune refractoriness.     

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.     

Posttransfusion purpura following bone marrow transplantation

BACKGROUND : Thrombocytopenia is a major cause of morbidity and hospital expense following bone marrow transplantation. Platelet transfusions in these patients are frequently complicated by the recipient's development of antibodies to HLA class I antigens. When these patients become refractory to the transfusion of HLA-matched platelets, the recipient's platelet antigen phenotype must be determined, to ensure that donor platelets will be phenotypically compatible. Cases of alloimmunization to HPA-1a and HPA-1b resulting in refractoriness to transfused platelets and the subsequent development of a posttransfusion purpura-like syndrome are reported. CASE REPORTS: In the first case, a 43-year-old woman with Stage IV infiltrating ductal breast cancer presented to the hospital for a transplant of autologous peripheral blood stem cells. After the transplant, her platelet count remained less than 10 × 10⁹ per L, despite daily platelet transfusions, including HLA-matched platelets. Fourteen days following the transplant, her serum was found to contain anti-HPA-1a. Initially, the patient was refractory to the transfusion of HPA-1a-negative platelets, but after treatment with intravenous immunoglobulin, she had transient increases in posttransfusion platelet counts. She was also treated with a staphylococcal protein A immunoadsorption column and has not had any such subsequent refractoriness. Her genotype has been found, by use of allele-specific oligonucleotide hybridization with white cell DNA, to be HPA-1b/1b. The second case involved a 32-year-old woman with chronic myelogenous leukemia who received an unrelated-donor marrow transplant. Three years later, her CML recurred, and she was treated with interferon-alpha. Four months afterward, she experienced interferon-alpha-induced thrombocytopenia and the interferon therapy was discontinued. She received 12 platelet transfusions in 20 days, but none was effective. Antibodies specific for HLA antigens and HPA-1b were detected, and three HLA-matched, HPA-1b-negative apheresis platelet components were given, but without effect. Two days after treatment with methylprednisolone (1 g intravenously) and prednisone (2 mg/kg/day orally), her platelet count was 26 × 10⁹ per L, and after 8 more days, it was 102 × 10⁹ per L, without further transfusions. She was found to be homozygous for HPA-1a (HPA-1a/1a). CONCLUSION : Anti-HPA- 1a and anti-HPA-1b can cause refractoriness to platelet transfusions in bone marrow transplant patients. Testing for platelet-specific antibodies should be considered in all patients who are refractory to HLA-matched platelets.     

Febrile reactions to platelet transfusion: the effect of increased interleukin 6 levels in concentrates prepared by the platelet-rich plasma method

Background: A relation between febrile reactions to platelet transfusion and high cytokine levels in platelet concentrates (PCs) was found previously. The levels of cytokines such as interleukin (IL)-6 are related to the while cell content of the PC during storage. Therefore, early removal of white cells should prevent reactions. Study Design and Methods: This prospective study was set up to compare methods for the preparation of random PCs, the platelet-rich plasma method (PRP-PCs), which results in a high white cell content, and the buffy coat method (BC-PCs), which results in a low white cell content, with regard to the frequency and severity of reactions to platelet transfusion and the IL-6 level of the PC. IL-6 was chosen because it is the major mediator of the acute-phase response. White cells were reduced in all PCs before transfusion. Results: Platelet transfusions (n = 584) in 64 patients were studied. An overall reaction frequency of 7.2 percent was observed. Transfusion reactions were seen predominantly in patients who received PRP-PCs (PRP-PCs: 9.3% vs. BC-PCs: 2.7%, p = 0.007). Allergic reactions were limited to transfusions of PRP-PCs. The following PRP-PC characteristics were significantly correlated with febrile transfusion reactions: IL-6 level (p < 0.0001), initial white cell count (p = 0.001), and storage time (p = 0.02). In this group, reactions were less frequent in patients receiving pretransfusion medication (p < 0.001). In the PRP-PC group, IL-6 content (p = 0.01) and initial white cell count (p = 0.04) were also significantly correlated with allergic reactions, which indicated that these or associated factors might have an effect on the outcome of this type of reaction. Conclusion: Febrile reactions are highly correlated with IL-6 levels in PCs. The low white cell content of BC-PCs is associated with undetectable IL-6 levels and a reduced frequency of febrile as well as allergic reactions in recipients. The BC method is the preferable one for the production of random-donor PCs.     

Platelet crossmatching with lymphocytotoxicity test: an effective method in alloimmunized Chinese patients

Fifty-three patients receiving long-term platelet transfusions were regularly screened for platelet-associated antibodies by a platelet suspension immunofluorescence test (PSIFT) and a lymphocytotoxicity test (LCT). Subsequently, 24 patients became alloimmunized; all of their antibodies were of HLA specificity. Eighty-two single-donor platelet transfusions were given, and the clinical responses were considered satisfactory if the 18-hour corrected count increment was 7.5 x 10(3) per microL or higher. In the meantime, 82 pairs of patient sera and donor lymphocytes were crossmatched. Among 63 crossmatched transfusions, 53 (84%) resulted in a satisfactory increment, with a mean (+/- SEM) of 17.71 +/- 1.96 (x 10(3)/microL), and 10 did not result in a satisfactory increment. The increments after 19 unmatched transfusions and 25 random-donor (uncrossmatched) transfusions were 0.7 +/- 0.3 and 2.39 +/- 0.66, respectively. The difference was not significant (p greater than 0.05). The agreement between the LCT results and clinical response was 88 percent. Retrospectively, the corrected count increments showed no significant differences (p greater than 0.05) among three groups of HLA grading: the increments for A/BU/BX, C/D, and random HLA matches were 22.97 +/- 4.07, 15.1 +/- 1.97, and 14.85 +/- 2.04, respectively. These results suggest that platelet crossmatching by LCT is an effective method for use in alloimmunized patients, especially Chinese patients.