Antibodies to human neutrophil antigen HNA-4b implicated in a case of neonatal alloimmune neutropenia.

BACKGROUND: Maternal alloantibodies directed against human neutrophil antigens (HNAs) can cause moderate-severe neutropenia in the newborn in a condition known as neonatal alloimmune neutropenia (NAIN). Neonates with NAIN can present with sepsis or be asymptomatic. NAIN has previously been reported as caused by antibodies against HNA-1a, -1b, and -1c; CD16b, -2, -3a, -4a, and -5a; and HLA, but not by antibodies against HNA-4b. We report a case of NAIN due to anti- HNA-4b alloimmunization in a term neonate. CASE REPORT: An infant with persistent and marked neutropenia was suspected of having neonatal alloimmune neutropenia. Blood samples from both parents were investigated for HNA and HLA incompatibilities by molecular typing techniques and the mother for the presence of HNA and HLA antibodies by serologic techniques. RESULTS: Initial results indicated the presence of granulocyte antibodies in the maternal serum, the specificity of which were shown to be anti-HNA-4b. Subsequently, the mother was genotyped as HNA-4b negative and the father as heterozygous HNA-4ab. The child was shown to have inherited the incompatible HNA-4b allele. CONCLUSION: We have demonstrated the first case of NAIN due to maternal alloimmunization against HNA-4b, pending ratification by the International Granulocyte Immunobiology Workshop.

Childhood invasive pneumococcal disease in Tasmania, 1994-2000.

OBJECTIVE: To describe the burden of invasive pneumococcal disease in Tasmanian children, including age-specific incidence and antibiotic-resistance pattern. METHODS: A population-based retrospective study was carried out, examining cases of childhood disease associated with isolates of Streptococcus pneumoniae from normally sterile sites, identified via scrutiny of laboratory records at all major Tasmanian laboratories during a 7-year period between January 1994 and December 2000. Medical records were sub-sequently examined for information describing the clinical syndrome and course of disease. RESULTS: Invasive pneumococcal disease was identified in 76 children during the 7-year period. The incidence per 100 000 children was 28.5 (95% CI 22.0-36.3) in children under 5 years and 54.3 (95% CI 40.2-71.8) in children under 2 years. The incidence of meningitis in children younger than 2 years was 12.2 (95% CI 6.1-21.8). Penicillin resistance was observed in 2.6% of cases, with no high level resistance. Predisposing conditions were identified in 34% of children with invasive disease. CONCLUSIONS: The incidence of invasive pneumococcal disease was comparable to many urban populations in Australia. The high rate of predisposing conditions supports the recommendations of the Australian Technical Advisory Group on Immunisation for targeted immunization in this group. The paucity of data describing Indigenous status is an argument for improved data collection in this area. The low level of penicillin resistance necessitates ongoing surveillance, and the lack of serotype information requires prospective data collection.

Rapid assessment of glycoprotein IIb/IIIa blockade with the platelet function analyzer (PFA-100) during percutaneous coronary intervention.

BACKGROUND: The platelet function analyzer PFA-100 (Dade Behring, Miami, Fla) evaluates platelet function by determining the time to occlusion of an aperture in a membrane coated with collagen and adenosine diphosphate or epinephrine as whole blood flows under shear stress conditions. Platelet aggregation causes aperture occlusion, and results are reported as closure time (CT). Interindividual variability is observed in the level of platelet inhibition achieved with use of the current abciximab dosing regimen (0.25-mg/kg bolus + 10-microg/min infusion for 12 hours). The relationships between specific levels of platelet inhibition and clinical efficacy and safety have not been fully established. METHODS AND RESULTS: We prospectively studied platelet function in 27 patients receiving abciximab during percutaneous coronary intervention. This evaluation included determinations of platelet-rich plasma aggregometry, receptor occupancy studies (D3 assay), and CT measurements at baseline and 10 minutes, 4 hours, 12 hours, and 24 hours after the bolus. All patients received abciximab, aspirin, and heparin; patients undergoing coronary stent implantation received aspirin and ticlopidine after the procedure. CT results were reported within 10 minutes after initiation of testing. For 96% of patients, CT was 300 seconds (maximum CT) immediately after abciximab bolus and remained so throughout the infusion. At 24 hours we observed variable recovery from platelet inhibition and in 72% of patients CT returned to normal (< or =130 seconds). CONCLUSIONS: Findings with the PFA-100 were similar to results observed with platelet aggregometry and receptor occupancy measurements. Most patients treated with abciximab exhibit normalized platelet function at 24 hours despite moderate levels of receptor occupancy, suggesting dissociation between occupancy and function.

Platelet GP IIIa Pl(A) polymorphisms display different sensitivities to agonists.

BACKGROUND: Both inherited predisposition and platelet hyperreactivity have been associated with ischemic coronary events, but mechanisms that support genetic differences among platelets from different subjects are generally lacking. Associations between the platelet Pl(A2) polymorphism of GP IIIa and coronary syndromes raise the question as to whether this inherited variation may contribute to platelet hyperreactivity. METHODS AND RESULTS: In this study, we characterized functional parameters in platelets from healthy donors with the Pl(A) (HPA-1) polymorphism, a Leu (Pl(A1)) to Pro (Pl(A2)) substitution at position 33 of the GP IIIa subunit of the platelet GP IIb/IIIa receptor (integrin alpha(IIb)beta(3)). We studied 56 normal donors (20 Pl(A1,A1), 20 Pl(A1,A2), and 16 Pl(A2,A2)). Compared with Pl(A1,A1) platelets, Pl(A2)-positive platelets showed a gene dosage effect for significantly greater surface-expressed P-selectin, GP IIb/IIIa-bound fibrinogen, and activated GP IIb/IIIa in response to low-dose ADP. Surface expression of GP IIb/IIIa was similar in resting platelets of all 3 genotypes but was significantly greater on Pl(A2,A2) platelets after ADP stimulation (P=0.003 versus Pl(A1,A1); P=0.03 versus Pl(A1,A2)). Pl(A1,A2) platelets were more sensitive to inhibition of aggregation by pharmacologically relevant concentrations of aspirin and abciximab. CONCLUSIONS: Pl(A2)-positive platelets displayed a lower threshold for activation, and platelets heterozygous for Pl(A) alleles showed increased sensitivity to 2 antiplatelet drugs. These in vitro platelet studies may have relevance for in vivo thrombotic conditions.

The effect of antiplatelet drugs, heparin, and preanalytical variables on platelet function detected by the platelet function analyzer (PFA-100).

The platelet function analyzer (PFA)-100 is a newly developed instrument that provides a rapid, in vitro, quantitative measurement of platelet adhesion and aggregation in whole blood flowing through a small aperture under high shear conditions. Thirty patients undergoing percutaneous transluminal coronary angioplasty (PTCA) and ten normal individuals were included in this study. In vitro and in vivo studies were conducted to discern the effect of combinations of antiplatelet drugs (aspirin, ticlopidine, abciximab) and heparin on the performance of the device as well as the effects of preanalytical variables, such as method of sample collection and ex vivo anticoagulants. Studies were also conducted examining the effect of aperture size (standard 150 microns vs. smaller 120 microns) on the ability of the device to detect the effect of antiplatelet drugs. There was no difference in mean PFA-100 closure time with citrate versus PPACK anticoagulants or with venipuncture vs. sheath sampling. Closure times did not vary with heparin administration. Closure times were slightly longer for patients taking aspirin plus ticlopidine compared to aspirin alone (p = NS). In contrast adenosine disphosphate (ADP) induced platelet aggregation was significantly less in patients that took aspirin plus ticlopidine vs. aspirin alone (p = .0005). In vitro, there was a dose-dependent increase in closure time for both aperture sizes with increasing abciximab concentration. Although both cartridges showed infinite closure times at an abciximab concentration of 2.25 micrograms/mL, there was a slight benefit to using the 120 microns aperture cartridges at abciximab concentrations of 1.75 to 2.0 micrograms/mL. In ten patients who were followed during abciximab therapy to assess the effect of aperture size, the PFA-100 was able to detect in vivo platelet inhibition by abciximab, but detection of recovery from abciximab-induced platelet dysfunction was slightly better for the PFA-100 with the 120 microns aperture compared to the standard 150 microns aperture collagen/ADP cartridge.

Comparison of microscopic and flow cytometric detection of platelet antibody in dogs suspected of having immune-mediated thrombocytopenia.

A flow cytometric platelet immunofluorescence assay (FC-PIFA) was compared with a previously developed microscopic platelet immunofluorescence assay (MI-PIFA) for detection of circulating platelet antibody. Both assays were performed on serum from 10 healthy dogs with normal platelet count, and on serum from 27 thrombocytopenic dogs--18 had primary immune-mediated thrombocytopenia (IMT), and 9 had IMT in addition to other immune-mediated disease (secondary IMT). Both assays yielded negative results for all control dogs. The MI-PIFA and FC-PIFA results were in agreement in 23 dogs with IMT (14 positive and 9 negative). There was linear correlation between MI-PIFA scores and FC-PIFA results (r = 0.873). Positive results were obtained for 55.5% of the dogs with suspected IMT, using the MI-PIFA, compared with 67%, using the FC-PIFA; however, the difference was not statistically significant. Use of fresh or frozen fixed donor platelets as the antigen source yielded similar results in the FC-PIFA.

Detection of antiplatelet antibody with a platelet immunofluorescence assay.

An indirect platelet immunofluorescence assay (PIFA) was developed for detection of circulating antiplatelet antibody in dogs with suspected immune-mediated thrombocytopenia (ITP). The PIFA was performed on 10 healthy dogs with normal platelet counts; 76 thrombocytopenic dogs, 20 of which were suspected of having ITP; and 18 dogs with other diseases and normal platelet counts. All normal dogs and negative test results. Fourteen (70%) of 20 dogs suspected of having ITP had positive test results. Fifteen of the remaining 56 thrombocytopenic dogs had positive test results, 9 had cancer and 6 had other immune-mediated diseases including systemic lupus erythematosus (SLE). In this study, the PIFA assay seemed to be more sensitive (70%) than the megakaryocyte immunofluorescence assay (41%) in the diagnosis of ITP. Of the 9 PIFA-positive dogs with neoplasia, 6 had lymphoproliferative disorders. The PIFA was positive in 5 of 18 diseased dogs with normal platelet counts. There was an inverse relationship between the platelet count and the intensity of fluorescence in the PIFA-positive dogs. We conclude that the PIFA is a sensitive screening method for detecting circulating antiplatelet antibody.

Protein A immunoadsorption treatment in hematology: an overview.

Staphylococcal protein A efficiently binds immunoglobulins and circulating immune complexes (CIC) and provides an effective medium to remove immunoglobulins and CICs from plasma while sparing albumin and most coagulation proteins. Although it activates the complement system its clinical use abrogates the need for plasma expanders necessitated by plasma exchange. Despite anecdotal reports of utility in several hematologic syndromes, publications of clinical trials are available only for autoimmune thrombocytopenic purpura (AITP) and refractoriness to platelet transfusions (RFT) associated with alloimmunization. In the former situation Snyder et al. (Blood 79:2237-2245, 1992) reported on 72 patients with AITP all of whom had failed at least two previous therapies including splenectomy in 68%. Forty-six percent achieved improved platelet counts following treatment. The response was durable (8-26 mo) in all but 10%. Spleen-intact patients could not be differentiated from those who had been splenectomized. Both responders and nonresponders showed significant decreases in CIC and platelet-directed immunoglobulin (PDIG), but responders achieved near-normal levels. The beneficial response of these factors, particularly in spleen-intact patients, warrants a prospective study. In our studies at the University of Minnesota twelve patients with thrombocytopenia secondary to bone marrow failure who were refractory to platelet transfusion were treated with protein A immunoadsorption. Ten had demonstrable antiplatelet Abs (Anti-HLA, HPA, ABO). Seven of 12 demonstrated improved platelet counts and post-transfusion corrected count increments after treatment. This was associated with decreased platelet utilization and clinical bleeding. A prospective controlled clinical trial is justified.

Severe thrombocytopenia in an acquired immunodeficiency syndrome patient associated with pentamidine-dependent antibodies specific for glycoprotein IIb/IIIa.

Severe thrombocytopenia developed in a patient with acquired immunodeficiency syndrome during treatment with intravenous pentamidine for Pneumocystis carinii pneumonia. The patient's bone marrow contained adequate numbers of megakaryocytes, suggesting peripheral platelet destruction. Platelet counts ranged between less than 3 and 20 x 10(9)/L for 2 weeks despite cessation of pentamidine, platelet transfusions, high-dose intravenous IgG, and 2 mg/kg/d prednisone. Thereafter, the platelet count increased to prepentamidine levels (95 x 10(9)/L0, permitting rapid withdrawal of steroids. Testing by immunofluorescence disclosed a high-titer, pentamidine-dependent IgG antibody in the patient's acute-phase serum that almost entirely disappeared by the time the patient's platelet count returned to baseline levels. This antibody reacted only with platelet glycoprotein (GP) IIb/IIIa as shown by antigen-capture enzyme-linked immunosorbent assay using monoclonal antibodies specific for various GPs, and was absorbable by normal, but not by GPIIb/IIIa-deficient platelets (from a patient with Glanzmann's thrombasthenia). The pentamidine-dependent antibody could not be demonstrated by immunoprecipitation using the patient's serum and 125I-labeled normal platelets, although a separate pentamidine-independent antibody was detected by this method. This latter antibody reacted with two GPs having molecular weights consistent with GPIIb/IIIa, and was present in postrecovery as well as acute-phase sera. However, only the pentamidine-dependent antibody was temporally associated with the severe thrombocytopenia. Therefore, we believe that these studies demonstrate, for the first time, that intravenous pentamidine therapy can provoke formation of drug-dependent antibodies that induce immunologic thrombocytopenia.

Detection of clonal platelet antibodies in immunologically-mediated thrombocytopenias: association with circulating clonal/oligoclonal B cells.

Aware that T and B cells in autoimmune thrombocytopenia are abnormal, including the existence of clonal B cell populations, we sought to characterize this clonal phenomenon in various immunological thrombocytopenias using platelet antibody light chain analysis, flow cytometry, Southern blot analysis, and PCR. Using a monoclonal antibody-antigen capture ELISA, we analysed sera from 21 of 26 patients with autoimmune, alloimmune, or drug-induced immunological thrombocytopenia for the light chain phenotypes of their platelet antibodies. Alloantibodies and drug-dependent antibodies from four and 14 patients, respectively, were found that expressed a predominant type of light chain, suggesting that these platelet-reactive antibodies were monoclonal or oligoclonal in nature. 14 of the 26 patients were available for light chain B cell phenotyping studies. Of these 14 patients, thrombocytopenia was due to autoimmunity in two, drug-induced immunity in four, and alloimmunity in eight. We detected clonal populations of B cells in all 14 patients by flow cytometry. Although six of these latter patients possessed platelet antibodies with clonal characteristics, light chain phenotypes of antibodies in five patients were opposite to those of their B cells. Eight of these patients were further examined for immunoglobulin gene rearrangement using Southern and/or polymerase chain reaction analysis. In all eight patients we detected clonal or oligoclonal B cell populations. Only two of these patients had malignancies (chronic lymphocytic leukaemia) that would be expected to have detectable clonal B cells, and thus the mechanism for clonal expansion in the other six patients did not appear to be related to an obvious neoplastic process. Prior to these studies, detection of clonal B cells in thrombocytopenic patients without known malignancies was limited to individuals with autoimmune thrombocytopenia, prompting the speculation that this particular autoimmune disorder arises from B cell dysregulation, rather than from expansion of specific autoantibody producing B cell clones. In contrast, the current studies provide evidence that clonal B cells are common to patients with any form of immunologically-mediated thrombocytopenia. Moreover, the majority of the platelet antibodies (86%) present in these disorders exhibited monoclonal characteristics in that there was an apparent restriction in light chain usage.

Specificity of drug-induced immune cytopenias.

What conclusions can be drawn concerning specificity of drug-induced immune reactions? We have seen that specificity of these reactions depends on several molecular features including the chemical nature of the drug, specific domains of particular membrane components, and as yet unidentified characteristics that determine selectivity for one or more cell types. This latter property does not seem to be related to shared membrane components because, for example, Rh antigens on RBCs, the peptide tail region of GPIb alpha on platelets, and the 85-kd GP on neutrophils are clearly not part of the same molecules. From multiple studies of quinine/quinidine-dependent and nomifensine-dependent antibody interactions with platelets and RBCs, respectively, we can conclude that these particular reactions are a function of specific features of the drug molecules and specific domains of various membrane glycoproteins. These characteristics strongly argue that the hypervariable regions of drug-dependent, platelet and RBC antibodies recognize simultaneously a specific domain of the membrane GP and a specific configuration of the drug molecule. If this is true, then it follows that together a specific domain of the cell membrane component plus the drug define an antigenic determinant or epitope for attachment of certain drug-dependent antibodies. We have also seen that some drug-dependent antibodies preferentially react with the drug alone when it is attached to cell membranes (eg, penicillin-dependent antibodies reacting with penicillin-coated RBCs or platelets). Some drugs elicit antibodies that react at specific sites on the cell membrane independently of drug (eg, nomifensine and the Rh antigens (E) or quinidine and platelet GPV). These three concepts of antibody specificity induced by drugs are presented in Fig 6, using RBCs as an example. Despite major advances in understanding drug-induced immune reactions during the past four decades, several important questions remain to be answered. For example, why are platelets involved more frequently than other cells of the circulation in these types of reactions? Why do some individuals develop drug-induced immune cytopenias that are specific for a single cell type, whereas others develop reactions involving multiple cell types with distinct antibodies? What mechanism directs the reaction toward platelets, RBCs, or neutrophils? How are drug-dependent antigens presented to the immune system? This latter question is particularly intriguing considering that most drugs known to induce immune cytopenias bind only weakly to target tissues.(ABSTRACT TRUNCATED AT 400 WORDS)

Treatment of refractoriness to platelet transfusion by protein A column therapy.

Ten thrombocytopenic patients (platelets < 10-24 x 10(9)/L) who were refractory to platelet transfusion were investigated for their responsiveness to staphylococcal protein A column therapy. Nine patients had previously been treated with steroids, intravenous immune globulin, and/or other forms of immunosuppressive therapy without improvement in their transfusion response. All patients were receiving multiple platelet transfusions without achieving 1-hour corrected count increments (CCIs) > or = 7500. Eight patients had antibodies that reacted with platelets and were directed against HLA class I antigens, ABO antigens, and/or platelet-specific alloantigens. Plasma (500-2000 mL) from each patient was passed over a protein A silica gel column and then returned to the patient. Patients received from 1 to 14 treatments. A positive response to protein A therapy was defined as at least a doubling of the pretreatment platelet count and/or two successive 10- to 120-minute posttransfusion CCIs > or = 7500. Following plasma treatments, 6 of 10 patients responded with daily platelet counts that averaged 48 +/- 11 x 10(9) per L as compared with counts of 16 +/- 7 x 10(9) per L (p < 0.0005) before treatment. Posttransfusion CCI values determined in four of these patients averaged 2480 +/- 810 and 10,010 +/- 3540 (p < 0.005) before and after treatment, respectively. In contrast, among the four unresponsive patients, platelet counts averaged 10 +/- 9 and 13 +/- 10 x 10(9) per L (p = NS), respectively, while posttransfusion CCIs were 700 +/- 1410 and 1520 +/- 2460 (p = NS), respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of platelet activation induced by HLA antibodies associated with alloimmune thrombocytopenia.

The platelet-activating properties of plasma containing multispecific HLA antibodies were studied in plasma from several persons stimulated by platelet or red blood cell transfusion or by pregnancy. Antibodies were characterized by their lymphocytotoxic effects and by a monoclonal antibody antigen--capture enzyme-linked immunoassay. Plasma from each patient induced dose-dependent aggregation and release of adenosine triphosphate with antigen-positive platelet-rich plasma. Plasma from three patients induced normal aggregation and adenosine triphosphate release with platelet-rich plasma from donors who had taken platelet inhibiting medications (e.g. aspirin, piroxicam). In contrast, these platelets failed to release adenosine triphosphate when stimulated with 5 mumol/L adenosine diphosphate. Platelets were fully activated when saturated with HLA antibodies from one patient, although little or no stimulation was observed at 50% saturation suggesting that additional plasma cofactors and/or a threshold of bound antibody were required for activation. With a murine monoclonal antibody specific for P-selectin and antimurine immunoglobulin G labeled with iodine 125, plasma from each patient was found to induce P-selectin expression that was approximately 50% of that induced by 0.2 U/ml thrombin. Expression on platelets of P-selectin induced by plasma from one patient was independent of whether the donor had taken aspirin. Purified immunoglobulin G from this same patient stimulated platelet activation, as did the patient's serum, but no activation was observed with F(ab')2 fragments prepared from the immunoglobulin G. These studies demonstrate that HLA antibodies (1) mediate expression of P-selectin on the platelet surface, (2) are as potent as thrombin in activating platelets previously exposed to antiinflammatory agents, and (3) require an intact Fc domain to activate platelets.

Characterization of multiple quinine-dependent antibodies in a patient with episodic hemolytic uremic syndrome and immune agranulocytosis.

A 23-year-old woman experienced six distinct episodes of severe combined neutropenia and thrombocytopenia. At least one of the episodes was accompanied by hemodialysis-requiring acute renal failure and fragmentation hemolysis (hemolytic uremic syndrome [HUS]). In retrospect, all episodes were probably associated with the ingestion of quinine. Quinine-dependent antibodies to platelets, neutrophils, T lymphocytes, and red blood cells (RBCs) were detected in the patient's serum. By a monoclonal antibody antigen capture assay, the patient's serum contained IgG antibodies, which in the presence, but not absence, of quinine reacted with platelet glycoprotein (GP) complexes Ib/IX and IIb/IIIa, but not Ia/IIa. By immunoprecipitation assay, the serum, after addition of quinine, reacted strongly with an 85-Kd neutrophil membrane protein and weakly with 130- and 60-Kd moieties. Serum adsorbed with RBCs in the presence of quinine continued to react with platelets and neutrophils, and serum that was absorbed with platelets continued to react with neutrophils and RBCs, indicating that the antigenic targets were different on platelets, neutrophils, and RBCs. Since platelets and endothelial cells share some antigens, we tested patient serum for antibodies to human umbilical vein endothelial cells (HUVEC); no quinine-dependent antibodies to HUVEC were detected. However, her quinine-dependent antibodies not only bound to platelets and neutrophils, but also activated neutrophils. Thus, the patient's serum with quinine aggregated neutrophils, but neither agent alone caused activation. Moreover, the patient's serum with quinine (but not without) augmented the adherence of neutrophils to HUVEC. Treatment of the patient's serum with staphylococcal protein A removed the quinine neutrophil aggregation cofactor, suggesting it was due to IgG. In both neutrophil aggregation and adherence assays, decomplementation of the patient's serum markedly blunted its effect. Furthermore, the patient's serum failed to aggregate formalin-inactivated neutrophils, suggesting neutrophil activation, probably by activated complement, was necessary for aggregation and adhesivity to endothelium. We conclude that our patient's neutropenia, thrombocytopenia, lymphopenia, and anemia were due to quinine-dependent antibodies, and that these antibodies recognized epitopes that were different in the three target cell populations. We further suggest that HUS was likely secondary to the activation and adhesion of neutrophils to endothelium.

Human platelet activating antibodies.

Platelet antibodies identified in the plasma of three multiply transfused patients and a woman who had delivered a baby with neonatal alloimmune thrombocytopenia were investigated for their platelet activating properties. Three patients possessed multispecific HLA antibodies reactive with 90 to 100% of the cells on a lymphocytotoxic panel. These antibodies were also detected using the MAIPA assay and MAb w6/32, which recognizes an epitope common to all HLA class I molecules. In addition to HLA antibodies, three of the patients possessed platelet-specific antibodies that were identified by the MAIPA assay as anti-HPA-1a and anti-HPA-3a (one patient) and anti-HPA-1b (two patients). Each of the HLA antibodies when reacted with platelets expressing the corresponding HLA antigens, potently induced aggregation and release of ATP from dense granules. In contrast, the HPA-1b antibodies induced platelet agglutination, but failed to trigger ATP release. However, platelets coated with these latter antibodies were now refractory to subsequent stimulation by ADP. Similarly, when HLA antibodies were reacted with platelets to produce suboptimal activation, the platelets could now be stimulated only poorly or not at all by either epinephrine or thrombin. This was also true for anti-HPA-1b, which, although not inducing aggregation or ATP release by itself, was capable of almost completely blocking thrombin-induced platelet activation. The thrombin-inhibiting activity of these antibodies could partially be reversed by pretreating antibody-coated platelets with epinephrine immediately followed by stimulation with thrombin. These findings suggest that transfused platelets may either be activated or inhibited by reaction with various platelet antibodies. Therefore it is conceivable that the presence of platelet reactive antibodies in multiply transfused recipients may contribute to the increased thrombotic and hemorrhagic symptoms often observed among these patients.

Posttransfusion purpura due to an alloantibody reactive with glycoprotein Ia/IIa (anti-HPA-5b).

A 38-year-old woman (JT) was diagnosed with posttransfusion purpura and significant posthysterectomy vaginal bleeding 9 days after the transfusion of 2 U of packed red blood cells. Analysis of JT's serum by a monoclonal antibody-antigen capture enzyme-linked immunosorbent assay method showed the presence of anti-HPA-5b (anti-Bra) antibodies directed against an epitope on platelet glycoprotein (GP) la of the GPIa/IIa complex. The patient's serum immunoprecipitated two proteins from 125I-labeled HPA-5b positive platelets that migrated under both nonreducing and reducing conditions on sodium dodecyl sulfate polyacrylamide gels at molecular weights characteristic of GPIa (150 Kd and 165 Kd, respectively) and GPIIa (120 Kd and 145 Kd, respectively). These bands were not precipitated when 125I-labeled HPA-5b negative platelets were used. Platelet typings performed on JT and her three children showed that the patient was HPA-5b negative and one of her children was HPA-5b positive. Platelets obtained from one of the donors who provided blood for the inciting transfusion also typed as HPA-5b positive. These findings demonstrate that posttransfusion purpura may be induced by antibodies directed against an alloantigenic epitope, namely HPA-5b (Bra), located on GPIa/IIa. Moreover, clinically significant bleeding can be associated with antibody reactions directed against this GP complex.

Synthesis of 10,11-dihydroxydihydroquinidine N-oxide, a new metabolite of quinidine. Preparation and 1H-nmr spectroscopy of the metabolites of quinine and quinidine and conformational analysis via 2D COSY nmr spectroscopy.

The first synthesis of 10,11-dihydroxydihydroquinidine N-oxide [7b], a recently isolated metabolite of quinidine, was accomplished in three steps from 1b. The related congener 7a in the quinine series was also prepared, as well as two other analogues 3a and 4a. In addition, the previously reported human metabolites 2a, 5a, and 6a of quinine [1a] and those 2b, 3b, 4b, 5b, and 6b of quinidine [1b] were synthesized. The chemical shift and coupling constants for all of the metabolites of quinine and quinidine were assigned via 2D COSY 1H-nmr spectroscopy. Moreover, the conformations of these metabolites in solution were found to parallel those of the parent alkaloids, quinine [1a] and quinidine [1b], respectively.