The mitochondrial membrane potential in human platelets: a sensitive parameter for platelet quality

BACKGROUND: Deterioration of platelet (PLT) quality during storage is accompanied by an increase in lactate production, indicating a decrease in mitochondrial function. In this study, the optimal conditions under which the fluorescent dye JC-1 can be used to detect changes in mitochondrial function in PLTs were established. STUDY DESIGN AND METHODS: PLTs were incubated at 37 degrees C in synthetic medium under various conditions of JC-1 loading. In the presence of a high membrane potential, this dye accumulates in the mitochondria with a concomitant increase in red fluorescence. After JC-1 loading, the ratio of red (FL2) to green (FL1) fluorescence was determined by flow cytometry. RESULTS: The FL2-to-FL1 ratio of PLTs (3 x 10(7)/mL, loaded with 0.5 micromol/L JC-1) amounted to about 5 in 1-day-old PLTs. At higher dye concentrations, the FL2-to-FL1 ratio was significantly lower, suggesting uncoupling by the dye itself. Plasma concentrations above 3 percent significantly affected the JC-1 signal. The FL2-to-FL1 ratio showed a dose-dependent decrease to an uncoupler of oxidative phosphorylation or to inhibition of the respiratory chain. JC-1-loaded PLTs showed a clear decrease in FL2-to-FL1 ratio after prolonged storage or upon ultraviolet (UV) illumination. Only after UV treatment did changes in JC-1 signal correlate with changes in CD62P expression. CONCLUSION: The FL2-to-F1 ratio of PLTs loaded with JC-1 is a reliable and sensitive indicator of the mitochondrial membrane potential, provided that the proper experimental conditions have been applied.     

HPA配型在免疫性血小板输注无效中的应用研究

目的探讨以HPA配型解决免疫性血小板输注无效的方案。方法 1)建立PCR-SSP方法检测HPA-1～5基因型检测方法,建立机采血小板供者库;2)采用微柱凝胶法和Capture-P法对32名血小板输血无效患者作血小板同种抗体筛查,并对2种方法比较;3)对血小板同种抗体筛查阳性患者采用已知HPA基因型的标准谱血小板作抗体鉴定并采取HPA基因型同型输注的原则寻找供者。结果 1)采用PCR-SSP方法成功检测出HPA-1～5基因型,并对1 000名血小板供者的HPA-1～5基因型定型;2)32例血小板输注无效病例中,微柱凝胶法检测血小板同种抗体阳性率为50%,Capture-P法血小板抗体阳性检出率为40%;3)32例血小板输血无效病例中2种方法同时血小板抗体阳性13例,其中2例鉴定为抗-HPA,分别为抗-HPA-5b(P=1/84)、抗-HPA-1a(P=1/55)。结论对抗-HPA引起的血小板输注无效患者采用HPA基因型相合的方法寻找供者是有效的。     

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.     

血小板输注无效患者的血小板抗体筛查与配合性输注

目的分析血小板输注无效（PTR）的主要原因,为患者选择适用的血小板,用以提高输注疗效。方法对多次输血患者于输血前后监测血小板计数值,并计算1h和24h血小板增高指数（CCI值）,对判断为血小板输注无效者,采用简易致敏血小板血清学技术（SEPSA）进行血小板抗体筛查,并进行血小板交叉配型,对配合性输注效果进行分析。结果278例多次输血患者发生PTR共88例（31．7％）;88例PTR患者中血小板抗体阳性67例（76．1％）;67例抗体阳性患者,血小板交叉配型成功37例,血小板输注有效32例,有效率达86．5％。结论血小板抗体的产生是导致血小板输注无效的主要免疫性因素,血小板配合性输注能显著提高血小板输注效果。     

Progressive platelet activation with storage: evidence for shortened survival of activated platelets after transfusion

Platelets are known to become activated during storage, but it is unclear whether such activation affects recovery or survival after platelet concentrate (PC) transfusion. With the use of flow cytometry to determine the percentage of platelets expressing the alpha-granule membrane protein 140 (GMP-140), a known adhesive ligand appearing on the platelet surface after activation, several studies were conducted. These investigations evaluated 1) the occurrence of significant platelet activation over time in PCs (n = 46) stored under standard blood bank conditions; 2) the correlation between platelet activation and platelet recovery in normal subjects after PC storage (n = 12), as assessed by the recovery of Indium-labeled platelets; and 3) the recovery of activated and unactivated platelets in thrombocytopenic cancer patients transfused with standard PCs (n = 11). It was determined 1) that an increasing duration of storage of PC was associated with increasing platelet activation as measured by the percentage of platelets expressing GMP-140, progressing from a mean of 4 +/- 2 percent (SD) on the day of collection to a mean of 25 +/- 8 percent by 5 days of storage: 2) that, in normal subjects, posttransfusion recovery of autologous platelets stored for 2 to 4 days and then labeled with In111 was inversely correlated with the percentage of activated platelets in the transfused PC (r = -0.55, p = 0.05); and 3) that, when thrombocytopenic patients were transfused with standard PCs, the recovery of the activated platelets in the transfused PCs averaged only 38 +/- 15 percent of the number predicted by the absolute platelet increment.(ABSTRACT TRUNCATED AT 250 WORDS)     

Single-donor platelets reduce the risk of septic platelet transfusion reactions

BACKGROUND: Septic platelet transfusion reactions (SPTRs) are the most common, serious risk of transfusion. Because SPTRs result from donor skin flora or asymptomatic bacteremia, the use of single-donor platelets (SDPs) has been proposed to reduce the risk of SPTRs from the risks with pools of platelet concentrates (PCs). STUDY DESIGN AND METHODS: Beginning in 1986, all febrile transfusion reactions were evaluated by culture of the platelet bag. Confirmed SPTRs were identified by isolation of the same bacteria from the bag and the patient's blood or by positive Gram's stain of the bag that confirmed a positive platelet culture. In 1987, a program to minimize PC use in favor of SDP use was initiated as a means of reducing SPTRs. RESULTS: In 12 years, the use of SDPs increased from 51.7 percent to 99.4 percent of all platelet transfusions at one institution. SPTRs fell from three events in 1 year to the current rate of one event per year. The incidence of SPTRs decreased from 1 in 4,818 transfusions to 1 in 15,098 transfusions. The rate of SPTRs due to PCs was 5.39 times higher than that of SPTRs due to SDPs (95% CI, 1.89,12.9). CONCLUSION: The use of SDPs is a simple means of reducing SPTRs. Other measures such as sterilization will be required to eliminate all SPTRs.     

Apheresis platelets: Emerging issues related to donor platelet count,apheresis platelet yield,and platelet transfusion dose

Emerging issues in stimulating apheresis platelet donors with platelet growth factors, the relative costs of apheresis and random donor platelet concentrates, optimal platelet transfusion dose, and leucoreduction of platelet products have caused renewed debate regarding apheresis products vs. random, pooled concentrates. The future role of apheresis products in platelet transfusion therapy will in large part be determined by costs, which are increasingly recognized to be influenced by donor platelet count, apheresis yield, and platelet transfusion dose. J. Clin. Apheresis 13:114–119, 1998. © 1998 Wiley-Liss, Inc.     

Automatic detection of immature platelets for decision making regarding platelet transfusion indications for pediatric patients.

Immature or reticulated platelets are known as a clinical marker of thrombopoiesis. Recently, an automatic method was established to detect reticulated platelets as immature platelet fraction (IPF) by means of hematology analyzer XE-2100. We assessed the effects of IPF detection after chemotherapy for various pediatric malignant disorders of 16 patients. Our results indicate that IPF should be considered a useful marker of imminent platelet recovery so that unnecessary platelet transfusion can be avoided.     

Infusible platelet membranes improve hemostasis in thrombocytopenic blood: experimental studies under flow conditions

BACKGROUND: The potential hemostatic effect of infusible platelet membranes (IPM; Cyplex, Cypress Bioscience) prepared from outdated human platelets is investigated. STUDY DESIGN AND METHODS: Increasing concentrations of IPM were added to blood samples anticoagulated with low-molecular-weight heparin, in which platelets and WBC counts had been experimentally reduced by a filtration procedure. Thrombocytopenic blood with IPM was circulated in a perfusion chamber at various shear rates (300, 600, and 1200/sec(-1)), and platelet and fibrin deposition on the surface of a damaged vessel was measured. Prothrombin fragments 1 and 2 (F1+2) levels were also monitored. RESULTS: Under conditions of severe thrombocytopenia (<6000 platelets/microL) IPM did not increase platelet deposition. However, a dose-dependent increase in fibrin deposition was observed with concentrations of IPM ranging from 0.5 to 2 mg per kg in perfusions at 300 and 600 per sec(-1) (p<0.05 vs. thrombocytopenic blood). Experimental studies performed under conditions of moderate thrombocytopenia and higher shear rates (25, 000-30,000 platelets/microL; at 600 and 1200/sec(-1)) showed that IPM concentrations equivalent to 0.5 or 1 mg per kg improved fibrin deposition (33.5 +/- 9.5% and 37.7 +/- 12.8%, respectively, vs. 22.7 +/- 5.2% in controls) and also promoted a moderate increase in platelet deposition, with a concomitant significant increase in the size of platelet aggregates (p<0.05). Exposure of thrombocytopenic blood to a damaged vessel resulted in an increase of F1+2 levels from 0.8 +/- 0.15 to 1.7 +/- 0.22 nM at 300 per sec(-1) and 1.94 +/- 0.46 nM at 600 per sec(-1). Postperfusion levels of F1+2 after the addition of IPM were always similar to levels in untreated controls. CONCLUSION: IPM promotes local procoagulant activity at sites of vascular damage under conditions of severe and moderate thrombocytopenia. IPM also appears to facilitate platelet cohesive functions under conditions of moderate thrombocytopenia.     

Quantitation of phosphatidylserine-exposing platelets in platelet concentrate prepared in routine blood transfusion laboratory

BackgroundPhosphatidylserine (PS) plays important roles in platelets’ pro-coagulant function. However, little is known about assessing this molecule in platelet concentrates (PCs) prepared for routine blood transfusion service.AimTo quantitate the number of PS-exposing platelets in PCs prepared in a routine transfusion laboratory.MethodsPC products were prepared according to routine laboratory procedure. The numbers of PS-exposing platelets in the PCs and in unprocessed whole blood were determined using flow cytometry.ResultsA cross-sectional study of 253 PCs found that they had significantly increased numbers of PS-exposing platelets compared to unprocessed whole blood (47,439 ± 26,500 cells/μL; 5903‒166,156 cells/μL) vs. 30,058 ± 12,958 cells/μL; 8,154-86,606 cells/μL). A heterogeneity study demonstrated that 6% and 2% of the measured PCs and of unprocessed donor whole blood, respectively, showed an increase in the number of PS-exposing platelets that was greater than 2 fold.ConclusionsThe study suggested that the number PS-exposing platelets in PC prepared in a routine transfusion laboratory differs. However, assessment of the number of PS-exposing platelets in platelet products could be a valid measure to use in managing the quality of platelet processing in routine laboratories.     

ABO-identical versus nonidentical platelet transfusion: a systematic review

BACKGROUND: The significance of ABO matching for platelet (PLT) transfusion has not been clearly defined. The primary objective of this report is to assess whether ABO-identical PLT transfusion is associated with improved mortality and/or morbidity for patients with hematologic/oncologic disorders.
STUDY DESIGN AND METHODS: A systematic review to January 2009 was conducted. Data on mortality, morbidity, PLT refractoriness, and PLT increment after transfusion were abstracted.
RESULTS: A total of 100 citations were identified. Nineteen studies were included in the systematic review. A total of 1502 patients from three randomized controlled trials and 16 observational studies were included. Survival, bleeding events, and transfusion reactions were only considered as secondary outcomes in the reports reviewed. The PLT count increment was the primary outcome of several studies and was consistently higher with ABO-identical PLT transfusion. The largest difference in increment between ABO-identical and nonidentical PLT transfusion was 4 × 10⁹/L. No consistent benefit in clinical outcomes was noted. Survival was assessed in three reports with conflicting results. Although two studies described bleeding as an outcome, the assessment of hemorrhage was considered inadequate. In six studies, ABO-nonidentical PLT transfusion was not associated with transfusion reactions, and the results from four studies addressing the impact of ABO-identical PLT transfusion on PLT and red blood cell utilization were conflicting.
CONCLUSION: ABO-identical PLT transfusion results in a higher PLT increment. Randomized controlled trials are required to definitely determine the effect of ABO-identical PLT transfusion on survival, bleeding events, or transfusion reactions.