Investigation of platelet function and platelet disorders using flow cytometry

Patients with thrombocytopenia or platelet disorders are at risk of severe bleeding. We report the development and validation of flow cytometry assays to diagnose platelet disorders and to assess platelet function independently of platelet count. The assays were developed to measure glycoprotein levels (panel 1) and platelet function (panel 2) in sodium citrated blood. Twenty healthy volunteers and five patients diagnosed with different platelet disorders were included. Glycoprotein expression levels of the receptors Ia, Ib, IIb, IIIa and IX were measured and normalised with forward scatter (FS) as a measurement of platelet size. Platelet function was assessed by CD63, P-selectin and bound fibrinogen in response to arachidonic acid, adenosine diphosphate (ADP), collagen-related peptide, ristocetin and thrombin receptor-activation peptide-6. All patients except one with suspected δ-granule defect showed aberrant levels of glycoproteins in panel 1. Glanzmann's thrombasthenia and genetically verified Bernard–Soulier syndrome could be diagnosed using panel 1. All patients showed reduced platelet function according to at least one agonist. Using panel 2 it was possible to diagnose Bernard–Soulier syndrome, δ-granule defect and GPVI disorder. By combining the two assays, we were able to diagnose different platelet disorders and investigate platelet function independent of platelet count.     

Measurement of reticulated platelets by simple flow cytometry: An indirect thrombocytopoietic marker

BACKGROUND: The aim of this study was to determine whether measurement of reticulated platelets (RP) by flow cytometry directly from whole blood, with no fixation or manipulation, is as useful a thrombocytopoietic marker as other more complex techniques. METHODS: RP percentage was prospectively assessed in thrombocytopenic patients (platelets <100x10(9)/L) and non-thrombocytopenic controls using a direct, whole-blood, dual-labelling flow cytometric method. Direct, whole-blood double coverage was achieved using a monoclonal antiglycoprotein (GP)-III antibody (CD61-PerCP(R)) for platelet identification and thiazol orange (Retic-count(R)) as platelet mARN stain. After establishing thrombocytopenia etiology, patients were grouped according to whether their rate of thrombopoiesis was increased or decreased. RESULTS: RP were measured in 53 thrombocytopenic patients with several etiologies and in 53 non-thrombocytopenic controls. The mean RP in 14 thrombocytopenic patients with no increased thrombopoietic activity was 4.8% (95% CI: 3.2-6.4) and the RP absolute number was 1.98x10(9)/L (95% CI: 1.3-2.6). The mean RP in 17 thrombocytopenic patients with increased thrombopoietic activity was 29.4% (95% CI: 24.7-34.1) and the RP absolute number was 7.24x10(9)/L (95% CI: 4.9-9.5). CONCLUSIONS: RP measurement by flow cytometry, directly from whole blood without manipulation, is a useful screening test to differentiate thrombocytopenia with high or low thrombopoietic activity.     

Evaluation of platelet turnover by flow cytometry

The number of circulating newly produced platelets depends on the thrombopoietic capacity of bone marrow as well as platelet removal from the bloodstream. Flow cytometric analysis with thiazole orange (TO), a fluorescent dye that crosses platelet membranes and binds intracellular RNA, has been used to measure circulating reticulated platelets (RPs) with high RNA content as an index of platelet turnover. We first assessed the specificity of TO flow cytometry and then applied this method in the diagnosis of thrombocytopenia caused by impaired platelet production or increased destruction. We also explored the utility of TO flow cytometry to predict thrombocytopoiesis after chemotherapy-induced bone marrow aplasia. Venous blood, anticoagulated with K(2)EDTA, was incubated with 0.6 microg/ml TO plus an anti-GPIIIa monoclonal antibody. The mean percentage of RPs in control subjects (n = 23) was 6.13 +/- 3.09%. RPs were 10.41 +/- 9.02% in patients (n = 10) with hematological malignancies during aplasia induced by chemotherapy and a significant increase in RPs (35.45 +/- 6.11%) was seen in the recovery phase. In 10 patients with idiopathic thrombocytopenic purpura, the percentage of TO positive platelets was 67.81 +/- 18.79 (P < 0.001 vs. controls). In patients with thrombocytopenia associated with hepatic cirrhosis (n = 21; 21.04 +/- 16.21%, P < 0.001 vs. controls) or systemic lupus erythematosus (n = 6, 29.08 +/- 15.57%; P < 0.001 vs. controls) increases in TO-stained platelets were also observed. Measurement of TO positive platelets may be a reliable tool for the laboratory identification of platelet disorders, with a higher sensitivity than measurement of platelet volume. Measurement of RPs may also prove useful to recognize the underlying pathogenetic mechanisms in thrombocytopenia.     

Agreement between blood draw techniques for assessing platelet activation by flow cytometry

It is widely believed that assays of platelet activation are susceptible to preanalytical variables related to blood draw technique. We assessed platelet activation by whole blood flow cytometry and investigated the effects of: (1) drawing blood into vacuum tubes or manually aspirated syringes, and (2) discarding the first drawn blood sample (discard tube). Platelet P-selectin expression and platelet-monocyte complexes were measured by flow cytometry under both basal conditions and following stimulation with 0.1, 1, or 10 µM ADP. Bland-Altman plots demonstrated agreement between results for vacuum tube and syringe-aspirated samples with an a priori-defined clinically relevant agreement limit of 5%. Agreement of results was also observed between discard tube and second draw samples for both vacuum-driven and manually aspirated blood. We conclude that a vacuum tube or a manually-aspirated syringe can be used when assessing platelet activation by flow cytometry and that there is no need for a discard tube.     

Multiple platelet defects identified by flow cytometry at diagnosis in acute myeloid leukaemia

Summary Previous findings of megakaryocytic hypogranulation and dysmegakaryocytopoietic features in acute myeloid leukaemia (AML) strongly indicate defects in platelet production. The bleeding tendency of these patients may result from dysregulated platelet production, resulting in thrombocytopenia as well as qualitative platelet defects. The present study examined platelet function at diagnosis in 50 AML patients by whole blood flow cytometry. Following in vitro platelet agonist stimulation, platelet activation markers were analysed and compared with 20 healthy individuals. To detect recent in vivo platelet activation, plasma soluble P-selectin (sP-selectin) was measured. Flow cytometric analysis of platelet activation markers demonstrated reduced CD62P [35.6 vs. 118.5 x 10(3) molecules of equivalent soluble fluorochrome (MESF); P < 0.0001], CD63 (11.3 vs. 50.7 x 10(3) MESF; P < 0.0001), and PAC-1 (41.5 vs. 90.5%; P = 0.0001) while reductions in CD42b were abnormal (45.6 vs. 70%; P < 0.0001). sP-selectin levels were similar in patients and healthy controls (0.04 vs. 0.27 fg/platelet; P = 0.84). The presented data indicate that AML pathogenesis may result in multiple platelet defects, involving adhesion, aggregation, and secretion and demonstrate that flow cytometry is a feasible method for platelet function analysis in patients with thrombocytopenia.     

A diagnostic test for heparin-induced thrombocytopenia: detection of platelet microparticles using flow cytometry

Based on our previous observation that heparin-induced thrombocytopenia (HIT) sera can generate platelet microparticles from washed platelets in a heparin-dependent fashion, we developed a test for HIT using flow-cytometry to measure heparin-dependent platelet microparticle formation. During the developmental phase of the assay the optimal physical conditions for microparticle generation were defined. 133 sera were then evaluated using the microparticle assay and the serotonin release assay to determine the threshold for defining a positive result that gave optimal sensitivity and specificity. The microparticle assay was then prospectively evaluated against the serotonin release assay in 202 sera referred to our laboratory for HIT testing. Overall agreement between the two assays was 96% (Cohen's kappa = 0.91). When the clinical data were reviewed on patients whose sera gave discrepant results between the two assays, no case of HIT was detected by one assay and missed by the other. The platelet microparticle assay is as accurate as the serotonin release assay and may be a useful non-radioactive test for HIT.     

Detection of platelet vesicles by flow cytometry

The composition and function of platelet-derived extracellular vesicles (EVs) in health and in disease are a major topic of investigation in biomedical research. However, efforts to delineate specific molecular repertoires and roles for different types of EVs in the circulation are limited not only by the lack of flow cytometers capable of analyzing submicron- and nano-materials across the full size spectrum of plasma EVs, but also by the lack of standardized methods and reference materials that would permit inter-laboratory reproducibility for these analyses. In this review, we summarize the flow cytometry of EVs, with a focus on platelet vesicles in plasma. In addition to delineating the basic principles that govern what precautions must be considered when using flow cytometry for the analysis of platelet vesicles, we provide an overview for how to standardize, control, annotate, and report EV flow cytometry data reproducibly, while looking forward to a next generation of high sensitivity instruments for the analysis of EVs and other submicron biomaterials in the circulation.     

Comparison of reticulated platelet count and mean platelet volume determination in the evaluation of bone marrow recovery after aplastic chemotherapy

Reticulated platelet count provides an estimate of thrombopoiesis in the same way as reticulocyte count is a measure of erythropoiesis. We applied thiazole orange (TO) staining, followed by fluorescence-activated flow-cytometric analysis, to platelets in whole-blood samples from normal subjects and 18 aplastic patients after chemotherapy for haematologic malignancies. The percentage of TO-positive platelets in 30 control subjects was 5.7 +/- 2.4% (mean +/- 1 SD), determining the threshold of reticulated platelet positivity as up to 10.5% (mean + 2 SD). In the 18 patients studied, the mean percentage of TO-positive platelets was 4.3 +/- 1.89% during aplasia and 23.3 +/- 9.43% during bone marrow recovery, respectively (P < 0.05). All patients had a percentage of TO-positive platelets of up to 10.5%. In comparison, mean platelet volume during bone marrow recovery increased in 12 cases of the 18 patients studied. We conclude that flow cytometric analysis of reticulated platelets is a sensitive and specific test for evaluating thrombopoiesis recovery during aplastic chemotherapy, and platelet transfusion should be reconsidered in these patients.     

Tracking and characterisation of transfused platelets by two colour, whole blood flow cytometry

We describe a flow cytometric technique to study transfused platelets in patients. By selecting donor/recipient pairs discrepant for HLA-A2, transfused platelets were identified using anti-HLA-A2 with a detection limit of <5%, and accuracy within 4.3% of predicted (r2 > 0.96, P < 0.0001). In two of three episodes, transfused platelets were present in greater numbers than predicted from increment counts. Platelets with bound fibrinogen fell from 20.9 +/- 23.6% of donor platelets pretransfusion to 1.7 +/- 0.3% 1 h post-transfusion, whereas P-selectin-positive platelets fell gradually, from 24.1 +/- 6.7 to 7.3 +/- 3.3% at 6 h. This method avoids radio or chemical labelling, and could be used to assess novel platelet preparations post-transfusion.     

Evaluation of the platelet counting by Abbott CELL-DYN SAPPHIRE haematology analyser compared with flow cytometry

The Abbot Cell-Dyn Sapphire is a new generation haematology analyser. The system uses optical/fluorescence flow cytometry in combination with electronic impedance to produce a full blood count. Optical and impedance are the default methods for platelet counting while automated CD61-immunoplatelet analysis can be run as selectable test. The aim of this study was to determine the platelet count performance of the three counting methods available on the instrument and to compare the results with those provided by Becton Dickinson FACSCalibur flow cytometer used as reference method. A lipid interference experiment was also performed. Linearity, carryover and precision were good, and satisfactory agreement with reference method was found for the impedance, optical and CD61-immunoplatelet analysis, although this latter provided the closest results in comparison with flow cytometry. In the lipid interference experiment, a moderate inaccuracy of optical and immunoplatelet counts was observed starting from a very high lipid value.     

Correlation between immature platelet fraction and reticulated platelets. Usefulness in the etiology diagnosis of thrombocytopenia

Background: Reticulated platelets (RP) are a surrogate marker for megakaryocytic activity, but the limitation of this determination is the lack of standardization of methodology. The determination of the immature platelet fraction (IPF) is performed in a simple, automated, and reproducible way between laboratories. We analyzed the correlation between IPF and RP, and usefulness of IPF in patients with thrombocytopenia. Methods: RP were determined by flow cytometry using double staining with thiazole orange and CD61 PerCP^®. IPF was performed with Sysmex XE2100 analyzer. We used a control group with normal platelets, and thrombocytopenic patients were classified into three groups: Group 1. Central thrombocytopenia, Group 2. Thrombocytopenia as a result of enhanced peripheral platelet destruction, and Group 3. Peripheral non‐immune thrombocytopenia by abnormal distribution. Results: Fourteen controls and 66 patients were analyzed. Group 1: 25 patients, they had mean and confidence interval 95% (95% CI) for IPF 8.67% (6.49–10.46%) and RP 4.08% (2.86–5.30%). Group 2: 20 patients, they had mean and 95%CI for IPF 16.80% (12.20–21.39%) and RP 16.14% (9.89–22.40%). Group 3: 21 patients, they had mean and 95% CI for IPF 9.04% (6.95–11.14%) and RP 5.23% (3.41–7.05%). The overall Pearson linear correlation between IPF and RP was r: 0.65. There were statistically significant differences in values of IPF and RP between Group 2 and the other two groups (P < 0.01). Conclusion: There is a good correlation between IPF and RP mainly in thrombocytopenia by peripheral destruction. Determination of IPF is an easy technique in their implementation, standardized and reproducible, so it could be a useful screening technique in patients with thrombocytopenia.     

Flow cytometric analysis of platelet cyclooxygenase-1 and -2 and surface glycoproteins in patients with immune thrombocytopenia and healthy individuals

Immature platelets may contain more platelet enzymes such as cyclooxygenase (COX)-1 and COX-2 than mature platelets. Patients with immune thrombocytopenia (ITP) have a higher fraction of immature platelets and can therefore be utilized as a biological model for investigating COX-1 and COX-2 platelet expression. The aims were to develop flow cytometric assays for platelet COX-1 and COX-2 and to investigate the COX-1 and COX-2 platelet expression, platelet turnover, and platelet glycoproteins in ITP patients (n = 10) compared with healthy individuals (n = 30). Platelet count and platelet turnover parameters (mean platelet volume (MPV), immature platelet fraction (IPF), and immature platelet count (IPC)) were measured by flow cytometry (Sysmex XE-5000). Platelet COX-1, COX-2, and the glycoproteins (GP)IIb, IX, Ib, Ia, and IIIa were all analyzed by flow cytometry (Navios) and expressed as median fluorescence intensity. COX analyses were performed in both whole blood and platelet rich plasma (PRP), whereas platelet glycoproteins were analyzed in whole blood only. ITP patients had significantly lower platelet count (55 × 10⁹/L) than healthy individuals (240 × 10⁹/L, p < 0.01), but a higher MPV (p = 0.03) and IPF (p < 0.01). IPC was similar for the two groups (p = 0.74). PRP had significantly lower MPV (p < 0.01) and significantly higher platelet count and IPC (both p-values <0.03) when compared with whole blood. IPF was similar for PRP and whole blood (p = 0.18). COX-1 expression was 10 times higher and COX-2 expression was 50% higher in PRP than in whole blood (p_COX-1 < 0.01, p_COX-2 < 0.01). Platelet COX-1 expression was higher in ITP patients than healthy individuals using whole blood (p_COX-1 < 0.01) and PRP, though this was nonsignificant in PRP (p_COX-1 = 0.17). In ITP patients, positive correlations were found between platelet turnover and COX-1 expression (all p-values <0.01, rho = 0.80–0.94), whereas healthy individuals showed significant though weaker correlations between platelet turnover and COX-1 and COX-2 expressions (all p-values <0.03, rho = 0.44–0.71). GPIIb, IX, and Ib expression was increased in ITP patients compared with healthy individuals (all p-values < 0.03). GPIIb, IX, Ib, and IIIa showed positive correlations with platelet turnover in ITP patients (all p-values <0.02, rho = 0.71–0.94), but weak and nonsignificant correlations in healthy individuals (all p-values >0.14, rho = 0.11–0.28). In conclusion, ITP patients expressed higher COX-1 and platelet glycoprotein levels than healthy individuals. COX-1 and platelet glycoproteins demonstrated positive correlations with platelet turnover in ITP patients. In healthy individuals, COX-1 and COX-2 expression correlated positively with platelet turnover. PRP was more sensitive compared with whole blood as regards determination of COX. Therefore, PRP is the recommended matrix for investigating COX-1 and COX-2 in platelets.     

Flow cytometry for pediatric platelets

The ability of platelets to carry out their hemostatic function can be impaired in a wide range of inherited and acquired conditions: trauma, surgery, inflammation, pre-term birth, sepsis, hematological malignancies, solid tumors, chemotherapy, autoimmune disorders, and many others. Evaluation of this impairment is vitally important for research and clinical purposes. This problem is particularly pronounced in pediatric patients, where these conditions occur frequently, while blood volume and the choice of blood collection methods could be limited. Here we describe a simple flow cytometry-based screening method of comprehensive whole blood platelet function testing that was validated for a range of pediatric and adult samples (n = 31) in the hematology hospital setting including but not limited to: classic inherited platelet function disorders (Glanzmann’s thrombasthenia; Bernard-Soulier, Wiscott-Aldrich, and Hermasky-Pudlak syndromes, MYH9-dependent thrombocytopenia), healthy and pre-term newborns, acute and chronic immune thrombocytopenia, chronic lympholeukemia, effects of therapy on platelet function, etc. The method output includes levels of forward and side scatter, levels of major adhesion and aggregation glycoproteins Ib and IIb-IIIa, active integrins’ level based on PAC-1 binding, major alpha-granule component P-selectin, dense granule function based on mepacrine uptake and release, and procoagulant activity quantified as a percentage of annexin V-positive platelets. This analysis is performed for both resting and dual-agonist-stimulated platelets. Preanalytical and analytical variables are provided and discussed. Parameter distribution within the healthy donor population for adults (n = 72) and children (n = 17) is analyzed.     

Platelet function investigation by flow cytometry: Sample volume,needle size,and reference intervals

Flow cytometry is an increasingly used method for platelet function analysis because it has some important advantages compared with other platelet function tests. Flow cytometric platelet function analyses only require a small sample volume (3.5 mL); however, to expand the field of applications, e.g., for platelet function analysis in children, even smaller volumes are needed. Platelets are easily activated, and the size of the needle for blood sampling might be of importance for the pre-activation of the platelets. Moreover, to use flow cytometry for investigation of platelet function in clinical practice, a reference interval is warranted.

The aims of this work were 1) to determine if small volumes of whole blood can be used without influencing the results, 2) to examine the pre-activation of platelets with respect to needle size, and 3) to establish reference intervals for flow cytometric platelet function assays.

To examine the influence of sample volume, blood was collected from 20 healthy individuals in 1.0 mL, 1.8 mL, and 3.5 mL tubes. To examine the influence of the needle size on pre-activation, blood was drawn from another 13 healthy individuals with both a 19- and 21-gauge needle. For the reference interval study, 78 healthy adults were included. The flow cytometric analyses were performed on a NAVIOS flow cytometer (Beckman Coulter, Miami, Florida) investigating the following activation-dependent markers on the platelet surface; bound-fibrinogen, CD63, and P-selectin (CD62p) after activation with arachidonic acid, ristocetin, adenosine diphosphate, thrombin-receptor-activating-peptide, and collagen.

The study showed that a blood volume as low as 1.0 mL can be used for platelet function analysis by flow cytometry and that both a 19- and 21-gauge needle can be used for blood sampling. In addition, reference intervals for platelet function analyses by flow cytometry were established.     

Flow cytometry analysis of platelet cyclooxygenase-2 expression: induction of platelet cyclooxygenase-2 in patients undergoing coronary artery bypass grafting

There are conflicting reports about the expression of cyclooxygenase (COX)-2 in human platelets. The present study describes a flow cytometric method for the measurement of platelet COX. Both COX-1 and COX-2 were shown to be expressed in platelets from patients undergoing a coronary artery bypass graft. There was a significant increase in COX-2 expression at day 5 as compared with pre-surgery values (mean fluorescence 12.31 +/- 0.88 versus 9.15 +/- 0.88; means +/- SEM, n = 7, P < 0.05), whereas COX-1 levels did not change (13.45 +/- 1.11 versus 12.38 +/- 1.41; n = 7, P > 0.05).     

Flow cytometry analysis of platelet P‐selectin expression in whole blood – methodological considerations

P‐selectin is an adhesion molecule found in the alpha granules of platelets. Activation occurs in response to a range of inflammatory and thrombotic agents resulting in rapid up‐regulation. Flow cytometry methods have recently been described for the analysis of platelet P‐selectin expression in whole blood. While introducing these methods into our laboratory it was noted that expression could be stimulated, in vitro, in a number of ways. This study shows that red cell lysis, the anticoagulant K₃ EDTA and the time elapse between blood collection and antibody labelling had statistically significant effects on P‐selectin expression. Post‐labelling fixation, with CellFIX, caused no significant effect. We conclude that blood for P‐selectin analysis should be collected in sodium citrate and that red cell lysis and centrifugation should be avoided. When comparing samples, the time between collection and labelling should be standardized. The relatively high CV for the assay indicates that all samples should be labelled and analysed in duplicate with the mean level reported.     

Prediction of haemorrhage in the early stage of acute myeloid leukaemia by flow cytometric analysis of platelet function

Haemorrhage is often responsible for the lethal course of acute myeloid leukaemia (AML). Previously, multiple platelet function defects were identified by flow cytometric analysis of platelet activation markers in AML. The role of flow cytometric analysis of platelet function in characterization of prognostic markers of haemorrhage in AML patients has not been well elucidated. The objective of this prospective study was to analyse platelet function in 50 AML patients at diagnosis and to compare results with clinical bleeding score, graded by common toxicity criteria. Platelet activation markers CD62P, CD42b, CD63 and PAC-1 were analysed following in vitro activation by thrombin receptor activating peptide. The following plasma haemostasis parameters were measured: soluble P-selectin, activated partial thromboplastin time, thrombin time, prothrombin time, D-dimer, fibrinogen, and von Willebrand factor antigen. In a multivariate analysis, P-selectin (CD62P) <36 molecules of equivalent soluble fluorochrome x 10(3) (P < 0.0015) and platelet count <40 x 10(9)/l (P = 0.01) were significant predictors of haemorrhage at diagnosis. Haemorrhage at diagnosis predicted grade 3-4 haemorrhage in the first 28 d following diagnosis (P = 0.018). The presented results indicate that low P-selectin is a prognostic marker of haemorrhage in AML.