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.     

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 K₂EDTA, was incubated with 0.6?µg/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.     

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.     

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.     

Evaluation of platelet glycoprotein Ib by fluorescence flow cytometry

Platelet glycoprotein Ib (GpIb), a receptor for von Willebrand's factor (vWF), was studied by way of fluorescence flow cytometry. Using a sandwich staining technique, GpIb was identified by a monoclonal antibody (6D1) directed against an epitope close to the vWF binding site. Platelets from normal individuals were symmetrically distributed with respect to GpIb content. Treatment of washed platelets with plasmin resulted in progressive loss of GpIb as measured by fluorescence flow cytometry and by loss of agglutination response when combined with ristocetin in the presence of vWF. In mixing experiments with GpIb-deficient and normal platelets, it was possible to detect a subpopulation of deficient cells comprising 2% of the total population. Streptokinase treatment of platelet-rich plasma caused loss of the agglutination response to ristocetin and the emergence of a population of GpIb-deficient platelets. Fluorescence flow cytometry appears to be an important new technique by which to study platelet surface receptors.     

Endotoxin induced platelet microvesicle formation measured by flow cytometry

Endotoxin (lipopolysaccharide, LPS) is a major component of the outermost membrane of gram-negative bacteria. Endotoxin is an important mediator of septic shock and it is involved in the development of disseminated intravascular coagulation (DIC), which is a dreaded complication of gram-negative bacterial infections. Platelet microvesicles are platelet derived vesicles that are formed during platelet activation. These microvesicles are too small to be detected by cell counters used in clinical laboratories, but they are active in haemostasis and may thus contribute to the development of DIC. We have used flow cytometry to study the in vivo effect of endotoxin on platelet microvesicle formation in clinical material and in a porcine model. We found increased levels of platelet microvesicles in patients with gram-negative bacterial sepsis. Endotoxin infusion in pigs caused microvesicle formation of up to four times the initial value. Thus, the formation of such microvesicles, which are associated with increased coagulation activity, may be initiated by endotoxin.     

Comparison of platelet activation in platelet concentrates measured by flow cytometry or ADVIA 2120

Background and Objectives The ADVIA 2120 Haematology Analyser is capable of measuring parameters that can be used as markers of platelet activation, mean platelet component (MPC), platelet component distribution width (PCDW) and mean platelet mass (MPM). This study investigated the degree of correlation of these measures of platelet granularity with CD62P measurement of platelet activation by flow cytometry in platelet concentrates. Materials and Methods Pooled platelets in plasma/citrate phosphate dextrose (CPD) anticoagulant or apheresis platelets in plasma/acid citrate dextrose formula A (ACD‐A) anticoagulant were evaluated. Pooled platelets were tested during 13 day storage, and apheresis platelets within 24 h of venepuncture. These were assessed for platelet activation using CD62P and the ADVIA, with or without extra EDTA anticoagulant. Results In pooled platelets, PCDW correlated strongly with CD62P, both with and without the addition of extra EDTA anticoagulant. There was a good correlation between MPC and CD62P with additional EDTA, but a weaker correlation without extra EDTA. There was no correlation between CD62P and MPM. In apheresis platelets the correlation between PCDW and CD62P was poor, whereas MPC correlated strongly with CD62P if EDTA anticoagulant was added. Conclusion The usefulness of ADVIA platelet granularity measures to predict the degree of platelet activation depends upon the anticoagulant present in the platelet concentrate, and whether extra EDTA is added to the sample. Although ADVIA MPC and PCDW measurement could not replace CD62P or other gold standard methods of assessing platelet activation, these ADVIA 2120 parameters may provide a quick check of platelet concentrate quality.     

Application of flow cytometry to platelet disorders

Flow cytometry is a powerful and versatile tool that can be used to yield definitive information regarding the phenotypic status of platelets. The method provides a quantitative assessment of the physical and antigenic properties of platelets (e.g., surface expression of receptors, bound ligands, components of granules, or interactions of platelets with other platelets, other blood cells, or components of the plasma coagulation system), thereby facilitating the diagnosis of inherited or acquired platelet disorders (e.g., Bernard-Soulier syndrome, Glanzmann thrombasthenia, storage pool disease), the pathological activation of platelets (e.g., in the setting of acute coronary syndromes, cerebrovascular ischemia, peripheral vascular disease, cardiopulmonary bypass), and changes in the ability of platelets to activate via specific stimuli (e.g., efficacy of antiplatelet therapies). Accordingly, this review summarizes the key technical and methodologic components of flow cytometric analysis of platelets, as well as specific examples of its application to diagnosis and patient care.     

Quantitation of platelet aggregation and microaggregate formation in whole blood by flow cytometry

Platelet aggregation and microaggregate formation were measured in samples of stirred whole blood by flow cytometry. Blood samples were stirred in a multi-sample agitator with ADP, fixed and labelled with a platelet-specific CD42a-FITC fluorescent antibody. The blood was then diluted and applied directly to a flow cytometer. Platelets were identified using a gating procedure based on their expression of CD42a and then quantified. Aggregation was monitored as a fall in the number of single platelets. Both reversible and irreversible aggregation responses to ADP were determined and these were found to correlate directly with aggregation responses determined using a well-established single platelet counting technique using the Ultra-Flo 100 Whole Blood Platelet Counter. We found from flow cytometry that ADP-induced aggregation was coupled with a transient formation of platelet microaggregates over the initial 60 s following ADP addition. Assessment of single platelet loss by flow cytometry was found to be a reliable way of monitoring aggregation responses and provided new information on rapid microaggregate formation in ADP-stimulated blood.     

Heterogeneity of platelet secretion in response to thrombin demonstrated by fluorescence flow cytometry

Platelet membrane changes that accompany in vivo activation may be difficult to detect if only a small fraction of circulating platelets has undergone secretion. This study describes an approach to that problem by using a method to measure the number of molecules of fluorescein-labeled antibody bound to individual platelets by flow cytometry. The platelet response to different concentrations of thrombin was determined by measuring the binding of a monoclonal antibody (S12) to GMP-140, an alpha-granule membrane protein that becomes exposed on the platelet surface during alpha-granule secretion. Unstimulated platelets bound a mean of 1,120 molecules of S12 per cell, and 93% of platelets bound less than 2,000 molecules. Platelet stimulation by 0.25 U/mL thrombin caused maximum S12 binding with a mean of 7,529 molecules per cell. Even at low concentrations of thrombin (0.025 U/mL), 5% of platelets were maximally activated, binding over 7,000 molecules of S12 per cell. Conversely, at 0.25 U/mL thrombin, 13% of platelets continued to bind less than 2,000 molecules of S12 per cell. A mixture of as little as 5% thrombin-activated platelets with unstimulated platelets could be detected by this method. Therefore flow cytometry offers an important tool for investigating patients who may have circulating activated platelets as part of a disorder predisposing to thrombosis or hemorrhage.     

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.     

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.     

Agonists-induced platelet activation varies considerably in healthy male individuals: studies by flow cytometry

Flow cytometric evaluation of platelet function extends our understanding of platelets’ role in various clinical conditions associated with either bleeding disorders, thrombosis, or monitoring of antiplatelet therapy. The use of suboptimal concentrations of various agonists may allow assessing the “activatability” of platelets. We determined platelet responsiveness to thrombin-receptor-activating peptide-6, arachidonic acid, adenosine 5c-diphosphate (ADP), epinephrine, collagen, and ristocetin at suboptimal concentrations by determination of P-selectin expression and binding of PAC-1 in 26 healthy male individuals. The response varied considerably from one individual to the next. However, within individuals, responses to all agonists except collagen correlated strongly (p<0.05), suggesting a global variability of platelet responses. Moreover, P-selectin expression and PAC-1 binding were strongly correlated (p<0.05). Interestingly, with epinephrine, PAC-1 positive events outnumbered P-selectin positive events, while this was not seen with the other agonists. Thus, epinephrine may specifically affect the conformational switch mechanism and receptor clustering. Our data indicate that the in vitro response to suboptimal concentrations of agonists varies, but individuals with selective platelet defects may still be identified based on data obtained with the various agonists.     

Blood platelet activation evaluated by flow cytometry: optimised methods for clinical studies

A variety of flow cytometry techniques are in use to evaluate in vivo blood platelet activation. We have in this study further developed and optimised these methods to be suitable for use in clinical studies. By preloading the Monovette® EDTA vacuum blood sampling tubes with 1/8 vol 4% (w/v) paraformaldehyde (PFA), we were able to assess platelet CD62P (P-selectin) expression in whole blood with less than 0.2% activated platelets. No washing or neutralising steps were required to remove excess fixative. Both basal and agonist-stimulated CD62P expression were stable for at least 48 h after sampling. The standard curve was linear from 1.9 (basal) to 8.1·10 3 (TRAP-stimulated) molecules of equivalent soluble fluorochrome units (MESF) in phycoerythrein-conjugated anti-CD62P labelled whole blood samples. These assay conditions were also well suited for assessment of platelet expression of CD41, CD42a, CD61 and CD63. The preanalytic storage period was extended from 10 min to at least 2 h for platelet PAC–1 and fibrinogen binding analysis by preloading Monovette® citrate tubes with 8/10 vol buffer. With PFA preloading, blood sampled into citrated tubes could be analysed for fractions of microparticles and platelet–platelet aggregates as well as for aggregate size.     

Effects of interferon on the cell cycle of human hepatoma HLF cells analyzed by flow cytometry

Growth inhibition by interferon (IFN) was investigated in human hepatoma HLF cells by use of flow cytometry to study the cell cycle. INF-alpha or -beta inhibited growth more than IFN-gamma. Use of either IFN-alpha or -beta and IFN-gamma at the same time inhibited growth more than with any one kind of IFN, but use of IFN-alpha and -beta together did not cause much inhibition. IFN inhibited growth by causing cells to accumulate in the S phase instead of moving on to the G2 phase. Accumulation in the S phase was less with IFN-gamma than with -alpha or -beta. It increased with the combination of IFN-alpha or -beta with IFN-gamma, but not with the combination of IFN-alpha and -beta.     

Blood platelet activation evaluated by flow cytometry: optimised methods for clinical studies

A variety of flow cytometry techniques are in use to evaluate in vivo blood platelet activation. We have in this study further developed and optimised these methods to be suitable for use in clinical studies. By preloading the Monovette EDTA vacuum blood sampling tubes with 1/8 vol 4% (w/v) paraformaldehyde (PFA), we were able to assess platelet CD62P (P-selectin) expression in whole blood with less than 0.2% activated platelets. No washing or neutralising steps were required to remove excess fixative. Both basal and agonist-stimulated CD62P expression were stable for at least 48 h after sampling. The standard curve was linear from 1.9 (basal) to 8.1 x 10(3) (TRAP-stimulated) molecules of equivalent soluble fluorochrome units (MESF) in phycoerythrein-conjugated anti-CD62P labelled whole blood samples. These assay conditions were also well suited for assessment of platelet expression of CD41, CD42a, CD61 and CD63. The preanalytic storage period was extended from 10 min to at least 2 h for platelet PAC-1 and fibrinogen binding analysis by preloading Monovette citrate tubes with 8/10 vol buffer. With PFA preloading, blood sampled into citrated tubes could be analysed for fractions of microparticles and platelet-platelet aggregates as well as for aggregate size.     

Analysis of human platelet glycoproteins IIb-IIIa and Glanzmann's thrombasthenia in whole blood by flow cytometry

Antibodies that bind to human platelet membrane glycoproteins IIb and IIIa were used to develop methods for analyzing platelet membrane components by flow cytometry. Platelets were tentatively identified by their low-intensity light scatter profiles in whole blood or platelet- rich plasma preparations. Identification of this cell population as platelets was verified by using platelet-specific antibodies and fluorescein-conjugated antiimmunoglobulin. Two-parameter analysis of light scatter versus fluorescence intensity identified greater than 98% of the cells in the "platelet" light scatter profile as platelets due to their acquired fluorescence. Both platelet-rich plasma and whole blood were used to study platelet membrane glycoproteins IIb and IIIa on a single cell basis in an unwashed system. Prostacycline was included in these preparations as a precautionary step to inhibit platelet aggregation during analysis. Flow cytometry is a successful technique for rapid detection of platelet membrane defects such as Glanzmann's thrombasthenia. Platelets from Glanzmann's thrombasthenic individuals were readily distinguished from platelets with normal levels of glycoprotein IIb and IIIa and from platelets with glycoprotein levels characteristic of heterozygote carriers of this disorder. This technique provides a sensitive tool for investigating platelet functional defects due to altered expression or deficiency of platelet surface proteins.     

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.