Laboratory Markers of Platelet Production and Turnover.

Platelets are formed from bone marrow megakaryocytes, circulate in blood for 7-10 days, and then are destroyed in the spleen and/or liver. Platelet production depends on the megakaryocyte population state in the bone marrow: number and size of the cells. The platelet turnover, i.e., the number of platelets passing through the bloodstream in a certain time, is determined by both the rate of their production and the rate of their destruction. The review considers laboratory markers, which are used to assess platelet production and turnover in the patients with hematologic and cardiovascular pathologies. These markers include some characteristics of platelets themselves: (i) content of reticulated ("young") forms in the blood detected by their staining with RNA dyes; (ii) indicators of the platelet size determined in hematology analyzers (mean volume, percentage of large forms) and in flow cytometers (light scattering level). Alterations of platelet production and turnover lead to the changes in blood plasma concentrations of such molecules as thrombopoietin (TPO, main mediator of megakaryocyte maturation and platelet formation in the bone marrow) and glycocalicin (soluble fragment of the membrane glycoprotein Ib detached from the surface of platelets during their destruction). Specific changes in the markers of platelet production and turnover have been observed in: (i) hypoproductive thrombocytopenias caused by suppression of megakaryocytes in the bone marrow; (ii) immune thrombocytopenias caused by accelerated clearance of the autoantibody-sensitized platelets; and (iii) thrombocytosis (both primary and reactive). The paper presents the data indicating that in patients with cardiovascular diseases an increased platelet turnover and changes in the corresponding markers (platelet size indexes and content of reticulated forms) are associated with the decreased efficacy of antiplatelet drugs and increased risk of thrombotic events, myocardial infarction, and unstable angina (acute coronary syndrome).

Platelet reticulated forms, size indexes and functional activity. Interactions in healthy volunteers.

Reticulated platelets (RP) are young, functionally active platelet forms which are detected by RNA staining. Their content in the circulation reflects the intensity of bone marrow thrombocytopoesis. The aim of this study was to assess in healthy volunteers the relationship between RP percentage and platelet size and activity. RP were quantitated by thiazole orange staining using flow cytometry. Platelet size indexes included mean platelet volume (MPV), platelet large cell ratio (P-LCR) measured in a Coulter type hematological analyzer and forward scattering (FSC) measured in a flow cytometer. Platelet functional activity was evaluated by expression of activated glycoprotein (GP) IIb-IIIa (PAC-1 antibody binding) and P-selectin with the use of flow cytometry. Platelets were activated by thrombin receptor activating peptide (TRAP) (10 and 1 µM) and ADP (20 and 2.5 µM). The percentage of RP in healthy volunteers varied from 2.9% to 23.8% (mean ± SD ‒ 11.7 ± 4.7%, n = 99) and correlated with all platelet size indexes: MPV, P-LCR and FCS (r from 0.452 to 0.529, p < .001, n = 87-99). On average, RP were distributed at a ratio of 9:1 between 50% subpopulations of large and small platelets according to their FSC index. Expression of GP IIb-IIIa activated form correlated with RP percentage and platelet size indexes when platelets were activated by TRAP and ADP at both applied concentrations (r from 0.309 to 0.560, p from 0.014 to < 0.001, n = 50-62). P-selectin expression correlated with RP percentage and platelet size indexes when platelets were activated by 10 µM TRAP inducing maximum expression of this activation marker (r from 0.332 to 0.556, p from 0.008 to < 0.001, n = 65), but not by weaker agonists: 1 µM TRAP, 20 and 2.5 µM ADP (r < 0.3, n = 54-66). Thus, high RP content in healthy volunteers is associated with increased platelet size and activity in the whole platelet population.

Circulating antiplatelet antibodies in pregnant women with immune thrombocytopenic purpura as predictors of thrombocytopenia in the newborns.

Newborns from mothers with immune thrombocytopenic purpura (ITP) have a risk of thrombocytopenia due to passage of maternal antiplatelet antibodies into fetal/neonatal circulation. We looked for predictors of neonatal thrombocytopenia (nTP) in pregnant women with ITP. One hundred pregnant women with platelet count <100 × 109/l, no non-immune causes of thrombocytopenia and increased platelet associated IgG (PA-IgG) were included in the study. Thirty seven and 63 of them gave birth to babies with and without nTP, respectively (nTP+ and nTP- groups). Platelet count, mean platelet volume, PA-IgG, antiplatelet circulating antibodies (cAB), time of ITP onset (before or during pregnancy), and frequency of corticosteroid treatment were compared in these groups. There were no differences in all test parameters between nTP+ and nTP- groups except cAB. These antibodies were detected in 33 out of 37 in nTP+ group and in 2 out of 63 mothers in nTP- group (p < 0.001). The sensitivity of this test was 89% and its specificity was 97%. A strong reverse correlation (r = -0.749, p < 0.001) was established between maternal cAB titer and neonatal platelet count. Antibodies against glycoproteins IIb-IIIa and/or Ib were identified in antigen specific MAIPA (Monoclonal Antibody Immobilization of Platelet Antigen) assay only in 10 out of 19 (53%) test sera with cAB. Antiplatelet cAB in pregnant women with ITP could serve as reliable predictors of nTP in their babies.

Relationships of mean platelet volume and plasma thrombopoietin with glycocalicin levels in thrombocytopenic patients.

BACKGROUNDS/AIMS: Relationships of mean platelet volume (MPV) and thrombopoietin (TPO) with platelet turnover assessed by glycocalicin measurement were evaluated in thrombocytopenic patients. METHODS: MPV, glycocalicin and platelet-associated IgG (PA-IgG) were measured in 107 patients with idiopathic thrombocytopenic purpura (ITP) and 19 patients with hypoproductive thrombocytopenia (HPT; aplastic anemia or leukemia), and TPO was measured in 53 ITP and 12 HPT patients. All the included ITP patients had PA-IgG ≥300% and glycocalicin ≥50% of control values, and HPT patients had PA-IgG <300% and glycocalicin <50% of control values. RESULTS AND CONCLUSIONS: MPV was higher in ITP than in HPT patients: 9.56 ± 1.69 and 7.59 ± 0.90 fl (p < 0.001). In the ITP group a direct correlation was detected between MPV and glycocalicin (r = 0.344, p < 0.001). This interaction was essentially expressed in patients with normal/increased glycocalicin (≥100% of control; r = 0.470, p < 0.001, n = 64). TPO was greatly enhanced in HPT in comparison with ITP patients (958 ± 659 and 11 ± 27 pg/ml, p < 0.001). In the ITP group a reverse correlation was detected between TPO and glycocalicin (r = -0.373, p = 0.006).

Differential procoagulant activity of microparticles derived from monocytes, granulocytes, platelets and endothelial cells: impact of active tissue factor.

: Microparticles released by activated/apoptotic cells exhibit coagulation activity as they express phosphatidylserine and some of them - tissue factor. We compared procoagulant properties of microparticles from monocytes, granulocytes, platelets and endothelial cells and assessed the impact of tissue factor in observed differences. Microparticles were sedimented (20 000g, 30 min) from the supernatants of activated monocytes, monocytic THP-1 cells, granulocytes, platelets and endothelial cells. Coagulation activity of microparticles was examined using plasma recalcification assay. The size of microparticles was evaluated by dynamic light scattering. Tissue factor activity was measured by its ability to activate factor X. All microparticles significantly accelerated plasma coagulation with the shortest lag times for microparticles derived from monocytes, intermediate - for microparticles from THP-1 cells and endothelial cells, and the longest - for microparticles from granulocytes and platelets. Average diameters of microparticles ranged within 400-600 nm. The largest microparticles were produced by endothelial cells and granulocytes, smaller - by monocytes, and the smallest - by THP-1 cells and platelets. The highest tissue factor activity was detected in microparticles from monocytes, lower activity - in microparticles from endothelial cells and THP-1 cells, and no activity - in microparticles from platelets and granulocytes. Anti-tissue factor antibodies extended coagulation lag times for microparticles from monocytes, endothelial cells and THP-1 cells and equalized them with those for microparticles from platelets and granulocytes. Higher coagulation activity of microparticles from monocytes, THP-1 cells and endothelial cells in comparison with microparticles from platelets and granulocytes is determined mainly by the presence of active tissue factor.