Platelet functional activity in patients with immune thrombocytopenia

Bodrova V.V.; Khaspekova S.G.; Shustova O.N.; Tsvetaeva N.V.; Mazurov A.V.

doi:10.18097/PBMCR1596

Platelet functional activity in patients with immune thrombocytopenia

Bodrova V.V.¹, Khaspekova S.G.¹, Shustova O.N.¹, Tsvetaeva N.V.², Mazurov A.V.¹

1. Chazov National Medical Research Center of Cardiology, Moscow, Russia
2. National Medical Research Center of Hematology, Moscow, Russia

Section: Clinical and Diagnostic Research

DOI: 10.18097/PBMCR1596 PubMed Id: 40904181

Year: 2025 Volume: 71 Issue: 4 Pages: 288-299

Immune thrombocytopenia (ITP) is one of the most common causes of decreased platelet count. Bleeding is the main clinical symptom of ITP; although its severity correlates with the depth of thrombocytopenia, it may also depend on changes in the functional activity of platelets. In this study we have compared platelet functional activity in healthy volunteers (HV) and in ITP patients, as well as in groups of ITP patients with different levels of bleeding. The study included 65 HV and 84 ITP patients. Platelet activity was assessed by flow cytometry. Platelets were activated with thrombin receptor activating peptide (TRAP) or ADP, and the exposure of activation markers, activated form of glycoprotein (GP) IIb-IIIa and alpha-granule membrane protein P-selectin, was determined on their surface by measuring the binding of PAC-1 and CD62P antibodies, respectively. Platelet-associated IgG (PA-IgG, an indicator of the level of antiplatelet autoantibodies), the percentage of “young” reticular platelets (RP, %) and platelet light scatter (an indicator of their size) were also assessed using flow cytofluorimetry. Platelet binding of PAC-1 (and, to a lesser extent, CD62P binding) was lower in ITP patients than in HV. In ITP patients, PAC-1 binding inversely correlated with the PA-IgG content. In contrast to HV, in ITP patients, PAC-1 and CD62P binding did not directly correlate with the platelet size and RP, %. In ITP patients with severe bleeding, the platelet count was lower, PAC-1 and CD62P binding was reduced and PA-IgG and RP, % levels were increased. Thus, a decrease in the content of activation markers on the platelet surface was registered in ITP patients; it was more pronounced in patients with severe bleeding. It is suggested that the cause of this decrease may be due to the effect of autoantibodies (PA-IgG) on platelets, and in particular on GP IIb-IIIa.

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Keywords: immune thrombocytopenia, platelet function, platelet antibodies, reticular platelets, platelet size, bleeding

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Bodrova, V. V., Khaspekova, S. G., Shustova, O. N., Tsvetaeva, N. V., Mazurov, A. V. (2025). Platelet functional activity in patients with immune thrombocytopenia. Biomeditsinskaya Khimiya, 71(4), 288-299.

References

Despotovic J.M., Bussel J.B. (2019) Immune Thrombocytopenia (ITP). In: Platelets, 4th ed. (Michelson A.D., Cattaneo M., Frelinger A.L., Newman P.J., eds., Academic Press, pp. 707–724. CrossRef Scholar google search
Provan D., Donald M., Arnold D.M., Bussel J.B., Chong B.H., Cooper N., Gernsheimer T., Ghanima W., Godeau B., González-López T.J., Grainger J., Hou M., Kruse C., McDonald V., Michel M., Newland A.C., Pavord S., Rodeghiero F., Scully M., Tomiyama Y., Wong R.S., Zaja F., Kuter D.J. (2019) Updated international consensus report on the investigation and management of primary immune thrombocytopenia. Blood Adv., 3(22), 3780–3817. CrossRef Scholar google search
Martínez-Carballeira D., Bernardo Á., Caro A., Soto I., Gutiérrez L. (2024) Pathophysiology, clinical manifestations and diagnosis of immune thrombocytopenia: contextualization from a historical perspective. Hematol. Rep., 16(2), 204–219. CrossRef Scholar google search
Neunert C., Noroozi N., Norman G., Buchanan G.R., Goy J., Nazi I., Kelton J.G., Arnold D.M. (2015) Severe bleeding events in adults and children with primary immune thrombocytopenia: a systematic review. J. Thromb. Haemost., 13(3), 457–464. CrossRef Scholar google search
Psaila B., Bussel J.B., Frelinger A.L., Babula B., Linden M.D., Li Y., Barnard M.R., Tate C., Feldman E.J., Michelson A.D. (2011) Differences in platelet function in patients with acute myeloid leukemia and myelodysplasia compared to equally thrombocytopenic patients with immune thrombocytopenia. J. Thromb. Haemost., 9(11), 2302–2310. CrossRef Scholar google search
van Bladel E.R., Laarhoven A.G., van der Heijden L.B., Heitink-Polle K.M., Porcelijn L., van der Schoot C.E., de Haas M., Roest M., Vidarsson G., de Groot P.G., Bruin M.C.A. (2014) Functional platelet defects in children with severe chronic ITP as tested with 2 novel assays applicable for low platelet counts. Blood, 123(10), 1556–1563. CrossRef Scholar google search
Frelinger A.L. 3rd, Grace R.F., Gerrits A.J., Berny-Lang M.A., Brown T., Carmichael S.L., Neufeld E.J., Michelson A.D. (2015) Platelet function tests, independent of platelet count, are associated with bleeding severity in ITP. Blood, 126(7), 873–879. CrossRef Scholar google search
Middelburg R.A., Carbaat-Ham J.C., Hesam H., Ragusi M.A.A.D., Zwaginga J.J. (2016) Platelet function in adult ITP patients can be either increased or decreased, compared to healthy controls, and is associated with bleeding risk. Hematology, 21(9), 549–551. CrossRef Scholar google search
Frelinger A.L. 3rd, Grace R.F., Gerrits A.J., Carmichael S.L., Forde E.E., Michelson A.D. (2018) Platelet function in ITP, independent of platelet count, is consistent over time and is associated with both current and subsequent bleeding severity. Thromb. Haemost., 118(1), 143–151. CrossRef Scholar google search
Panzer S., Höcker L., Rieger M., Vormittag R., Koren D., Dunkler D., Pabinger I. (2007) Agonist-inducible platelet activation in chronic idiopathic autoimmune thrombocytopenia. Eur. J. Haematol., 79(3), 198–204. CrossRef Scholar google search
Connor D.E., Ma D.D.F., Joseph J.E. (2013) Flow cytometry demonstrates differences in platelet reactivity and microparticle formation in subjects with thrombocytopenia or thrombocytosis due to primary haematological disorders. Thromb. Res., 132(5), 572–577. CrossRef Scholar google search
Nishiura N., Kashiwagi H., Akuta K., Hayashi S., Kato H., Kanakura Y., Tomiyama Y. (2020) Reevaluation of platelet function in chronic immune thrombocytopenia: impacts of platelet size, platelet-associated anti-αIIbβ3 antibodies and thrombopoietin receptor agonist. Br. J. Haematol., 189(4), 760–771. CrossRef Scholar google search
Ignatova A.A., Suntsova E.V., Pshonkin A.V., Martyanov A.A., Ponomarenko E.A., Polokhov D.M., Fedorova D.V., Voronin K.A., Kotskaya N.N., Trubina N.M., Krasilnikova M.V., Uzueva S.Sh., Serkova I.V., Ovsyannikova G.S., Romanova K.I., Hachatryan L.A., Kalinina I.I., Matveev V.E., Korsantiya M.N., Smetanina N.S., Evseev D.A., Sadovskaya M.N., Antonova K.S., Khoreva A.L., Zharkov P.A., Shcherbina A., Sveshnikova A.N., Maschan A.A., Novichkova G.A., Panteleev M.A. (2021) Platelet function and bleeding at different phases of childhood immune thrombocytopenia. Sci. Rep., 11, 9401. CrossRef Scholar google search
Skipper M.T., Rubak P., Stentoft J., Hvas A.-M., Larsen O.H. (2018) Evaluation of platelet function in thrombocytopenia. Platelets, 29(3), 270–276. CrossRef Scholar google search
Psaila B., Bussel J.B., Linden M.D., Babula B., Li Y., Barnard M.R., Tate C., Mathur K., Frelinger A.L., Michelson A.D. (2012) In vivo effects of eltrombopag on platelet function in immune thrombocytopenia: no evidence of platelet activation. Blood, 119(17), 4066–4072. CrossRef Scholar google search
Panzer S., Rieger M., Vormittag R., Eichelberger B., Dunkler D., Pabinger I. (2007) Platelet function to estimate the bleeding risk in autoimmune thrombocytopenia. Eur. J. Clin. Invest., 37(10), 814–819. CrossRef Scholar google search
Bowles K.M., Cooke L.J., Richards E.M., Baglin T.P. (2005) Platelet size has diagnostic predictive value in patients with thrombocytopenia. Clin. Lab. Haematol., 27(6), 370–373. CrossRef Scholar google search
Kaito K., Otsubo H., Usui N., Yoshida M., Tanno J., Kurihara E., Matsumoto K., Hirata R., Domitsu K., Kobayashi M. (2005) Platelet size deviation width, platelet large cell ration, and mean platelet volume have sufficient sensitivity and specificity in the diagnosis of immune thrombocytopenia. Br. J. Haematol., 128(5), 698–702. CrossRef Scholar google search
Borkataky S., Jain R., Gupta R., Singh S., Krishan G., Gupta K., Kudesia M. (2009) Role of platelet volume indices in the differential diagnosis of thrombocytopenia: a simple and inexpensive method. Hematology, 14(3), 182–186. CrossRef Scholar google search
Khaspekova S.G., Shustova O.N., Golubeva N.V., Vasiliev S.A., Mazurov A.V. (2015) Relationships of mean platelet volume and plasma thrombopoietin with glycocalicin levels in thrombocytopenic patients. Acta Haematol., 133(3), 295–299. CrossRef Scholar google search
Kienast J., Schmitz G. (1990) Flow cytometric analysis of thiazole orange uptake by platelets: a diagnostic aid in the evaluation of thrombocytopenic disorders. Blood, 75(1), 116-121. CrossRef Scholar google search
Ault K.A., Rinder H.M., Mitchell J., Carmody M.B., Vary C.P., Hillman R.S. (1992) The significance of platelets with increased RNA content (reticulated platelets). A measure of the rate of thrombopoiesis. Am. J. Clin. Pathol., 98(6), 637–646. CrossRef Scholar google search
Kurata Y., Hayashi S., Kiyoi T., Kosugi S., Kashiwagi H., Honda S., Tomiyama Y. (2001) Diagnostic value of tests for reticulated platelets, plasma glycocalicin, and thrombopoietin levels for discriminating between hyperdestructive and hypoplastic thrombocytopenia. Am. J. Clin. Pathol., 115(5), 656–664. CrossRef Scholar google search
Abe Y., Wada H., Sakakura M., Nishioka J., Tomatsu H., Hamaguchi Y., Oguni S., Shiku H., Nobori T. (2005) Usefulness of fully automated measurement of reticulated platelets using whole blood. Clin. Appl. Thromb. Hemost., 11(3), 263–270. CrossRef Scholar google search
Bodrova V.V., Shustova O.N., Khaspekova S.G., Mazurov A.V. (2022) Platelet reticulated forms, size indexes and functional activity. Interactions in healthy volunteers. Platelets, 33(3), 398–403. CrossRef Scholar google search
Rodeghiero F., Michel M., Gernsheimer T., Ruggeri M., Blanchette V., Busse J.B., Cines D.B., Cooper N., Godeau B., Greinacher A., Imbach P., Khellaf M., Klaassen R.J., Kühne T., Liebman H., Mazzucconi M.G., Newland A., Pabinger I., Tosetto A., Stasi R. (2013) Standardization of bleeding assessment in immune thrombocytopenia: report from the International Working Group. Blood, 121(14), 2596–2606. CrossRef Scholar google search
Khaspekova S.G., Shustova O.N., Golubeva N.V., Naimushin Y.A., Larina L.E., Mazurov A.V. (2019) Circulating antiplatelet antibodies in pregnant women with immune thrombocytopenic purpura as predictors of thrombocytopenia in the newborns. Platelets, 30(8), 1008–1012. CrossRef Scholar google search
Bierling P., Bettaieb A., Fromont P., Favrin M., Duedari N. (1994) Anti-GMP140 (CD62) autoantibody in a patient with autoimmune thrombocytopenic purpura. Br. J. Haematol., 87(3), 631–633. CrossRef Scholar google search
Bodrova V.V., Shustova O.N., Khaspekova S.G., Mazurov A.V. (2023) Laboratory markers of platelet production and turnover. Biochemistry (Moscow), 88(Suppl. 1), S39–S51. CrossRef Scholar google search

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