Cell Derived Microparticles (MP) in Different Phases of Thrombotic Thrombocytopenic Purpura (TTP) and Effect of Exchange Plasmapheresis (EPP) on Their Profiles

BACKGROUND: Cell derived MPs are small membrane vesicles released during cell activation or apoptosis. They express an inside-out membrane, which exposes the negatively charged phospholipid layer outside, allowing clotting factors to be anchored and generate thrombin. Among various species of MPs, R...

Full description

Saved in:
Bibliographic Details
Published in:Blood 2018-11, Vol.132 (Supplement 1), p.3736-3736
Main Authors: Ali, Robert A, Paul, Yonette, McCauley, Robert Forestal, Yaniz, Miriam, Gonzalez, Martha Q., Horstman, Lawrence L., Jy, Wenche, Ahn, Yeon S.
Format: Article
Language:English
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:BACKGROUND: Cell derived MPs are small membrane vesicles released during cell activation or apoptosis. They express an inside-out membrane, which exposes the negatively charged phospholipid layer outside, allowing clotting factors to be anchored and generate thrombin. Among various species of MPs, RMP (red cell MPs), PMP (platelet MPs), LMP (leukocytes), EMP (endothelial cells) are of special interest. They play an important role in hemostasis, thromboses, and inflammation. MPs mirror early injury of parent cells and are sensitive early biomarkers of underlying disorders. TTP is a microangiopathy mediated by antibody-induced depletion of ADAMTS13, a von Willebrand factor-cleaving protease. Endothelial injury promotes platelet clumping and formation of platelet rich microthrombi in the microcirculation. Subsequent platelet sequestration leads to impaired microcirculation, thrombocytopenia and red cell fragmentation with a microangiopathic hemolytic anemia. Exchange plasmapheresis (EPP) is the standard therapy. It removes antibodies to ADAMTS13, replacing it with ADAMTS13 rich plasma. It is possible that EPP removes thrombogenic MPs to improve the clinical course of TTP. In this study, we investigated MP profiles in active and remission phase of TTP and the effect of EPP on MP profiles. We also aimed to determine if MP profiles may be a useful measure for monitoring clinical course and tracking progress of therapy. METHODS: A retrospective study was conducted evaluating MP assays in patients with TTP. MP profiles were reviewed in acute and remission phases of TTP. Acute phase was defined as thrombocytopenia, clinical evidence of microangiopathy and hemolytic anemia and low ADAMTS13 activity. Remission was defined as sustained normalization of laboratory parameters and no further microangiopathy for at least one month. Patients were studied longitudinally, with MP assays before and after EPP. EMP were measured by CD31+/CD42b− (EMP31), CD62E+ (EMP62); PMP by CD31+/CD42b+ (PMP42) and CD41+ (PMP41). All were measured in platelet-poor plasma by flow cytometry. All MP data are presented in units of x105/µL. The differences in MP patterns among TTP patients in active and remission phases of disease, as well as the effect of EPP on MP profiles were assessed. RESULTS: Among 20 patients with TTP, 8 (40%) were in acute phase and 12 (60%) in remission. An average of 10.7 EPP were performed. The average platelet count prior to EPP was 50.6x103/µL, which increased to 248
ISSN:0006-4971
1528-0020
DOI:10.1182/blood-2018-99-115651