1.
Biological stratification of clinical disease courses in childhood immune thrombocytopenia
Schmidt DE, Heitink-Pollé KMJ, Mertens B, Porcelijn L, Kapur R, van der Schoot CE, Vidarsson G, van der Bom JG, Bruin MCA, de Haas M
Journal of thrombosis and haemostasis : JTH. 2021
Abstract
BACKGROUND In childhood immune thrombocytopenia (ITP), an autoimmune bleeding disorder, there is a need for better prediction of individual disease courses and treatment outcomes. OBJECTIVE To predict the response to intravenous Immunoglobulins (IVIg) and ITP disease course using genetic and immune markers. METHODS Children aged below seven years with newly diagnosed ITP (N = 147) from the TIKI study were included, which randomized children to an IVIg or observation group. A total of 46 variables were available: clinical characteristics, targeted genotyping, lymphocyte immune phenotyping, and platelet autoantibodies. RESULTS In the treatment arm, 48/80 children (60%) showed a complete response (platelets ≥100 x 10(9) /L) that lasted for at least one month (complete sustained response; CSR) and 32 exhibited no or a temporary response (absence of a sustained response; ASR). For a biological risk score, five variables were selected by regularized logistic regression that predicted ASR vs CSR: 1) hemoglobin; 2) platelet count; 3) genetic polymorphisms of FcγRIIc; 4) the presence of IgG anti-platelet antibodies; and 5) preceding vaccination. The ASR sensitivity was 0.91 (95% CI, 0.80 - 1.00) and specificity was 0.67 (95% CI, 0.53 - 0.80). In the 67 patients of the observation arm, this biological score was also associated with recovery during one-year follow-up. The addition of the biological score to a predefined clinical score further improved the discrimination of favorable ITP disease courses. CONCLUSIONS The prediction of disease courses and IVIg treatment responses in ITP is improved by using both clinical and biological stratification.
2.
Anti-Platelet Antibodies in Childhood Immune Thrombocytopenia: Prevalence and Prognostic Implications
Schmidt DE, Heitink-Polle KMJ, Porcelijn L, van der Schoot CE, Vidarsson G, Bruin MCA, de Haas M
Journal of thrombosis and haemostasis : JTH. 2020
Abstract
BACKGROUND Anti-platelet antibody testing may be useful for the diagnosis and management of childhood immune thrombocytopenia (ITP). OBJECTIVES Here we aimed to assess the prevalence and prognostic significance of anti-platelet glycoprotein-specific IgM and IgG antibodies. METHODS Children with newly diagnosed ITP were included at diagnosis and randomized to an intravenous immunoglobulins (IVIg) or careful observation group (TIKI trial). In this well-defined and longitudinally followed cohort (N = 179), anti-platelet glycoprotein-specific IgM and IgG antibodies were determined by MAIPA. RESULTS The dominant circulating anti-platelet antibody class in childhood ITP was IgM (62% of patients); but IgG antibodies were also found (10%). Children without IgM platelet antibodies were older and more often female. There was weak evidence for an association between IgM anti-GP IIb/IIIa antibodies and an increased bleeding severity (P=0.03). The IgM and IgG anti-platelet responses partially overlapped, and reactivity was frequently directed against multiple glycoproteins. During one year follow-up, children with IgM antibodies in the observation group displayed a faster platelet recovery compared to children without IgM, also after adjustment for age and preceding infections (P=7.1x10(-5) ). The small group of patients with detectable IgG anti-platelet antibodies exhibited an almost complete response to IVIg treatment (N=12; P=0.02), suggesting that IVIg was particularly efficacious in these children. CONCLUSIONS Testing for circulating anti-platelet antibodies may be helpful for the clinical prognostication and the guidance of treatment decisions in newly diagnosed childhood ITP. Our data suggest that the development of even more sensitive tests may further improve the clinical value of antibody testing.
3.
Intravenous immunoglobulin versus observation in childhood immune thrombocytopenia: a randomized controlled trial
Heitink-Polle KMJ, Uiterwaal CSPM, Porcelijn L, Tamminga RYJ, Smiers FJ, van Woerden NL, Wesseling J, Vidarsson G, Laarhoven AG, de Haas M, et al
Blood. 2018;132((9):):883-891
Abstract
Management of children with newly diagnosed immune thrombocytopenia (ITP) consists of careful observation or immunomodulatory treatment. Observational studies suggest a lower risk of chronic ITP in children after intravenous immunoglobulin (IVIg) treatment. In this multicenter randomized trial, children aged 3 months-16 years with newly diagnosed ITP, platelet counts ≤20 x 10(9)/L and mild to moderate bleeding were randomly assigned to receive either a single infusion of 0.8 g/kg IVIg or careful observation. Primary outcome was development of chronic ITP, at time of study initiation defined as a platelet count < 150 x 10(9)/L after 6 months. Two hundred and six children were allocated to receive IVIg (n=102) or careful observation (n=104). Chronic ITP occurred in 18.6% in the IVIg group and in 28.9% in the observation group (relative risk [RR] 0.64; 95% confidence interval [CI] 0.38-1.08). Platelet counts < 100 x 10(9)/L at 12 months (current definition of chronic ITP) were observed in 10% children in the IVIg group and in 12% in the observation group (RR 0.83; 95% CI 0.38-1.84). Complete response rates in the first three months were significantly higher in the IVIg group. IgG- Fc receptor IIb genetic variations were associated with early complete response in both groups. Grade 4-5 bleeding occurred in 9% in the observation group versus 1% in the IVIg group. IVIg treatment at diagnosis in children with ITP did not result in a lower rate of chronic ITP. In the IVIg group higher early complete response rates and less bleeding events were observed. This trial was registered at www.trialregister.nl as NTR 1563.
4.
Quality of life in children with acute immune thrombocytopenia is related to the course of the disease and not to treatment modality or bleeding tendency
Heitink-Polle KMJ, Haverman L, Annink KV, de Haas M, Bruin MCA
Blood. 2012;120((21):): Abstract No. 1098.