Evaluation of the immature platelet fraction in the diagnosis and prognosis of childhood immune thrombocytopenia

Rapid assessment of platelet production would distinguish between thrombocytopenia due to decreased platelet production or increased peripheral platelet destruction. We evaluated the value of immature platelet fraction (IPF) in differentiating immune thrombocytopenia (ITP) from thrombocytopenia secondary to bone marrow failure and its potential use as a prognostic marker. Forty-one young patients with ITP were compared with 14 patients with hematological malignancies under chemotherapy, representing a control group with thrombocytopenia due to bone marrow suppression and 30 age- and sex-matched healthy controls. Patients were studied stressing on bleeding manifestations, organomegaly/lymphadenopathy and therapy. Complete blood count including IPF was performed using Sysmex XE-2100. ITP patients were classified into two subgroups: acute ITP with spontaneous resolution within 3 months from diagnosis and chronic ITP that lasted ≥1 year from diagnosis. Median IPF was 11.8% in patients with ITP, 7% in those with hematological malignancy and 3% in the control group (p?<?0.001). ITP patients had significantly higher mean platelet volume (MPV), platelet distribution width (PDW), platelet large cell ratio (P-LCR) and IPF compared with patients with malignancy or healthy controls, while plateletcrit (PCT) was significantly lower in ITP patients than other groups (p?<?0.001). IPF was increased in patients with chronic ITP compared with acute ITP group (p?<?0.001). Patients with active ITP had the highest IPF followed by those in partial remission, while ITP patients in remission had the lowest IPF. IPF was positively correlated to the number of lines of treatment used, MPV, PDW and P-LCR, while negatively correlated to platelet count and PCT among ITP patients (p?<?0.001). Multiple regression analysis showed that platelet count and P-LCR were independently related to IPF. ROC curve analysis revealed that the cut-off value of IPF at 9.4% could be diagnostic for ITP patients with a sensitivity of 88% and a specificity of 85.7%. We suggest that IPF may be a rapid and inexpensive automated marker for etiology of thrombocytopenia and can be integrated as a standard parameter to evaluate the thrombopoietic state of the bone marrow. It may be considered as a potential prognostic marker for the development of chronic ITP.     

Beyond the platelet count: immature platelet fraction and thromboelastometry correlate with bleeding in patients with immune thrombocytopenia

Platelet counts (PC) estimate bleeding risk in Immune Thrombocytopenia (ITP). We investigated whether measures of thromboelastometry and absolute immature platelet fraction (A‐IPF) would correlate better with acute bleeding score (ABS) than PC or mean platelet volume (MPV). Simultaneous determination of ABS, complete blood count and thromboelastometry was performed in 141 ITP patients; 112 underwent A‐IPF testing. Subgroup analyses were performed for paediatric subjects, PC <60 × 10⁹/l and <30 × 10⁹/l. PC significantly inversely correlated with ABS in all subjects, PC <30 × 10⁹/l and total paediatric cohort. MPV did not correlate with ABS in any subgroup. Thromboelastometry measures of clot firmness, but not PC, significantly correlated with ABS in all subjects with PC <60 × 10⁹/l, and children with PC <60 × 10⁹/l and <30 × 10⁹/l. A‐IPF demonstrated stronger correlation with ABS than did PC among all subjects, those with PC <60 × 10⁹/l, all children and children with PC <30 × 10⁹/l (r = ?0·37; r = ?0·34; r = ?0·44; r = ?0·60) versus ABS with PC (r = ?0·36; ns; r = ?0·32; ns). Stronger correlations of both thromboelastometry measures of clot firmness and A‐IPF than PC with ABS suggest factors beyond PC, i.e. related to platelet function, contribute to ITP bleeding pathophysiology. Thromboelastometry, A‐IPF and ABS can be incorporated into routine or acute visits.     

Correlation between immature platelet fraction and reticulated platelets. Usefulness in the etiology diagnosis of thrombocytopenia

Background: Reticulated platelets (RP) are a surrogate marker for megakaryocytic activity, but the limitation of this determination is the lack of standardization of methodology. The determination of the immature platelet fraction (IPF) is performed in a simple, automated, and reproducible way between laboratories. We analyzed the correlation between IPF and RP, and usefulness of IPF in patients with thrombocytopenia. Methods: RP were determined by flow cytometry using double staining with thiazole orange and CD61 PerCP^®. IPF was performed with Sysmex XE2100 analyzer. We used a control group with normal platelets, and thrombocytopenic patients were classified into three groups: Group 1. Central thrombocytopenia, Group 2. Thrombocytopenia as a result of enhanced peripheral platelet destruction, and Group 3. Peripheral non‐immune thrombocytopenia by abnormal distribution. Results: Fourteen controls and 66 patients were analyzed. Group 1: 25 patients, they had mean and confidence interval 95% (95% CI) for IPF 8.67% (6.49–10.46%) and RP 4.08% (2.86–5.30%). Group 2: 20 patients, they had mean and 95%CI for IPF 16.80% (12.20–21.39%) and RP 16.14% (9.89–22.40%). Group 3: 21 patients, they had mean and 95% CI for IPF 9.04% (6.95–11.14%) and RP 5.23% (3.41–7.05%). The overall Pearson linear correlation between IPF and RP was r: 0.65. There were statistically significant differences in values of IPF and RP between Group 2 and the other two groups (P < 0.01). Conclusion: There is a good correlation between IPF and RP mainly in thrombocytopenia by peripheral destruction. Determination of IPF is an easy technique in their implementation, standardized and reproducible, so it could be a useful screening technique in patients with thrombocytopenia.     

Haematological characteristics of MYH9 disorders due to MYH9 R702 mutations

Objective: MYH9 disorders are characterised by giant platelets, thrombocytopenia, and Döhle body‐like cytoplasmic granulocyte inclusion bodies that result from mutations in MYH9, the gene for non‐muscle myosin heavy chain‐IIA (NMMHC‐IIA). MYH9 R702 mutations are highly associated with Alport manifestations and result in Epstein syndrome. The aim of our study was to determine the haematological characteristics of MYH9 disorders as a result of R702 mutations to aid in making a proper diagnosis. Patients and methods: Platelet size of patients with MYH9 disorders was determined as platelet diameter by microscopic observation of 200 platelets on stained peripheral blood smears. Double in situ hybridisation using a biotinylated oligo(dT) probe and immunofluorescence analysis of neutrophil NMMHC‐IIA was performed on peripheral blood smears. Results: Patients carrying R702 mutations had significantly larger platelets than those with other MYH9 mutations. Although granulocyte inclusion bodies were mostly invisible on stained blood smears, immunofluorescence analysis for NMMHC‐IIA showed an abnormal type II localisation in all neutrophils. We first showed that poly(A)+ RNA coincided with accumulated NMMHC‐IIA at inclusion bodies in patients with MYH9 disorders. However, no condensation of poly(A)+ RNA at inclusion bodies was observed in patients with R702 mutations. Conclusion: Our study shows that R702 mutations result in especially large platelets and inclusion bodies being faint and mostly invisible on conventionally stained blood smears. We further demonstrated that poly(A)+ RNA content but not NMMHC‐IIA accumulation is responsible for the morphological appearance/stainability of inclusion bodies on stained blood smears and the amount of poly(A)+ RNA is decreased in those with R702 mutations.     

Determinants of platelet count in pediatric patients with congenital cyanotic heart disease: Role of immature platelet fraction

Objectives

Congenital heart defects are common noninfectious causes of mortality in children. Bleeding and thrombosis are both limiting factors in the management of such patients. We assessed the frequency of thrombocytopenia in pediatric patients with congenital cyanotic heart disease (CCHD) and evaluated determinants of platelet count including immature platelet fraction (IPF) and their role in the pathogenesis of thrombocytopenia.

Methods

Forty‐six children and adolescents with CCHD during pre‐catheter visits were studied; median age was 20.5 months. Complete blood count including IPF as a marker of platelet production and reticulated hemoglobin content (RET‐He) as a marker of red cell production and iron status were done on Sysmex XE 2100 (Sysmex, Japan). C‐reactive protein, prothrombin time (PT), Activated partial thromboplastin time (APTT) were also assessed.

Results

Thrombocytopenia was found in 6 patients (13%). PT was prolonged (P = .016) and IPF was significantly higher in patients with thrombocytopenia compared with patients with normal platelet count (14.15 ± 5.2% vs 6.68 ± 3.39%; P = .003). Platelet count was negatively correlated with IPF while significant positive correlations were found between IPF and hemoglobin, red blood cells (RBCs) count, hematocrit (Hct), PT, reticulocytes count, and immature reticulocyte fraction.

Conclusions

We suggest that elevated IPF in CCHD patients with thrombocytopenia may denote peripheral platelets destruction as an underlying mechanism. Hemoglobin level, RBCs count, Hct, and RET‐He were not significant determinants for platelet count in CCHD.     

Immature platelet fraction measurement is influenced by platelet size and is a useful parameter for discrimination of macrothrombocytopenia

Abstract

Background

Reticulated platelets (RPs) as measured using flow cytometry are useful parameters of thrombopoiesis; however, difficulties remain with standardization between laboratories. On the other hand, immature platelet fraction (IPF) measurement, as determined using an automated hematology analyzer, is simple, reproducible, and displays a good correlation with RP, although specific factors may affect its value. We previously noticed that a small proportion of patients exhibit extremely high IPF values that do not correlate with flow cytometrically measured RP.

Objectives

We investigated the mechanism of the aberrant increase in IPF values of different types of macrothrombocytopenia.

Patients/methods

IPF, RP, and other platelet indexes were analyzed using samples from 15 congenital macrothrombocytopenic patients from 12 families, 150 immune thrombocytopenic patients, and 27 normal individuals. We further monitored the change in IPF values and morphology during platelet agglutination.

Results

IPF values were about five times higher in MYH9 disorders (IPF 48.6 ± 1.9%) and about twice as high in other macrothrombocytopenias (IPF 18.4 ± 2.1%) than in immune thrombocytopenic patients with similar platelet counts (IPF 9.2 ± 0.3%). We then examined changes in IPF values during ethylenediaminetetraacetic acid- and macroglobulinemia-induced platelet agglutination. The IPF value significantly increased in a time-dependent manner along with the formation of platelet clumps and was strongly influenced by a few tiny platelet aggregates.

Conclusions

These results suggested that IPF values are influenced by platelet size. Furthermore, IPF could be a useful and convenient parameter for screening of macrothrombocytopenia, which presents with a disproportionately high IPF value.     

MYH9 related disease: A novel missense Ala95Asp mutation of the MYH9 gene

MYH9-related disease (MYH9-RD) is a rare autosomal dominant disorder caused by mutations in MYH9, the gene encoding the heavy chain of non-muscle myosin IIA. Patients present with congenital macrothrombocytopenia and inclusion bodies in neutrophils and might develop sensorineural deafness, presenile cataract, and/or progressive nephritis leading to end-stage renal failure. In a family with eight individuals suffering from macrothrombocytopenia and hearing impairment we identified a novel c.Ala95Asp mutation. Affecting the motor domain of the protein, the mutation is likely to be associated with a severe phenotype. Therefore, this family should be carefully monitored to follow-up the renal status even though the affected members do not seem to be at risk of early kidney disease.     

First description of somatic mosaicism in MYH9 disorders

MYH9 disorders are characterized by giant platelets, thrombocytopenia, and Dohle body-like cytoplasmic granulocyte inclusion bodies that result from mutations in MYH9, which encodes non-muscle myosin heavy chain-A (NMMHCA). These disorders are known to be transmitted in an autosomal dominant manner, although about 20% of cases are considered to be sporadic. We report here the first case of a MYH9 disorder because of somatic mosaicism. The patient was the father of a male with typical May-Hegglin anomaly. The father had normal platelet counts, however, both normal-sized and giant platelets were observed on his peripheral blood smears. In addition, 14% of neutrophils contained inclusion bodies and the rest showed a normal morphology. Quantitative fluorescent polymerase chain reaction analysis showed that only 6% of DNA from peripheral blood leucocytes harboured the mutation. The mosaicism was demonstrated at a similar rate in different tissues, buccal mucosa cells and hair bulb cells, implying that the mutation had occurred before gastrulation. Mosaicism might account for some de novo mutations in MYH9 disorders.     

Identification of three in‐frame deletion mutations in MYH9 disorders suggesting an important hot spot for small rearrangements in MYH9 exon 24

MYH9 disorders include hereditary macrothrombocytopenias with leukocyte inclusion bodies. Among more than 200 genetically confirmed families, the vast majority of cases exhibit single point mutations including substitutions and deletions of the COOH‐terminus in the protein‐coding sequence of MYH9. Only four in‐frame deletions have been reported to date. In the current study, we describe three in‐frame deletions including p.E1084del, p.E1066_A1072del and p.G1055_Q1068del, all of which are localized to exon 24. Interestingly, these three deletions were found to induce the diverse clinical manifestations on the non‐hematological symptoms, while they equally demonstrated type I staining of inclusion bodies. As a result of these findings, we suggest that exon 24 represents a potential ‘hot spot’ for unequal homologous recombination, which may generate in‐frame deletions in the coiled‐coil rod of non‐muscle myosin heavy chain‐IIA. The exact length and position of these deletions may also determine the severity of the non‐hematological manifestations, however does not appear to affect the morphology of the leukocyte inclusion bodies. These findings further our current understanding of the molecular pathogenesis underlying MYH9 disorders.     

Immature platelet fraction related parameters in the differential diagnosis of thrombocytopenia

Abstract

The pathogenesis of thrombocytopenia can be divided into increased destruction (ID) of platelets in the peripheral blood and decreased production (DP) of platelets in the bone marrow. This study aimed to analyze the efficacy of immature platelet fraction (IPF) related parameters, including the IPF count (IPF#), IPF percentage (IPF%) and highly fluorescence IPF percentage (H-IPF%), measured by XN-9000, in the differential diagnosis of thrombocytopenia. One hundred and twenty healthy volunteers were enrolled in the healthy control (HC) group, and 180 thrombocytopenia patients were grouped into either the increased destruction (ID) group or the decreased production (DP) group according to their final diagnosis. IPF# was significantly lower in the DP group than in the ID and HC groups (P < .01). Among the three groups, the ID group had the highest IPF% and H-IPF%, and the HC group had the lowest IPF% and H-IPF%. The differences between the three groups were all statistically significant (P < .01). In differentiating the ID patients from the DP patients, the areas under the operating characteristics curve of IPF#, IPF% and H-IPF% were 0.859, 0.944 and 0.930, respectively. False positive rates were below 0.04 when IPF#, IPF% and H-IPF% were above 2.65, 7.55 and 2.35, respectively. IPF related parameters showed high efficacy in the differential diagnosis of thrombocytopenia. However, due to the small numerical values of the IPF related parameters in some thrombocytopenia patients, the fluctuations of IPF% and H-IPF% should also be taken into consideration. Though H-IPF% is a new parameter, its effectiveness in the differential diagnosis of thrombocytopenia is not better than IPF%’s.     

Assessment of an immature platelet fraction (IPF) in peripheral thrombocytopenia

A new automated method to reliably quantify reticulated platelets, expressed as the immature platelet fraction (IPF), has been developed utilizing the XE-2100 blood cell counter with upgraded software (Sysmex, Kobe, Japan). The IPF is identified by flow cytometry techniques and the use of a nucleic acid specific dye in the reticulocyte/optical platelet channel. The clinical utility of this parameter was established in the laboratory diagnosis of thrombocytopenia due to increased peripheral platelet destruction, particularly autoimmune thrombocytopenic purpura (AITP) and thrombotic thrombocytopenic purpura (TTP). Reproducibility and stability results over 48 h were good. An IPF reference range in healthy individuals was established as 1.1-6.1%, with a mean of 3.4%. Patients in whom platelet destruction might be abnormal, were studied and two of these patients followed serially during the course of treatment. The IPF was raised in several disease states. The most significant increases in IPF values were found in patients with AITP (mean 22.3%, range 9.2-33.1%) and acute TTP (mean 17.2%, range 11.2-30.9%). Following patients during treatment demonstrated that as the platelet count recovered the IPF% fell. These results show that a rapid, inexpensive automated method for measuring the IPF% is feasible and should become a standard parameter in evaluating the thrombocytopenic patient.     

Immunocytochemistry for the heavy chain of the non-muscle myosin IIA as a diagnostic tool for MYH9-related disorders

Summary. May–Hegglin anomaly (MHA), Sebastian syndrome (SBS) and Fechtner syndrome (FTNS) are autosomal‐dominant macrothrombocytopenias with Döhle‐like leucocyte inclusions. These diseases are due to mutations of the MHY9 gene, encoding the heavy chain of non‐muscle myosin IIA (NMMHC‐A). We investigated the NMMHC‐A localization in blood cells from eight MHA, SBS or FTNS patients with known MYH9 mutations. All the patients showed an altered localization of NMMHC‐A in granulocytes and platelets, suggesting that Döhle‐like bodies are due to the aggregation of NMMHC‐A in the cytoplasm. Therefore, immunocytochemistry for NMMHC‐A is a simple and sensitive method to detect pathological phenotypes of granulocytes and platelets in the diagnosis of MYH9‐related disorders.     

High-resolution melting analysis for detection of MYH9 mutations

May-Hegglin anomaly (MHA), Sebastian (SBS), Fechtner (FTNS) and Epstein (EPS) syndromes are rare autosomal dominant disorders with giant platelets and thrombocytopenia. Other manifestations of these disorders are combinations of the presence of granulocyte inclusions and deafness, cataracts and renal failure. Currently, MHA, SBS, FTNS and EPS are considered to be distinct clinical manifestation of a single illness caused by mutations of the MYH9 gene encoding the heavy chain of non-muscle myosin IIA (NMMHC-IIA). As the MYH9 gene has a high number of exons, it takes much time and material to use this method for the detection of MYH9 mutations. Recently, a new method has been introduced for scanning DNA mutations without the need for direct sequencing: high-resolution melting analysis (HRMA). Mutation detection with HRMA relies on the intercalation of the specific dye (LC Green plus) in double-strand DNA and fluorescence monitoring of PCR product melting profiles. In our study, we optimized the conditions and used HRMA for rapid screening of mutations in all MYH9 exons in seven affected individuals from four unrelated families with suspected MYH9 disorders. Samples identified by HRMA as positive for the mutation were analysed by direct sequencing. HRMA saved us over 85% of redundant sequencing.