Periodic acid-Schiff (PAS) staining of immature platelets in donors

Glycogen in platelets (PLTs) on smears of peripheral blood of 40 donors was investigated by the periodic acid-Schiff (PAS) method. Three groups were formed. Group 1 was consisted of 21 men undergoing the donor selection procedure. Additionally, 9 first-time donors undergoing plateletpheresis (Group 2) and 10 donors who frequently underwent platelet apheresis (Group 3) were studied as a model of relative thrombocytopenia. Cell sizes were measured with the use of a Image Analyzer "ASPBC" (Russia). The training procedure and classification of PAS-blood PLTs were made on the basis of expert evaluation. In this article, we have established three facts. First, the PAS-positive PLT area was larger than that of the PAS-negative cells (9.5?±?3.6?sq.mkm vs. 3.9?±?1.3?sq.mkm, p?相似文献   

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.     

Detection and quantification of circulating immature platelets: agreement between flow cytometric and automated detection

Immature platelets—also termed reticulated platelets (RP)—are platelets newly released into the circulation, and have been associated with a variety of pathological thrombotic events. They can be assessed by flow cytometry after staining with thiazole orange (TO) or by using a module added to a fully automated analyzer that is currently in wide clinical use and expressed as a fraction of the total platelet count (IPF). We sought to assess the correlation and agreement between these two methods. IPF was measured using Sysmex XE 2100—and at the same time point- we used TO staining and flow cytometry to measure RP levels. Two different gates were used for the flow cytometry method, 1 and 0.5 %. Measurements from the automated analyzer were then compared separately to measurements performed using each gate. Agreement between methods was assessed using Bland–Altman method. Pearson’s correlation coefficient was also calculated. 129 subjects were enrolled and stratified into 5 groups: (1) Healthy subjects, (2) End stage renal disease, (3) Chronic stable coronary artery disease, (4) Post Coronary artery bypass surgery, (5) Peripheral thrombocytopenia. Median IPF levels were increased for patients in groups 2, 3, 4 and 5 (4.0, 4.7, 4.3, and 8.3 % respectively) compared to healthy subjects (2.5 %) p = 0.0001. Although the observed correlation between the two methods tended to be good in patients with high IPF values (i.e., group 5), the overall observed correlation was poor (Pearson’s correlation coefficient r = 0.27). Furthermore, there was poor agreement between the two methods in all groups. Despite the good correlation that was observed between the two methods at higher IPF values, the lack of agreement was significant.     

Measurements of immature platelets with haematology analysers are of limited value to separate immune thrombocytopenia from bone marrow failure

Detection of immature platelets in the circulation may help to dissect thrombocytopenia due to platelet destruction from bone marrow failure (BMF ). We prospectively tested the predictive value of immature platelets, measured as immature platelet fraction (IPF ) on the XE‐5000 (Sysmex, Kobe, Japan) or percentage of reticulated platelets (rPT ) on the CD Sapphire (Abbott Diagnostics, Santa Clara, CA, USA) to separate immune thrombocytopenia (ITP ) from BMF (leukaemia, myelodysplastic syndrome, aplastic anaemia). We analysed 58 samples of patients with BMF , 47 samples of patients with ITP and 97 controls. Median rPT (CD Sapphire) was increased to 9·0% in ITP and to 10·9% in BMF , compared to 1·9% in controls. Median IPF (XE‐5000) was 16·2% in ITP , 10·2% in BMF and 2·5% in controls. We found an inverse correlation between high fractions of immature platelets and low platelet counts in thrombocytopenic samples regardless of the diagnosis. In conclusion, we observed a broad overlap of immature platelets between ITP and BMF , which may be caused by an accelerated release of immature platelets in any thrombocytopenic state and decreased production in many patients with ITP . Despite this, IPF (XE‐5000) had some power to discriminate ITP from BMF , whereas rPT (CD Sapphire) was of no predictive value.     

Measurement of reticulated platelets by simple flow cytometry: An indirect thrombocytopoietic marker

BACKGROUND: The aim of this study was to determine whether measurement of reticulated platelets (RP) by flow cytometry directly from whole blood, with no fixation or manipulation, is as useful a thrombocytopoietic marker as other more complex techniques. METHODS: RP percentage was prospectively assessed in thrombocytopenic patients (platelets <100x10(9)/L) and non-thrombocytopenic controls using a direct, whole-blood, dual-labelling flow cytometric method. Direct, whole-blood double coverage was achieved using a monoclonal antiglycoprotein (GP)-III antibody (CD61-PerCP(R)) for platelet identification and thiazol orange (Retic-count(R)) as platelet mARN stain. After establishing thrombocytopenia etiology, patients were grouped according to whether their rate of thrombopoiesis was increased or decreased. RESULTS: RP were measured in 53 thrombocytopenic patients with several etiologies and in 53 non-thrombocytopenic controls. The mean RP in 14 thrombocytopenic patients with no increased thrombopoietic activity was 4.8% (95% CI: 3.2-6.4) and the RP absolute number was 1.98x10(9)/L (95% CI: 1.3-2.6). The mean RP in 17 thrombocytopenic patients with increased thrombopoietic activity was 29.4% (95% CI: 24.7-34.1) and the RP absolute number was 7.24x10(9)/L (95% CI: 4.9-9.5). CONCLUSIONS: RP measurement by flow cytometry, directly from whole blood without manipulation, is a useful screening test to differentiate thrombocytopenia with high or low thrombopoietic activity.     

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.     

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 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.     

Complement activation on platelets correlates with a decrease in circulating immature platelets in patients with immune thrombocytopenic purpura

The role of the complement system in immune thrombocytopenic purpura (ITP) is not well defined. We examined plasma from 79 patients with ITP, 50 healthy volunteers, and 25 patients with non‐immune mediated thrombocytopenia, to investigate their complement activation/fixation capacity (CAC) on immobilized heterologous platelets. Enhanced CAC was found in 46 plasma samples (59%) from patients with ITP, but no samples from patients with non‐immune mediated thrombocytopenia. Plasma from healthy volunteers was used for comparison. In patients with ITP, an enhanced plasma CAC was associated with a decreased circulating absolute immature platelet fraction (A‐IPF) (<15 × 10⁹/l) (P = 0·027) and thrombocytopenia (platelet count < 100 × 10⁹/l) (P = 0·024). The positive predictive value of an enhanced CAC for a low A‐IPF was 93%, with a specificity of 77%. The specificity and positive predictive values increased to 100% when plasma CAC was defined strictly by enhanced C1q and/or C4d deposition on test platelets. Although no statistically significant correlation emerged between CAC and response to different pharmacological therapies, an enhanced response to splenectomy was noted (P < 0·063). Thus, complement fixation may contribute to the thrombocytopenia of ITP by enhancing clearance of opsonized platelets from the circulation, and/or directly damaging platelets and megakaryocytes.     

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.     

Chronic thrombocytopenia of childhood: use of non-invasive methods in clinical evaluation

OBJECTIVES: An unselected group of 21 children with chronic thrombocytopenia was investigated to understand the patients' platelet abnormality better. METHODS: Platelet counts, mean platelet volumes (MPV), membrane glycoproteins and Fcgamma receptor type IIA (FcgammaRIIA) polymorphism H131R, reticulated platelets (% RP), antiplatelet antibodies and plasma thrombopoietin (TPO) were measured. RESULTS: Sixteen patients had idiopathic thrombocytopenic purpura (ITP) (group 1: platelets < 50 x 10(9)/L, n = 6; group 2: 50-99 x 10(9)/L, n = 4; group 3: 100-149 x 10(9)/L, n = 4; group 4: splenectomised patients with normal platelet counts, n = 2). Five patients had familial thrombocytopenia. Six healthy children were studied as a reference. In the 19 thrombocytopenic patients, the platelets were significantly larger and % RP and TPO levels were significantly higher than those in the controls. Increased megakaryocytosis at diagnosis was associated with larger MPV and higher % RP but not with platelet level or TPO. The % RP was remarkably high in all ITP patients of group 1 indicating a brisk production of platelets despite low peripheral count. In all patients with familial thrombocytopenia, TPO was increased suggesting that the syndrome was not because of defective TPO production. The distribution of FcgammaRIIA alleles in the patients was similar to that in the controls. CONCLUSIONS: A combined application of % RP and TPO could be helpful in classifying patients with chronic thrombocytopenia into different categories. The observations may be of value in the clinical evaluation of ITP patients and lead to avoidance of invasive examinations at least in some patients.     

Immature platelet fraction and high-on treatment platelet reactivity with ticagrelor in patients with acute coronary syndromes

Residual high-on treatment platelet reactivity (HRPR) has been associated with a 2–9 fold increased risk of acute ischemic events in patients with acute coronary syndromes or coronary stenting. However, the mechanism of suboptimal platelet inhibition are still poorly understood. Aim of present study was to evaluate the role of the percentage of reticulated platelets on HRPR with ticagrelor. In patients treated with ASA (100–160 mg) and ticagrelor (90 mg twice a day) platelet reactivity and the reticulated platelets fraction (immature platelets fraction, IPF) were assessed at 30–90 days after acute coronary syndrome. Aggregation was assessed by multiple-electrode aggregometry. HRPR was defined as ADP test >417 AU*min. Our population is represented by 190 patients, divided according to tertiles values of IPF (<2.5; 2.5–3.99; ≥4 %). Higher IPF was associated to a larger platelet volume and lower platelets count (p < 0.001), and inversely related with a history of previous coronary revascularization (p = 0.03). Twenty-one out of 190 (11.0 %) patients displayed HRPR. No difference in the levels of circulating IPF was found in patients with or without HRPR (p = 0.25), with no correlation between the rate of reticulated platelets and platelet reactivity at ADP test (r = ?0.084, p = 0.26). In fact no association was observed between high levels of IPF and the occurrence of HRPR (adjusted OR[95 % CI] = 0.69[0.34–1,37], p = 0.28), even after correction for baseline differences. In patients treated with ticagrelor, the levels of circulating reticulated platelets assessed at 30–90 days post-ACS are not associated with platelet reactivity or the occurrence of HRPR.     

Reticulated platelets as a marker of megakaryopoiesis in liver cirrhosis; relation to thrombopoietin and hepatocyte growth factor serum concentration

BACKGROUND/AIMS: Thrombocytopenia often accompanies chronic liver diseases. It can occur due to the decrease in blood platelet production by megakaryocytes, the increase in peripheral destruction, or splenic sequestration. METHODOLOGY: We estimate the reticulated platelets by use of flow cytometry in patients with liver cirrhosis with thrombocytopenia (n-24, platelets median (M)-77g/L), with normal platelet count (n-16, platelets M-193g/L) and in healthy (n-27, platelets M-242g/L). The level of reticulated platelets was determined in whole peripheral blood stained with thiazole orange and incubated with monoclonal antibodies anti-CD41. RESULTS: Patients with liver cirrhosis and thrombocytopenia revealed significantly lower reticulated platelet levels than patients without thrombocytopenia and healthy subjects (M-1.0% vs. 1.5% vs. 2.0% respectively). The correlation between reticulated platelet level and platelet count, serum level of thrombopoietin and hepatocyte growth factor in liver cirrhosis was not established. An inverse correlation was noted between reticulated platelets and thrombopoietin (r - 0.6, p<0.01) and hepatocyte growth factor (r - 0.5, p<0.01) in the control group. A positive correlation between platelet count in liver cirrhosis and serum level of thrombopoietin (r - 0.35, p<0.05) and hepatocyte growth factor (r - 0.48, p<0.01) was observed. CONCLUSIONS: Our studies showed that decreased production of platelets by megakaryocytes due to low thrombopoietin concentration could be a possible cause of thrombocytopenia in liver cirrhosis.     

Prognostic significance of reticulated platelet levels in diabetic patients with stable coronary artery disease

Abstract

Levels of reticulated platelets (RP) increase during high platelet turnover conditions, and have been shown to correlate with diabetes mellitus (DM) status. Little is known regarding the prognostic significance of levels of RP among patients with stable coronary artery disease (SCAD).

The study consisted of patients with SCAD and DM, who visited our cardiology outpatient clinic between June 2016 and February 2017. RP levels were measured at baseline as immature platelet fraction (IPF)%, using flow cytometry. Outcomes at 2 years consisted of bleeding events and major adverse cardiovascular events (MACE), which included death, myocardial infarction, cerebrovascular accident and urgent revascularization.

The study included 104 patients (mean age - 71.2 ± 9.5 years, 76.9% were male, and 83.7% had hypertension). IPF was significantly higher at baseline among patients who had suffered from a MACE (4.57% vs. 2.53%, p < .001), and lower in patients who had suffered from bleeding events, compared with those who had not (1.57% vs. 3.00%, p = .004). There were higher rates of MACE at higher IPF quartiles (p < .001, AUC-0.770), and higher rates of bleeding at the lowest quartiles (p = .007, AUC-0.781).

In SCAD patients with DM, levels of RP are associated with a higher risk of MACE, and inversely correlated with the risk of bleeding.     

Platelet production and platelet destruction: assessing mechanisms of treatment effect in immune thrombocytopenia

This study investigated the immature platelet fraction (IPF) in assessing treatment effects in immune thrombocytopenia (ITP). IPF was measured on the Sysmex XE2100 autoanalyzer. The mean absolute-IPF (A-IPF) was lower for ITP patients than for healthy controls (3.2 vs 7.8 × 10?/L, P < .01), whereas IPF percentage was greater (29.2% vs 3.2%, P < .01). All 5 patients with a platelet response to Eltrombopag, a thrombopoietic agent, but none responding to an anti-FcγRIII antibody, had corresponding A-IPF responses. Seven of 7 patients responding to RhoD immuneglobulin (anti-D) and 6 of 8 responding to intravenous immunoglobulin (IVIG) did not have corresponding increases in A-IPF, but 2 with IVIG and 1 with IVIG anti-D did. This supports inhibition of platelet destruction as the primary mechanism of intravenous anti-D and IVIG, although IVIG may also enhance thrombopoiesis. Plasma glycocalicin, released during platelet destruction, normalized as glycocalicin index, was higher in ITP patients than controls (31.36 vs 1.75, P = .001). There was an inverse correlation between glycocalicin index and A-IPF in ITP patients (r2 = -0.578, P = .015), demonstrating the relationship between platelet production and destruction. Nonresponders to thrombopoietic agents had increased megakaryocytes but not increased A-IPF, suggesting that antibodies blocked platelet release. In conclusion, A-IPF measures real-time thrombopoiesis, providing insight into mechanisms of treatment effect.     

Detection of reticulated platelets: estimating the degree of fluorescence of platelets stained with thiazole orange

The primary problem in the measurement of reticulated platelets (RP) stained with thiazole orange (TO) by flow cytometry is the definition of a threshold limit for fluorescence positivity. We evaluated settings for the threshold gate for TO positivity based on two principles: a fluorescence histogram (median FL1, Relative FL1) or a plot of forward light scatter (FSC; reflecting the distribution of the platelet size) versus fluorescence intensity (% RP). These methods were applied prospectively in examination of 54 healthy blood donors (16 females) and a total of 50 blinded patient samples: pregnant women with thrombocytopenia (Group 1A, n = 11), thrombocytopenic women after delivery (Group 1B, n = 9) and healthy women with a thrombocytopenic newborn (Group 2, n = 30). Group 1A displayed higher median FL1 (mean 306, CI 279-332) as compared to that of Group 2 (mean 266, CI 255-277; p = 0.0038) or to that of the female controls (mean 249, CI 231-268; p < 0.001). Relative FL1 was also higher in the patients of Group 1A than those of Group 2 (p = 0.037). When analysing the % RP, the difference between these groups was not significant. In the patients (n = 50), the median FSC (mean 407, SD 40, CI 395-418) was also higher than that of the controls (n = 54; mean 383, SD 25, CI 376-390; Mann-Whitney U-test, p = 0.0015). In Group 1A, a significant correlation was observed between the Patient median FL1 and Patient median FSC (r = 0.62, p = 0.043). When developing methods for the measurement of RP, it seems to be useful to analyse the data with more than one principle to define the threshold limit for TO positivity.     

Immature platelet fraction in hypertensive pregnancy

Background: Imbalance in hemostatic mechanisms can occur during pregnancy with a tendency for hypercoagulability and increased thrombosis risk. Pregnant women with hypertensive disorder, especially preeclampsia, show alterations in platelet indexes. Immature platelet fraction (IPF) has been suggested as a sensitive index for monitoring changes in platelet production and destruction. Objectives: To evaluate the IPF in patients diagnosed with a gestational hypertensive disorder (GHD). Patients and methods: A cross-sectional study was conducted at an University Hospital to estimate maternal blood IPF index in 99 pregnant women, divided into three groups: normotensive pregnancy (NP), preeclampsia syndrome (PES), and non-proteinuric hypertensive pregnancy (nPHP). Following ethical approval and written informed consent, samples were collected from 33 NP, 34 PES, and 32 nPHP women. Platelet indexes were measured by fluorescent flow cytometry. Results: IPF and mean platelet volume (MPV) counts in GHD were significantly higher than in NP (IPF: 3.8, 2.4–5.1%; 8.6, 5.8–10.6%; 7.3, 4.2–10.2%; p < 0.001 and MPV: 10.6 ± 0.9 fL; 12.1 ± 1.0 fL; 11.6 ± 1.0 fL; p < 0.001 for NP, PES, and nPHP, respectively). No difference was detected between PES and nPHP groups. The distribution of patients with an IPF above 6.1%for NP, PES, and nPHP was 9%, 65%, and 43.8%, respectively (p < 0.001). IPF as a test to differentiate GHD from the controls achieved an area under the curve of 0.83 on a receiver operating characteristics curve. Conclusion: A distinct profile in platelet indexes was detected in hypertensive pregnancies. It suggests that these markers could be used in daily routine as an additional tool in the management of pregnant women.     

Impact of immature platelet fraction on platelet reactivity during prasugrel maintenance treatment

Residual high on-treatment platelet reactivity (HTPR) despite dual antiplatelet therapy (DAPT) has emerged as a predictor of major ischemic events in patients undergoing percutaneous coronary interventions (PCIs), especially after an acute cardiovascular event. However, its determinants are still poorly defined. Therefore, the aim of the present study was to evaluate the role of the percentage of reticulated platelets on HTPR in patients on DAPT with ASA (100–160 mg) and prasugrel (10 mg).

Platelet reactivity and the reticulated platelets fraction (immature platelets fraction [IPF]) were assessed at 30–90 days after an acute coronary syndrome. Aggregation was assessed by multiple-electrode aggregometry. HTPR was defined as ADP test > 417 AU × min.

Our population is represented by 180 ACS patients undergoing stent implantation, divided according to median values of IPF (< or ≥ 2.8%). Higher IPF values were associated to lower platelet count (p < 0.001) and a higher rate of active smokers (p = 0.02). No difference was observed in terms of mean platelet reactivity, with different activating stimuli. The prevalence of HTPR on prasugrel did not significantly differ in patients with IPF < or ≥ 2.8% (8%vs. 11.8%, p = 0.46; adjusted OR [95% CI] = 1.89 [0.66–5.4], p = 0.24).

Our study showed that in patients treated with prasugrel after PCI for ACS, the immature platelet fraction influences neither platelet reactivity nor the rate of HTPR.     

Reticulated platelet determination: methodologies and applications for the evaluation of thrombocytopenic disorders

Reticulated platelets retain some residual mRNA in their cytoplasm and are thought to be newly produced platelets. In recent years, it has been reported that the reticulated platelet count (RP) correlates well with platelet production. For that reason, the measurement of RP (%) is considered useful for analyses of platelet kinetics and differential diagnoses of thrombocytopenic disorders. However, certain technical difficulties exist because fluorochrome thiazole orange (TO), which is used for staining purposes, stains platelet granules nonspecifically, and so far, only a few reports have documented the study of precision staining techniques. We evaluated staining criteria precisely in an effort to solve the issue of nonspecific staining by TO, and concluded that the important points for effective staining were (1) fixation of platelets, (2) 1:8 dilution of TO (ReticCount), (3) incubation for 1 to 2 hours, and (4) the capture of platelets using anti-CD42b monoclonal antibody. We stained reticulated platelet samples by the above method and achieved intra-assay reproducibility of 3.4-5.1% RP (%) in normal subjects was 8.7 +/- 2.2%. It was significantly higher (23.6 +/- 13.3%) in patients with idiopathic thrombocytopenic purpura (ITP), and elevated in 87% of all evaluated ITP patients. Our method is sensitive, provides reproducible results, and can be effectively utilized for the analysis of platelet kinetics and differential diagnosis of thrombocytopenia.     

The Platelet Destruction Site in Thrombocytopenic Purpuras

The site of sequestration of ⁵¹Cr-labelled platelets has been studied in 465 subjects, of whom 317 suffered from idiopathic thrombocytopenic purpura. The validity of the method was demonstrated in several ways: a given subject usually showed the same site of platelet sequestration when investigated more than once even after a long interval; there were characteristic and very different platelet sequestration curves in the thrombocytopenias due to bone marrow hypoplasia, hypersplenism or ITP; and there was a correlation between the preoperative in vivo results and the radioactivity found in the spleen after splenectomy.
In ITP the destruction of labelled platelets was more often splenic in children and in patients whose thrombocytopenia responded to steroid therapy. There was a perfect correlation between the site of platelet destruction and the platelet rise immediately after splenectomy. There was a good correlation between the site of platelet destruction and the long-term effectiveness of splenectomy.