Leah Adix

Severe hemorrhage in children with newly diagnosed immune thrombocytopenic purpura

Controversy exists regarding management of children newly diagnosed with immune thrombocytopenic purpura (ITP). Drug treatment is usually administered to prevent severe hemorrhage, although the definition and frequency of severe bleeding are poorly characterized. Accordingly, the Intercontinental Childhood ITP Study Group (ICIS) conducted a prospective registry defining severe hemorrhage at diagnosis and during the following 28 days in children with ITP. Of 1106 ITP patients enrolled, 863 were eligible and evaluable for bleeding severity assessment at diagnosis and during the subsequent 4 weeks. Twenty-five children (2.9%) had severe bleeding at diagnosis. Among 505 patients with a platelet count less than or equal to 20 000/mm(3) and no or mild bleeding at diagnosis, 3 (0.6%), had new severe hemorrhagic events during the ensuing 28 days. Subsequent development of severe hemorrhage was unrelated to initial management (P = .82). These results show that severe bleeding is uncommon at diagnosis in children with ITP and rare during the next 4 weeks irrespective of treatment given. We conclude that it would be difficult to design an adequately powered therapeutic trial aimed at demonstrating prevention of severe bleeding during the first 4 weeks after diagnosis. This finding suggests that future studies of ITP management should emphasize other outcomes.

Bleeding manifestations and management of children with persistent and chronic immune thrombocytopenia: data from the Intercontinental Cooperative ITP Study Group (ICIS)

Long-term follow-up of children with immune thrombocytopenia (ITP) indicates that the majority undergo remission and severe thrombocytopenia is infrequent. Details regarding bleeding manifestations, however, remain poorly categorized. We report here long-term data from the Intercontinental Cooperative ITP Study Group Registry II focusing on natural history, bleeding manifestations, and management. Data on 1345 subjects were collected at diagnosis and at 28 days, 6, 12, and 24 months thereafter. Median platelet counts were 214 × 10(9)/L (interquartile range [IQR] 227, range 1-748), 211 × 10(9)/L (IQR 192, range 1-594), and 215 × 10(9)/L (IQR 198, range 1-598) at 6, 12, and 24 months, respectively, and a platelet count <20 × 10(9)/L was uncommon (7%, 7%, and 4%, respectively). Remission occurred in 37% of patients between 28 days and 6 months, 16% between 6 and 12 months, and 24% between 12 and 24 months. There were no reports of intracranial hemorrhage, and the most common site of bleeding was skin. In patients with severe thrombocytopenia we observed a trend toward more drug treatment with increasing number of bleeding sites. Our data support that ITP is a benign condition for most affected children and that major hemorrhage, even with prolonged severe thrombocytopenia, is rare.

Chronic transfusion practices for prevention of primary stroke in children with sickle cell anemia and abnormal TCD velocities

Chronic transfusions are recommended for children with sickle cell anemia (SCA) and abnormal transcranial Doppler (TCD) velocities ( 200 cm/sec) to help prevent the occurrence of a primary stroke [1]. The goal is usually to maintain the sickle hemoglobin concentration (HbS) <30%; however, this goal is often difficult to achieve in clinical practice. The NHLBI-sponsored trial ‘‘TCD With Transfusions Changing to Hydroxyurea (TWiTCH)’’ will compare standard therapy (transfusions) to alternative therapy (hydroxyurea) for the reduction of primary stroke risk in this patient population. Transfusions will be given according to current transfusion practices at participating sites. To determine current academic community standards for primary stroke prophylaxis in children with SCA, 32 clinical sites collected data on 340 children with abnormal TCD velocities receiving chronic transfusions to help prevent primary stroke. The average (mean ± 1 SD) pretransfusion HbS was 34 ± 11% (institutional average 23–48%); the 75th and 90th percentiles were 41 and 50%, respectively. Lower %HbS was associated with higher pretransfusion Hb values and receiving transfusions on time. These data indicate variable current transfusion practices among academic pediatric institutions and in practice, 30% HbS may not be an easily attainable goal in this cohort of children with SCA and abnormal TCD. Children with sickle cell anemia (SCA) compose a high risk group for the development of stroke. If untreated, 11% will experience a clinical stroke by 20 years of age [2]. Adams et al. have shown that children with SCA who are at risk for primary stroke can be identified by measuring time-averaged mean blood flow velocities in the internal carotid or middle cerebral arteries by TCD [3]. Abnormal TCD velocities ( 200 cm/sec) are associated with high risk for stroke and warrant transfusion therapy to reduce the risk of primary stroke. First stroke can be successfully prevented in 90% of children with SCA and abnormal TCD velocities by the use of chronic transfusion therapy, with a goal of keeping HbS concentrations less than 30% [1]. TCD with Transfusions Changing to Hydroxyurea (TWiTCH) is an NHLBIsponsored, Phase III, multicenter trial comparing standard therapy (monthly transfusions) to alternative therapy (daily hydroxyurea) to reduce the risk of primary stroke in children with SCA and documented abnormal TCD velocities. Since transfusions compose the standard treatment arm, accurate %HbS values achieved in actual clinical practice were needed for protocol development. The majority of our information about transfusing patients with SCA to prevent stroke comes from secondary stroke prevention, i.e., the use of chronic red blood cell transfusions to prevent a second stroke after a first clinical stroke has occurred. Classically, transfusions are administered at 4-week intervals to maintain HbS at less than 30%. After several years of transfusion therapy, a few centers increase transfusion interval to 5–6 weeks and allow HbS to increase toward 50% in selected patients [4,5]. Our previous study in 295 children with SCA who received transfusions for secondary stroke prevention revealed an average pretransfusion HbS of 35 ± 11% with highly variable institutional %HbS levels ranging from 22 to 51% [6] In order to determine the current clinical standard of transfusion therapy for primary stroke prevention for elevated TCD velocities, we performed a larger survey of potential TWiTCH sites. We hypothesized that average pretransfusion HbS values achieved at pediatric academic centers would be higher than 30%. This study defines the current practice at academic medical centers in provision of chronic transfusion therapy to help reduce the risk of primary stroke in children with SCA. A total of 340 children with SCA and history of abnormal TCD velocities receiving chronic PRBC transfusions for primary stroke prophylaxis were identified at 32 institutions (Table I). The number of patients per site ranged from 3 to 33 (median 9 per site). A total of 3,970 transfusions were administered over the 12-month period, with a mean of 11.7 ± 2.8 transfusions per patient. Results were similar when analyzed by each patient contributing equally or each transfusion contributing equally (Table II). The predominant transfusion type by patient was defined as the technique used 6 times over the 12-month period. Most children (79%) received primarily simple transfusions, while 19% had primarily exchange transfusions (11% partial / manual exchange, 8% erythrocytapheresis), and 2% multiple transfusion types. The transfusion goal was <30% at almost all sites (84%), while at five sites, the %HbS was allowed in selected patients to increase to 50% after a period of clinical stability. The majority (95%) of the transfusions were administered within the defined 7-day window. On average, late transfusions were given 1.3 ± 5.5 days after the defined 7-day window. Thirty percent of the patients had at least one late transfusion and 14% had 2 or more late transfusions in the 1-year period. For the 3,653 transfusions with reported %HbS values (representing 92% of the 3,970 transfusions), the mean pretransfusion HbS percentage was 33.2 ± 14.0% (median 32%). The 75th percentile for HbS values was 41%, while the 90th percentile was 51%. There were substantial differences among institutional pretransfusion %HbS values, ranging from 23 ± 14% HbS at one institution where HbS was reported for 103 transfusions given to nine patients during the 12-month period, to 48 ± 15% at another institution where HbS was reported for 95 transfusions administered to nine patients during the same time frame (Table III). The five sites with increased HbS goals to 50% in selected patients did not have higher values than others. For each transfusion, subjects were less likely to have pretransfusion HbS <30% if they were older [OR 0.92 for each year increase in age, 95% CI (0.89, 0.96)] and on transfusions for a longer period of time [OR 0.90 for each year increase in duration, 95% CI (0.86, 0.94)]. Patients with higher pretransfusion Hb levels were more likely to have pretransfusion HbS <30% [OR 1.63 for each g/dL increase in Hb, 95% CI (1.46, 1.83)] and late transfusions were less likely to be associated with a pretransfusion HbS <30% [OR 0.27, 95% CI (0.18, 0.41)]. The Hb result does not appear to be a function of late transfusions since both covariates remained significant when modeled jointly. History of alloor autoantibodies, TCD velocity, and erythrocytapheresis use were not significant predictors of a pretransfusion HbS <30%. During the initial STOP study, transfusions were given to maintain pretransfusion HbS values at less than 30% [3]. However, there were frequent transient rises of HbS above this level [7]. Furthermore, extended follow-up results from the STOP study showed that pretransfusion %HbS values during the post-trial follow-up were higher than those during the STOP study [8]. The average %HbS per patient was 27.5 ± 12.4, still within the desired goal of 30%. However, pretransfusion HbS levels were 30–34.9% in 12%, 35–39.9% in 7%, and greater than 40% in 12% of the transfusions. In the STOP2 study, where children with abnormal TCD velocities whose Doppler readings became normal were randomly assigned to continue or stop transfusions, 24% of the patients had pretransfusion HbS levels greater than 30% [9]. These findings indicate that even in the context of a prospective clinical trial, maintaining HbS <30% was difficult to achieve. With the subsequent recommendation to treat all children with SCA who are at risk for primary stroke with transfusions to maintain HbS <30%, the feasibility of this approach in actual clinical practice is not known. Possible Letters

Laboratory markers of thrombosis risk in children with hereditary spherocytosis

Recent data suggest that adults with hereditary spherocytosis (HS) may be protected from atherothrombosis before splenectomy but have increased risk of thrombosis following splenectomy. In order to aid in making informed decisions regarding splenectomy in children with HS, we conducted a retrospective study of several surrogate laboratory markers of thrombosis risk in children with HS.

Current challenges in the management of children with idiopathic thrombocytopenic purpura

Much progress has been made during the past several decades in the diagnosis and management of childhood idiopathic thrombocytopenic purpura (ITP). Although we do not yet know ITPs cause, opportunities for research discovery in other areas have blossomed in recent years. One major step forward has been realization that outcomes other than platelet count are important in children with ITP, most especially the severity of hemorrhage, cost and side effects of treatment, and overall quality of life. The classical definition of chronic ITP (thrombocytopenia lasting greater than 6 months) has been questioned. Debate continues whether ITP can truly be cured, especially when it lasts for years. Much excitement has recently been generated as a result of a new mechanism of ITP treatment, that is, enhancing platelet production. Yet problems continue regarding how best to conduct research involving newly diagnosed ITP patients, for a number of barriers are still to be overcome. Fortunately, however, abundant information and support for ITP patients and their families is now much more available than in years past. Pediatr Blood Cancer 2006;47:681–684.

Intravenous Ferric Carboxymaltose in Children with Iron Deficiency Anemia Who Respond Poorly to Oral Iron

Objective To assess the benefits and risks of intravenous (IV) ferric carboxymaltose (FCM) in children with iron deficiency anemia (IDA). Study design In a retrospective cohort study of patients seen at our center, we identified all FCM infusions in children with IDA over a 12‐month period through a query of pharmacy records. Clinical data, including hematologic response and adverse effects, were extracted from the electronic medical record. Results A total of 116 IV FCM infusions were administered to 72 patients with IDA refractory to oral iron treatment (median age, 13.7 years; range, 9 months to 18 years). Median preinfusion and postinfusion hemoglobin values were 9.1 g/dL and 12.3 g/dL, respectively (at 4‐12 weeks after the initial infusion; n = 53). Sixty‐five patients (84%) experienced no adverse effects. Minor transient complications were encountered during or immediately after 7 infusions. Conclusion FCM administered as a short IV infusion without a test dose proved to be safe and highly effective in a small yet diverse population of infants, children, and adolescents with IDA refractory to oral iron therapy.

Assessment of a positive selection technique using an avidin column to isolate human peripheral blood T cell subsets

The current studies were designed to assess a new technique for positively selecting human T cells from whole peripheral blood mononuclear cells using the minimal amount of monoclonal antibody required to bind the T cell to an avidin column indirectly via a biotin-conjugated secondary antibody. Positive selection of T cells has previously been avoided because the saturating amounts of antibodies required for other isolation procedures can lead to aberrant results in assays of T cell activation and function. The avidin column technique for obtaining purified T cell subsets was compared to a multi-step procedure that included negative selection panning. The positive selection technique was easily performed within 4 h whereas the negative selection technique required a minimum of 12 h to complete. The avidin column technique proved to be a rapid and simple method for isolating T cell subsets of high purity and normal functional capabilities. Since minimal amounts of monoclonal antibodies were used for the purification protocol, no consistent inhibitory or stimulatory effect of the residual antibody was noted in assays of activation and proliferation of positively selected T cells compared to T cells isolated by negative selection panning.

Effect of Low-Dose Ferrous Sulfate vs Iron Polysaccharide Complex on Hemoglobin Concentration in Young Children With Nutritional Iron-Deficiency Anemia: A Randomized Clinical Trial.

Importance Iron-deficiency anemia (IDA) affects millions of persons worldwide, and is associated with impaired neurodevelopment in infants and children. Ferrous sulfate is the most commonly prescribed oral iron despite iron polysaccharide complex possibly being better tolerated. Objective To compare the effect of ferrous sulfate with iron polysaccharide complex on hemoglobin concentration in infants and children with nutritional IDA. Design, Setting, and Participants Double-blind, superiority randomized clinical trial of infants and children aged 9 to 48 months with nutritional IDA (assessed by history and laboratory criteria) that was conducted in an outpatient hematology clinic at a US tertiary care hospital from September 2013 through November 2015; 12-week follow-up ended in January 2016. Interventions Three mg/kg of elemental iron once daily as either ferrous sulfate drops or iron polysaccharide complex drops for 12 weeks. Main Outcomes and Measures Primary outcome was change in hemoglobin over 12 weeks. Secondary outcomes included complete resolution of IDA (defined as hemoglobin concentration >11 g/dL, mean corpuscular volume >70 fL, reticulocyte hemoglobin equivalent >25 pg, serum ferritin level >15 ng/mL, and total iron-binding capacity <425 &mgr;g/dL at the 12-week visit), changes in serum ferritin level and total iron-binding capacity, adverse effects. Results Of 80 randomized infants and children (median age, 22 months; 55% male; 61% Hispanic white; 40 per group), 59 completed the trial (28 [70%] in ferrous sulfate group; 31 [78%] in iron polysaccharide complex group). From baseline to 12 weeks, mean hemoglobin increased from 7.9 to 11.9 g/dL (ferrous sulfate group) vs 7.7 to 11.1 g/dL (iron complex group), a greater difference of 1.0 g/dL (95% CI, 0.4 to 1.6 g/dL; P < .001) with ferrous sulfate (based on a linear mixed model). Proportion with a complete resolution of IDA was higher in the ferrous sulfate group (29% vs 6%; P = .04). Median serum ferritin level increased from 3.0 to 15.6 ng/mL (ferrous sulfate) vs 2.0 to 7.5 ng/mL (iron complex) over 12 weeks, a greater difference of 10.2 ng/mL (95% CI, 6.2 to 14.1 ng/mL; P < .001) with ferrous sulfate. Mean total iron-binding capacity decreased from 501 to 389 &mgr;g/dL (ferrous sulfate) vs 506 to 417 &mgr;g/dL (iron complex) (a greater difference of −50 &mgr;g/dL [95% CI, −86 to −14 &mgr;g/dL] with ferrous sulfate; P < .001). There were more reports of diarrhea in the iron complex group than in the ferrous sulfate group (58% vs 35%, respectively; P = .04). Conclusions and Relevance Among infants and children aged 9 to 48 months with nutritional iron-deficiency anemia, ferrous sulfate compared with iron polysaccharide complex resulted in a greater increase in hemoglobin concentration at 12 weeks. Once daily, low-dose ferrous sulfate should be considered for children with nutritional iron-deficiency anemia. Trial Registration clinicaltrials.gov Identifier: NCT01904864