Neuronopathic Gaucher disease presenting with microcytic hypochromic anemia.

Gaucher disease (GD) is caused by a hereditary deficiency of glucocerebrosidase, resulting in accumulation of glucosylceramide and potentially manifesting as hepatosplenomegaly. We report the case of a 15-month-old boy with chronic neuronopathic GD. The patient had prolonged anemia despite continued iron supplementation for 3 months. White blood count (WBC), hemoglobin (Hb), platelet count, and corrected reticulocyte count were 3,300 /µL, 8.7 g/dL, 90,000 /µL, and 0.55, respectively. The patient had microcytic hypochromic anemia with mildly elevated ferritin. Physical examination revealed hepatosplenomegaly. Bone-marrow aspiration showed sheets of Gaucher cells. Glucocerebrosidase activity in monocytes was significantly lower than normal. Genetic analysis revealed a homozygous L444P mutation of GBA, and he was diagnosed with type 1 GD. Enzyme replacement treatment (ERT) consisting of imiglucerase was initiated and was effective; WBC, Hb, and platelet count gradually normalized and the hepatosplenomegaly improved. However, when the patient entered elementary school, he showed mild impaired cognitive function, and supranuclear gaze palsy occurred the same year. He was ultimately diagnosed with type 3 GD and continued ERT. Pediatric hemato-oncologists should be aware of GD, especially when patients exhibit anemia refractory to iron therapy, radiologic bone deformity, neurologic signs or symptoms, and growth retardation.

A child with severe iron-deficiency anemia and a complex TMPRSS6 genotype.

OBJECTIVES: We report a case of a 7-year-old girl with severe hypochromic microcytic anemia, who was unresponsive to classical iron supplements. We suspected IRIDA, iron-refractory iron-deficiency anemia, a genetic iron metabolism disorder, caused by TMPRSS6 variations. TMPRSS6 encodes matriptase-2, a negative regulator of hepcidin, and its pathological variants are related to normal to high levels of hepcidin. We analyzed the TMPRSS6 gene and we improved clinical management of the patient, selecting the appropriate supplementation therapy. Intervention & Technique: The parenteral iron therapy was started, but the patient was only partially responsive and the anemia persisted. To confirm the diagnosis, the TMPRSS6 gene sequence was analyzed by DNA sequencing and other relevant biochemical parameters were evaluated. RESULTS: The TMPRSS6 sequence analysis showed a complex genotype with a rare heterozygous missense variant, in addition to other common polymorphisms. The serum hepcidin value was normal. We unexpectedly observed a normalization of patient's hemoglobin (Hb) levels only after liposomal iron treatment. DISCUSSION AND CONCLUSION: The proband was symptomatic for IRIDA during a critical phase of growth and development, but we did not find a clearly causative genotype. A long-term result, improving stably patient's Hb levels, was obtained only after liposomal iron supplementation. Children may be at greater risk for iron deficiency and the degree of anemia as well as the response to the iron supplements varies markedly patient to patient. Here, we show the importance of comprehensive study of these patients in order to collect useful information about genotype-phenotype association of genes involved in iron metabolism.

Diagnosis of iron-deficient states.

The diagnosis of iron deficiency anemia is typically straightforward, especially when classic biochemical and hematological changes are present in a subject at risk. It can be challenging in the presence of diseases or when it is due to inherited defects of iron metabolism. The identification of iron deficiency prior to anemia development is also difficult. New hematological parameters such as reticulocyte Hb content have expanded the classic ones such as MCV, MCH and MCHC. A variety of hematology analyzers now provide novel parameters to assess cellular hypochromia and microcytosis in both reticulocytes and mature red blood cells. The repertoire of biochemical markers has also been expanded, with iron, transferrin and ferritin being supplemented by circulating transferrin receptor and hepcidin. Molecular identification of functional variants of key iron metabolism determinants has provided explanations for the heritability of some iron metabolism biomarkers. Genetic defects in some of these molecules are responsible for hereditary microcytic anemias, also called atypical microcytic anemias. In this review, we examine the most significant hematological and biochemical markers for iron metabolism, as well as relevant genetic polymorphisms and defects affecting iron handling.

[Diagnosis of hypochromic microcytic anemia in children]. / Exploration d'une anémie microcytaire chez l'enfant.

Iron deficiency is the most frequent cause of hypochromic microcytic anemia in children, but other causes, some of them requiring specific management, may be involved. Checking the iron-status is absolutely mandatory. When iron-status parameters are low, inadequate intake, malabsorption, blood loss, and abnormal iron utilization must be tested. In absence of iron deficiency, α- and ß-globin and heme biosynthetic gene status must be checked. Assessing the iron stock level is difficult, because there is an overlap between the values observed in iron-replete and iron-deprived patients, so that at least 2 iron-status parameters must be below normal for diagnosing iron deficiency. Furthermore, inflammation may also mimic some characteristics of iron deficiency. Diagnosing iron deficiency leads to prescribing iron supplementation with follow-up at the end and 3 months after cessation of treatment. When iron stores are not replete at the end of treatment, compliance and dosage must be reevaluated and occult bleeding sought. The latter is also required when the iron store decreases 3 months after cessation of iron replacement.

Microcytic hypochromic anemia patients with thalassemia: genotyping approach.

BACKGROUND: Microcytic hypochromic anemia is a common condition in clinical practice, and alpha-thalassemia has to be considered as a differential diagnosis. AIMS: This study was conducted to evaluate the frequency of alpha-gene, beta-gene and hemoglobin variant numbers in subjects with microcytic hypochromic anemia. SETTING AND DESIGNS: Population-based case-control study in the Iranian population. MATERIALS AND METHODS: A total of 340 subjects from southwest part of Iran were studied in the Research Center of Thalassemia and Hemoglobinopathies (RCTH), Iran. Genotyping for known alpha- and beta-gene mutations was done with gap-PCR and ARMS. In cases of some rare mutations, the genotyping was done with the help of other techniques such as RFLP and ARMS-PCR. STATISTICAL ANALYSIS: Statistical analysis was carried out by SPSS 11.5 and an independent-sample t test. RESULTS: Out of the total 340 individuals, 325 individuals were evaluated to have microcytic hypochromic anemia based on initial hematological parameters such as MCV<80 fl; MCH<27 pg; the remaining 15 patients were diagnosed with no definite etiology. The overall frequency of -alpha3.7 deletion in 325 individuals was 20.3%. The most frequent mutations were IVS II-I, CD 36/37 and IVS I-110 with frequencies of 6.31%, 5.27% and 1.64%, respectively. Only, there was a significant difference between beta-thalassemia trait and beta-thalassemia major with regard to MCV (P<0.05) and MCH (P<0.05) indices, and also MCH index between beta-thalassemia trait and Hb variants (P<0.05). CONCLUSION: Molecular genotyping provides a rapid and reliable method for identification of common, rare and unknown alpha- and beta-gene mutations, which help to diagnose unexplained microcytosis and thus prevent unnecessary iron supplementation.

Genotyping of alpha-thalassemia in microcytic hypochromic anemia patients from North India.

Microcytic hypochromic anemia is a common condition in clinical practice and alpha-thalassemia has to be considered as a differential diagnosis. Molecular diagnosis of alpha-thalassemia is possible by polymerase chain reaction. The aim of this study was to evaluate the frequency of alpha-gene numbers in subjects with microcytosis. In total, 276 subjects with microcytic hypochromic anemia [MCV<80fl; MCH<27pg] were studied. These include 125 with thalassemia trait, 48 with thalassemia major, 26 with sickle-cell thalassemia, 15 with E beta-thalassemia, 40 with iron-deficiency anemia, 8 with another hemolytic anemia, and 14 patients with no definite diagnosis. Genotyping for -alpha3.7 deletion, -alpha4.2 deletion, Hb Constant Spring, and a-triplications was done with polymerase chain reaction. The overall frequency of -alpha3.7 deletion in 276 individuals is 12.7%. The calculated allele frequency for a-thalassemia is 0.09. The subgroup analysis showed that co-inheritance of a-deletion is more frequent with the sickle-cell mutation than in other groups. We were able to diagnose 1/3 of unexplained cases of microcytosis as a-thalassemia carriers. The a-gene mutation is quite common in the Indian subcontinent. Molecular genotyping of a-thalassemia helps to diagnose unexplained microcytosis, and thus prevents unnecessary iron supplementation.

Cancer-related anemia: pathogenesis, prevalence and treatment.

Cancer-related anemia is a cytokine-mediated disorder resulting from complex interactions between tumor cells and the immune system. Overexpression of certain inflammatory cytokines results in shortened survival of red blood cells, suppression of erythroid progenitor cells, impaired iron utilization, and inadequate erythropoietin production. Numerous other factors may also contribute to the development of anemia in cancer patients. The European Cancer Anaemia Survey (ECAS) has provided the most current, comprehensive, prospectively collected data on the incidence and prevalence of anemia among cancer patients, as well as important perspectives on anemia treatment and relationship of hemoglobin and performance status. ECAS enrolled over 15,000 treated and untreated patients with various malignancies from cancer centers in 24 European countries and followed them for up to 6 months. The initial analysis of the ECAS data revealed that 39% of the total cancer patient population was anemic (hemoglobin <12.0 g/dl) at enrollment, although the rate varied according to tumor type, disease status, and cancer treatment status. Of the patients who were not anemic at enrollment and started cancer treatment during the survey, those undergoing chemotherapy--either alone or in combination with radiotherapy--had the highest incidence of anemia (63 and 42%, respectively). Low hemoglobin levels correlated with poor performance status and only 40% of patients who were anemic at some time during the survey received treatment for their anemia. These findings are noteworthy, since a growing body of clinical evidence indicates that the treatment of anemia can significantly improve patients' quality of life and may also improve the clinical outcome.

The quantitative assessment of body iron.

Current initiatives to reduce the high prevalence of nutritional iron deficiency have highlighted the need for reliable epidemiologic methods to assess iron status. The present report describes a method for estimating body iron based on the ratio of the serum transferrin receptor to serum ferritin. Analysis showed a single normal distribution of body iron stores in US men aged 20 to 65 years (mean +/- 1 SD, 9.82 +/- 2.82 mg/kg). A single normal distribution was also observed in pregnant Jamaican women (mean +/- 1 SD, 0.09 +/- 4.48 mg/kg). Distribution analysis in US women aged 20 to 45 years indicated 2 populations; 93% of women had body iron stores averaging 5.5 +/- 3.35 mg/kg (mean +/- 1 SD), whereas the remaining 7% of women had a mean tissue iron deficit of 3.87 +/- 3.23 mg/kg. Calculations of body iron in trials of iron supplementation in Jamaica and iron fortification in Vietnam demonstrated that the method can be used to calculate absorption of the added iron. Quantitative estimates of body iron greatly enhance the evaluation of iron status and the sensitivity of iron intervention trials in populations in which inflammation is uncommon or has been excluded by laboratory screening. The method is useful clinically for monitoring iron status in those who are highly susceptible to iron deficiency.

[Chronic lead poisoning-- a" forgotten" cause of anemia]. / Intoxicatia cronica cu plumb--o cauza "uitata" a sindromului anemic.

We present the case of a female patient with a chronic hypersideremic anemia associated with digestive and neurological symptoms, with a long time ignored toxic history. The diagnose was based on very high levels of lead in serum and urine, very high levels of D-aminolaevulinic acid in the urine, and the presence of basophilic stippling of erythrocytes in the smear of the patient. Lead intoxication was due to ingestion of home-made alcohol (domestic devices made from lead mixtures) and of yogurt preserved in lead-glazed mugs.

Anemia in the elderly.

Anemia should not be accepted as an inevitable consequence of aging. A cause is found in approximately 80 percent of elderly patients. The most common causes of anemia in the elderly are chronic disease and iron deficiency. Vitamin B12 deficiency, folate deficiency, gastrointestinal bleeding and myelodysplastic syndrome are among other causes of anemia in the elderly. Serum ferritin is the most useful test to differentiate iron deficiency anemia from anemia of chronic disease. Not all cases of vitamin B12 deficiency can be identified by low serum levels. The serum methylmalonic acid level may be useful for diagnosis of vitamin B12 deficiency. Vitamin B12 deficiency is effectively treated with oral vitamin B12 supplementation. Folate deficiency is treated with 1 mg of folic acid daily.

[Red cell distribution width (RDW): its use in the characterization of microcytic and hypochromic anemias]. / Indice de distribución de glóbulos rojos (RDW): su aplicación en la caracterización de anemias microcíticas e hipocrómicas.

With the widespread use of cell counters we have now acquired new red cell indices complementary of the old ones, like the HDW and RDW (Red Cell Distribution Width) which detect the heterogeneity of red cell size and anisocytosis in the blood smear. We studied 90 patients with the following results. 1) in the control group of healthy volunteers (n = 50) RDW results were (mean +/- ES) 13.90 +/- 0.10% and MCV (mean +/- ES) 90 +/- 5 fl; 2) the iron deficiency patients (IDA) (n = 20) gave a MCV of (mean +/- ES) 68.60 +/- 1.77 fl., and RDW (mean +/- ES) 20.20 +/- 1.21%; 3) the beta-thalassemic patients (n = 20) had an MCV of (mean +/- ES) 66.45 +/- 1.95 fl, and RDW (mean +/- ES) 17.08 +/- 0.40%. We compared the results of MCV between IDA and thalassemics and against the control group with the following results: control vs IDA and control vs thalassemic with significant differences with p < 0.01, and no significant difference when we compared IDA vs thalassemics. Then we compared the results of RDW between IDA and thalassemics and against the control group with the following results: control vs IDA and control vs thalassemic with significant differences with p < 0.001 and with significant differences when we compared IDA vs thalassemics p < 0.001. The statistical results were obtained with the one-way analysis of variance (ANOVA). The results show that RDW is a more sensitive indicator than MCV to establish the possible origin of microcytic hypochromic anemias and that both should be used together in early diagnosis.

Serum transferrin receptor and transferrin receptor-ferritin index identify healthy subjects with subclinical iron deficits.

Despite the established utility of serum transferrin receptor (sTfR), serum ferritin, and the sTfR/log ferritin ratio (TfR-F Index) in the diagnosis of iron deficiency (ID) anemia, the numeric values of these parameters, which are indicative of subclinical ID, remain to be clearly defined. In this study, 65 apparently healthy nonanemic adults (22 men and 43 women) were treated with 3 months of oral iron supplementation to evaluate its effect on parameters reflecting iron status and to determine the prevalence of subclinical iron deficiency in apparently healthy adults. Significant supplementation-induced changes were observed in sTfR, ferritin, and TfR-F Index values in women, whereas in men, none of the studied parameters showed any significant change. Iron-deficient erythropoiesis (IDE) was not observed in men, but was found in 17 women (40%). Although individuals with a compromised iron status may be represented in substantial numbers in conventional reference populations, they can be readily identified using sTfR, ferritin, and TfR-F Index determinations.

Percentage of hypochromic red blood cells as predictor of erythropoietic and iron response after i.v. iron supplementation in maintenance haemodialysis patients.

BACKGROUND: The percentage of hypochromic red blood cells (RBC), defined as those with a cellular haemoglobin < 28 g/dl has been suggested to be a sensitive marker of functional iron deficiency in maintenance haemodialysis (HD) patients. Thus, during rHuEpo therapy an increase in hypochromic RBC to > 10% would indicate that more intensive iron supplementation may be required. METHODS: We investigated 70 HD patients 57.1 +/- 15.3 years old and on maintenance HD for 66.3 +/- 47.9 months without blood loss from gastrointestinal bleeding or from the vascular access, without surgery and without infectious disease or malignancy. During the study period of 12 weeks, each patient received in i.v. dose of 800 mg ferrogluconate. Haemoglobin, haematocrit, and the percentage of hypochromic RBC were measured before and every 4 weeks after the start of the study; serum ferritin, zinc protoporphyrin (ZPP) and C-reactive protein (CRP) were measured at the beginning (baseline) and end of the study. RESULTS: At baseline the percentage of hypochromic RBC was < or = 5.0% in 28 patients, > 5.0 and < or = 10.0% in 25 patients and > 10.0% in 17 patients, suggesting functional iron deficiency in at least 42 patients. Nine patients had serum ferritin values < 100 micrograms/1; nonetheless in these patients the median percentage of hypochromic RBC was 5.9% (range 0.9-14.3%), indicating that an absolute iron deficiency can occur in the presence of normal amounts of hypochromic RBC. There was a significant correlation between serum ferritin levels and hypochromic RBC at the end, but not at the beginning, of the study. However, there was no correlation between ZPP and hypochromic RBC at any time during the study. During i.v. iron supplementation the rHuEpo dose could be reduced by 8.5% in patients with hypochromic RBC < or = 5.0%, by 11.3% in patients with hypochromic RBC > 5.0 and < or = 10.0% and by 23.4% in patients with hypochromic RBC > 10.0%, demonstrating the benefit of i.v. iron in patients with functional iron deficiency. In HD patients in whom serum ferritin levels remained below 290 micrograms/l until the end of the study, a significant reduction of the rHuEpo dosage could be obtained during i.v. iron therapy. This was not the case in patients with serum ferritin > 290 micrograms/l after iron supplementation. We found that the percentage of hypochromic RBC is the most sensitive parameter for predicting hyporesponsiveness in CRP-positive patients. HD patients with hypochromic RBC > 6% and low to moderate increases in serum ferritin levels after i.v. iron supplementation significantly benefit from i.v. iron therapy compared to HD patients with hypochromic RBC < 6%. CONCLUSIONS: Two different aspects should be taken into consideration in HD patients treated with rHuEpo and concomitant i.v. iron therapy: (1) response of the erythropoietic system to rHuEpo, and (2) adequate delivery of the supplemented iron to the erythropoietic system. The patient's percentage of hypochromic RBC and increase in serum ferritin after i.v. iron supplementation should be used to decide whether or not i.v. iron should be given and to monitor this type of therapy in HD patients.

Iron deficiency. Current trends and fads.

Anaemia due to iron deficiency remains the commonest form of anaemia world-wide, predominantly due to blood loss, either associated with infestations such as hook worm or menstrual blood loss, or malnutrition. In Australia, iron deficiency anaemia is the commonest form of anaemia and is seen in pregnant and breastfeeding females where the iron balance is often in a negative state. Fads and fallacies abound, particularly in this group. Despite extensive knowledge of iron metabolism, diagnosis of iron deficiency often remains a difficult problem. The use of diagnostic tests available is discussed in this article.

Intracranial hypertension in a dieting patient.

We report a case of encephalopathy with paranoid psychosis in association with intracranial hypertension. This occurred in a patient whose diet consisted almost solely of walnuts, ginseng tea, and vitamin A supplements. The patient was found to be severely iron- and vitamin B12-deficient. She was vitamin A toxic. Venous sinus thrombosis was also present. Symptoms remitted with serial lumbar punctures, normalization of diet, and repletion of vitamin B12 and iron stores. Physicians should be alerted to the possibility of a potentially confusing clinical presentation with coexistent and seemingly mutually exclusive neurologic conditions in patients with extremely restricted or fad diets.

Iron status markers and serum erythropoietin in 120 mothers and newborn infants. Effect of iron supplementation in normal pregnancy.

In a randomized, double-blind, placebo controlled study of the effect of iron supplementation during pregnancy, iron status (hemoglobin (Hb), serum (S-)transferrin saturation, S-ferritin) and S-erythropoietin (EPO) were assessed in 120 healthy pregnant women at 14-16 weeks of gestation, and just before delivery; 63 women were treated with 66 mg iron daily, and 57 with placebo. There were no differences in baseline values in the two groups. At term, the iron treated group had significantly higher Hb, transferrin saturation, S-ferritin (median 22 micrograms/l vs. 14 micrograms/l, (p < 0.0001) and lower S-EPO compared to the placebo treated group. In the iron group, 30.2% had exhausted iron stores (i.e. S-ferritin < 20 micrograms/l), 6.3% latent iron deficiency (S-ferritin < 20 micrograms/l and transferrin saturation < 15%), and no patients had iron deficiency anemia (S-ferritin < 20 micrograms/l and transferrin saturation < 15% and HB < 110 g/l). In the placebo group, 93.0% had exhausted iron stores, 54.4% latent iron deficiency, and 17.5% iron deficiency anemia; S-EPO was inversely correlated to iron status markers: Hb, rs = -0.51, p < 0.001; transferrin saturation, rs = -0.65, p < 0.0001; S-ferritin, rs = -0.31, p < 0.01, suggesting that the elevation in S-EPO was secondary to iron deficient erythropoiesis. Newborns to iron treated mothers had higher cord S-ferritin, median 155 micrograms/l, than newborns to placebo treated mothers, median 118 micrograms/l (p < 0.02); there were no differences in birth weight, transferrin saturation, or S-EPO.(ABSTRACT TRUNCATED AT 250 WORDS)

Assessing iron status in children with chronic renal failure on erythropoietin: which measurements should we use?

Iron deficiency severely limits the efficacy of recombinant human erythropoietin (EPO). In order to determine how best to identify and monitor children at risk of developing iron deficiency, we serially measured several parameters of iron status in nine children before and during a 24-week period of EPO therapy. Serum ferritin was the best predictor of development of iron deficiency, five of the nine children developed iron deficiency, characterised by a poor haemoglobin response or evidence of microcytosis and hypochromia; all had a serum ferritin of 60 micrograms/l or less at the start of EPO. Haemoglobin response was also related to change in mean red cell volume (MCV); a falling MCV, irrespective of absolute value, accompanying a poor response to EPO. Iron treatment in five children resulted in significant improvements in haemoglobin and iron status parameters. Although MCV remained low, there was a marked increase in red cell volume distribution width after iron, which may be of value in monitoring the response to iron therapy. We suggest that children with a serum ferritin of 60 micrograms/l or less and those who develop a falling MCV during EPO treatment should receive high-dose oral iron supplementation before and during treatment with EPO.

Prevalence and type of anaemia in female cotton mill workers in Beijing, China.

The present study investigates the prevalence and type of anaemia in Chinese female cotton mill workers. The prevalence of anaemia is reported in 447 non-pregnant female workers aged between 19 and 45 years. The mean value for haemoglobin (Hb) was 123 (SD 15) g/l and 150 of the total 447 subjects had Hb values below 120 g/l; thus 34% of the population was anaemic according to World Health Organization (WHO, 1975) criteria. The mean value for free erythrocyte protoporphyrin (FEP) was 419 (SD 215) micrograms/l; 55% of the total population had FEP values higher than 350 micrograms/l and 72% among the anaemic subjects. Serum ferritin (SF) was tested in all the women with a Hb value less than 120 g/l and 71% of them had SF values below 12.0 micrograms/l. Eighty women diagnosed as either Fe deficient or with Fe-deficient anaemia were selected for a diagnostic supplementation trial. They were randomly assigned to FeSO4 (60 or 120 mg Fe/d) or placebo treatment for 12 weeks. Fe supplementation increased mean Hb values from 114 to 127 g/l (P < 0.001) and SF levels from 9.7 to 30.0 micrograms/l (P < 0.001), and decreased mean FEP values from 570 to 277 micrograms/l (P < 0.001). The response rate of Hb in the whole Fe-treated group or Fe-treated subjects with an Hb level less than 120 g/l was 90% or 92% respectively. These findings indicate that the type of anaemia in this population was mainly Fe deficiency. It was also found that in this population the severity of anaemia, not the prevalence, was significantly related to the use of intra-uterine devices (IUD).