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Query: UMLS:C0002871 (anemia)
 52,094 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The cause of anemia in chronic renal failure is multifactorial. Decreased erythropoietin (EPO) production is the main pathogenetic factor, but iron deficiency is the primary cause of unresponsiveness to EPO therapy. The diagnosis of iron deficiency in patients with chronic renal failure is difficult. We assessed the sensitivity and specificity of serum ferritin, total iron-binding capacity, transferrin saturation index, erythrocyte ferritin, and serum transferrin receptor in 63 patients with chronic renal failure undergoing dialysis (47 men, 16 women) with iron deficiency anemia. They were selected on the basis of clinical stability and absence of factors that may interfere with iron metabolism. None of the patients had received intravenous iron therapy or recombinant human erythropoietin (rHuEPO). Bone marrow biopsy with iron staining was the reference standard for iron stores. The receiver operating characteristic (ROC) curve and the area under the curve were calculated to assess the sensitivity and specificity of iron metabolism parameters. The parameter with the largest area under the ROC curve was serum ferritin (0.83). A cut point of 121 microgram/L showed a sensitivity and a specificity of 75%. The areas under the ROC curves of serum transferrin receptor and erythrocyte ferritin were 0.69 and 0.68, respectively. The remaining parameters showed areas under the ROC curve less than 0.65. Although serum transferrin receptor and erythrocyte ferritin may be acceptable markers for iron deficiency in stable chronic renal failure patients, serum ferritin level continues to be the most reliable diagnostic parameter. Transferrin saturation index is not a reliable parameter for the diagnosis of iron deficiency in stable patients not treated with rHuEPO.
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PMID:Diagnosis of iron deficiency in chronic renal failure. 1046 62

Vitamin A deficiency produces anemia and altered iron status. In this study with rats we tested two hypotheses regarding vitamin A deficiency: (1) that it impairs erythropoiesis, leading to an increased red cell turnover, and (2) that it inhibits the glycosylation of transferrin. Erythropoietic activity was assessed indirectly by determining the myeloid:erythroid ratio in bone marrow smears, the number of erythroid colonies in the red pulp of spleen, the blood reticulocyte index, and zinc protoporphyrin and plasma transferrin receptor concentrations. Transferrin glycosylation was assessed by measuring the sialic acid content of transferrin. The effects of vitamin A deficiency were compared with those of iron deficiency. Iron deficiency produced anemia and low iron levels in organs. Vitamin A deficiency produced low levels of plasma and hepatic retinol, and it induced decreased plasma total iron-binding capacity and raised iron levels in tibia and spleen. Short- but not long-term iron deficiency reduced the number of erythroid colonies in spleen; vitamin A deficiency had no influence. Neither iron nor vitamin A deficiency influenced the myeloid:erythroid ratio in bone marrow smears and the blood reticulocyte production. Plasma transferrin receptor and erythrocyte zinc protoporphyrin concentrations were not affected by vitamin A deficiency but increased with iron deficiency. Vitamin A deficiency did not stimulate erythrocyte breakdown, as indicated by unaltered plasma lactate dehydrogenase activity and reduced plasma total bilirubin levels. Both vitamin A and iron deficiencies raised the proportion of multiple sialylated transferrins in plasma. Thus, we have not found evidence that vitamin A deficiency affects erythropoiesis and erythrocyte turnover. The iron accumulation in spleen and bone marrow may be related to reduced iron transport due to inhibition of transferrin synthesis rather than inhibition of transferrin sialylation.
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PMID:Indicators of erythrocyte formation and degradation in rats with either vitamin A or iron deficiency. 1082 45

Effective management of early anaemia in the course of chronic renal insufficiency requires the following: (i) implementing an efficient diagnostic strategy to exclude common contributing factors; (ii) initiating epoetin therapy for the majority of patients; for and (iii) ensuring adequate iron supply erythropoiesis. Diagnostic inquiry is warranted whenever the haemoglobin concentration is below the normal range adjusted for age and gender. The most efficient diagnostic approach is to assume erythropoietin deficiency, exclude iron deficiency, and pursue further diagnostic tests only when red-cell indices are abnormal or when leukopenia or thrombocytopenia are also present. Macrocytosis should prompt an inquiry into alcoholism, B12 deficiency, or folate deficiency. Microcytosis suggests iron deficiency or thalassaemia. Associated cytopenias raise the possibility of alcohol toxicity, pernicious anaemia, malignancy, or myelodysplastic syndrome. Epoetin therapy is warranted whenever the haemoglobin concentration has fallen below 10.0 g/dl. To initiate therapy prior to dialysis, epoetin should be administered at an average dose of 100 IU/kg/week (80-120 IU/kg/week, 50-150 IU/kg/ week) by subcutaneous injection. Haemoglobin concentration should be monitored every 2 weeks and the epoetin dose adjusted by increments or decrements of 25% to maintain a rate of rise of haemoglobin concentration of 0.2-0.6 g/dl (0.3 0.6 g/dl/week, 0.2-0.5 g/dl/week). When the target range is achieved, the dose of epoetin should be continually adjusted to maintain a stable haemoglobin concentration. Transferrin saturation and ferritin concentration should be monitored monthly, and sufficient iron provided to maintain transferrin saturation above 20%. The lower the haemoglobin concentration, the greater the likelihood that future intravenous iron will be required. Oral iron supplements should be avoided, since they are costly, ineffective, and troublesome to patients. Finally, a blunted therapeutic response to epoetin therapy provides important diagnostic information and gnostic inquiry.
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PMID:Management of early renal anaemia: diagnostic work-up, iron therapy, epoetin therapy. 1103 56

Several parenteral iron preparations are now available. This article focuses on iron sucrose, a hematinic, used more widely than any other for more than five decades, chiefly in Europe and now available in North America. Iron sucrose has an average molecular weight of 34 to 60 kd, and after intravenous (IV) administration, it distributes into a volume equal to that of plasma, with a terminal half-life of 5 to 6 hours. Transferrin and ferritin levels can be measured reliably 48 hours after IV administration of this agent. Iron sucrose carries no "black-box" warning, and a test dose is not required before it is administered. Doses of 100 mg can be administered over several minutes, and larger doses up to 300 mg can be administered within 60 minutes. The efficacy of iron sucrose has been shown in patients with chronic kidney disease (CKD) both before and after the initiation of dialysis therapy. Iron sucrose, like iron gluconate, has been associated with a markedly lower incidence of life-threatening anaphylactoid reactions and may be administered safely to those with previously documented intolerance to iron dextran or iron gluconate. Nonanaphylactoid reactions, including non-life-threatening hypotension, nausea, and exanthema, also are extremely uncommon with iron sucrose. Management of patients with the anemia of CKD mandates that we carefully examine the effectiveness and safety of this oldest of iron preparations and the accumulating present-day data regarding it and contemporaneous agents.
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PMID:Iron sucrose: the oldest iron therapy becomes new. 1266 81

We present the results on Anaemia Management in Fresenius Medical Care Spain dialysis centres as reported by EuCliD (European Clinical Database), evaluating a population of 4,426 patients treated in Spain during the year 2001. To analyse the erythropoietin dose and the haemoglobin levels we divided the population in two groups according to the time with dialysis treatment: patients treated less than six months and patients between six months, and four years on therapy. We compared our results with the evidence based recommendations Guidelines: the European Best Practice Guidelines (EBPG) and the US National Kidney Foundation (NKF-K/DOQI). We also compared our results with those presented by the ESAM2 on 2,618 patients on dialysis in Spain carried out in the second half of the year 2000. We observed that 70% of the population reaches an haemoglobin value higher that 11 g/dl, with a mean erythropoietin (rHu-EPO) dose of 111.9 Ul/kg weight/week (n = 3,700; SD 74.9). However, for those patients on treatment for less than six months, the mean Haemoglobin only reaches 10.65 g/dl (n = 222; SD 1.4). The rHu-EPO was administrated subcutaneously in 70.2% of the patients. About the iron therapy, 86% of the patients received iron treatment and the administration route was intravenous in 93% of the population. The ferritin levels were below 100 micrograms/dl in 10% of the patients and 26.4% showed a transferrin saturation index (TSAT) below 20%. The erythropoieting resistance index (ERI), as rHu-EPO/haemoglobin, has been used to evaluate the response to rHu-Epo, according to different variables. It was observed that the following factors lead to a higher rHu-EPO resistance: intravenous rHu-EPO as administration route, the presence of hypoalbuminemia, increase of protein C reactive, Transferrin saturation below 20% and starting dialysis during the last six months.
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PMID:[Anemia management in haemodialysis. EuCliD database in Spain]. 1251 89

In untreated hepatitis virus (HCV)-positive renal transplant patients, the rate of liver fibrosis progression is low. In contrast, in those treated by ribavirin monotherapy, liver fibrosis score increased significantly after only 1 year of ribavirin monotherapy. The aim of this study was to identify the factors that might contribute to accelerate liver fibrosis progression in this population. Eleven patients were included in the study. Intrahepatic transforming growth factor (TGF)-beta, interferon (IFN)-gamma, and interleukin (IL)-10 mRNA quantification determined by real-time reverse transcription-polymerase chain reaction (RT-PCR) were similar before and after ribavirin therapy. The number of amino acid substitutions observed in the hypervariable region (HVR)-1 of the HCV genome between baseline and 1 year after ribavirin monotherapy was low, i.e., 3 (1-11) amino acid substitutions, suggesting the absence of a high selection pressure induced by ribavirin. In contrast, due to ribavirin-induced hemolysis, there was a significant increase in serum ferritin levels (P = 0.02) and in intrahepatic iron deposition (P = 0.04). Transferrin level and total iron-binding capacity decreased significantly during ribavirin monotherapy (P = 0.004). The increased liver fibrosis observed in renal transplant patients receiving ribavirin monotherapy could be related to ribavirin-induced anemia. Severe chronic hemolysis is responsible for iron overload, liver iron deposition, and an acceleration in the progression of liver fibrosis.
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PMID:Factors accelerating liver fibrosis progression in renal transplant patients receiving ribavirin monotherapy for chronic hepatitis C. 1577 76

We investigated the effect of exercise on iron metabolism in horses. Four horses were walked on a mechanical walker for 1 wk (pre-exercise). They then performed moderate exercise on a high-speed treadmill in the first week of the exercise and relative high in the second week and high in the third week. Serum iron was significantly lower in the third week of exercise than in the pre-exercise. Transferrin saturation (TS) was significantly lower in the first and third weeks of exercise than in the pre-exercise. Serum haptoglobin was significantly lower in the first week of exercise than in the pre-exercise and further significantly lower in the second and third weeks than in the first. The packed cell volume did not change during the experiment. The exercise significantly increased the apparent absorption of iron. Urinary iron excretion did not change throughout the experiment. Sweat iron loss did not change during the exercise. The exercise significantly increased iron balance. We considered that hemolysis is induced by moderate exercise and is further enhanced by heavy exercise, which decreases serum iron and TS. However, the increase in iron absorption compensates for the adverse effect of exercise on iron status. Therefore, exercise does not induce anemia in horses.
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PMID:Effect of exercise on iron metabolism in horses. 1617 Feb 20

A normocytic normochromic anemia is one of the first signs of renal failure. Since anemia increases morbidity and mortality, its elimination is one of the essential objectives of the treatment. Human recombinant erythropoietin (rHuEPO) has changed the therapeutical approach to anemia. The aim of the present study was to compare efficacy of anemia correction in peritoneal dialysis patients depending on treatment and dialysis modality. The study is the retrospective analysis of 64 patients who presented to our Clinic in 2003. Eighteen (28.13%) patients were treated with rHuEPO, 14 (28%) underwent continuous ambulatory peritoneal dialysis (CAPD), 2 (100%)--automated peritoneal dialysis (APD) and 2 (33.3%)--intermittent peritoneal dialysis (IPD). Mean hemoglobin level was 98.6 +/- 17.82 g/l in patients treated with rHuEPO versus 98.81 +/- 15.14 g/l in patients without rHuEPO treatment. Erythropoietin requirements were 3392.85 +/- 1211.77 IU/week All patients received iron supplementation during rHuEPO therapy. Mean serum ferritin levels were 463.41 +/- 360 ug/l. Transferrin saturation (TSAT) was 0.35 +/- 0.16%. No difference of serum iron and TSAT levels was found between CAPD and IPD patients. The degree of anemia significantly differed between CAPD and IPD patients. A total of 17.11% of PD patients were given blood transfusions, most frequently during the first three months after the onset of dialysis. Our conclusion is that the number of patients receiving rHuEPO should be increased, as 50% of our patients should be substituted, while only 28% are being treated. As 50% of patients receiving rHuEPO failed to reach target Hgb levels, higher EPO doses should be considered. Iron stores should be continuously monitored, particularly in patients receiving rHuEPO, since iron deficiency is an important problem for patients undergoing peritoneal dialysis, especially during erythropoietin therapy. Oral iron supplementation is satisfactory in the majority of patients, and iron-gluconate is absorbed better than iron-sulphate. If required, intra-venous iron bolus is safe and efficient. Continuous peritoneal dialysis treatment improves blood count more effectively compared to intermittent procedures, as hemoglobin levels are significantly higher in patients with comparable iron stores. Peritoneal dialysis is particularly efficient in improving the blood count in diabetics, since no significant difference of anemia between patients affected by diabetes mellitus and the others could be found in our study.
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PMID:[Anemia in peritoneal dialysis patients]. 1691 54

A 6-mo longitudinal study of 48 hemodialysis patients (HPs) with chronic renal failure was performed. Three blood samplings were done. Samples of whole blood from each patient were collected during hemodialysis sessions after passing through the artificial kidney. Zinc and copper levels were measured by atomic absorption spectrometry. Additionally, 36 biochemical indexes were evaluated during the study. Fifty-two healthy matched controls were also considered. Mean serum zinc and copper concentrations in HPs were significantly decreased (Zn) and increased (Cu), when compared with healthy controls (p < 0.01). Zinc concentrations found in the first and second blood samplings from patients were significantly lower than those measured for the third sampling (p < 0.01). The etiology of chronic renal failure influenced the statistically serum Zn levels of patients (p < 0.05). Serum copper levels of HPs were significantly diminished by the existence of secondary associated diseases (p < 0.01). Uric acid and parathyroid hormone, and total-cholesterol and glutamic-pyruvic-transaminase levels were significantly (p < 0.05) and linearly related with serum zinc and copper concentrations, respectively. From all of indexes, creatinine, direct bilirubin, magnesium, calcium, parathyroid hormone, transferrin, and albumin were statistically modified along the longitudinal study (p < 0.05). Transferrin serum levels were significantly diminished in the third blood sampling, indicating the tendency toward anemia in the patients. This result is reinforced by low levels of biochemical and hematological indexes related with iron body staus.
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PMID:Longitudinal study of serum zinc and copper levels in hemodialysis patients and their relation to biochemical markers. 1719 22

DMT1 deficiency causes microcytic hypochromic anemia due to decreased erythroid iron utilization. Anemia is present from birth. Transferrin saturation is high and serum ferritin is mildly elevated, despite liver iron overload. DMT1 deficiency must be considered in the differential diagnosis of microcytic hypochromic anemia observed in the newborn period.
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PMID:Natural history of recessive inheritance of DMT1 mutations. 1815 16


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