Intravenous iron supplementation in children on hemodialysis

BACKGROUND: Children with end-stage renal disease (ESRD) on hemodialysis (HD) are often absolute or functional iron deficient. There is little experience in treating these children with intravenous (i.v.) iron-sucrose. In this prospective study, different i.v. iron-sucrose doses were tested in children with ESRD on HD and the effect on iron status measured. METHODS: Fourteen patients were divided into three groups according to their actual iron status. Group A--iron deficient (ferritin (F)<100 microg/L, or F 100-400 microg/L and transferrin saturation (TSAT)<20%). These patients were treated with i.v. iron-sucrose 3 mg/kg/dialysis. Group B--iron-replete (F 100-400 microg/L and TSAT> or =20%, or TSAT>50%). These patients received 0.3 mg/kg/dialysis iron-sucrose. Group C--possible iron-overloaded (F>400 microg/L). These patients were not treated with iron. RESULTS: Group A--3 mg/kg/dialysis of iron-sucrose resulted in a major increase in F, indicating possible iron overload. Therefore, the iron-deficient patients received 1 mg/kg/dialysis iron-sucrose during 22 periods of 2-14 (mean 5) weeks: the median F increased from 186 to 343 microg/L (p<0.001). Group B--0.3 mg/kg/dialysis iron-sucrose resulted in adequate iron levels during 22 periods of 2-60 (mean 9) weeks. CONCLUSION: In children, 3 mg/kg/dialysis iron-sucrose complex results in a possible iron overload. Dosage of 1 mg/kg/dialysis and 0.3 mg/kg/dialysis seem adequate for correction and maintenance therapy respectively.     

Efficacy of hepatic computed tomography to detect iron overload in chronic hemodialysis

The diagnostic efficacy of hepatic computed tomography density (HCTD) in comparison with serum ferritin for the detection of iron overload was investigated in uremic patients on maintenance hemodialysis (HD) and in patients with idiopathic hemochromatosis (IHC). Ten IHC patients, 38 HD patients and 40 healthy subjects underwent the CT scanning of the liver and determination of percent saturation of transferrin, serum ferritin concentration and HLA typing. Liver iron content was determined by histochemical grading and direct measurement of liver iron concentration either in IHC patients or in HD patients. Nineteen HD patients were considered to have iron overload on the basis of liver iron concentration exceeding 3.6 mumol/100 mg dry weight. The mean +/- SD values of HCTD in healthy subjects, IHC patients, HD patients with iron overload and without iron overload were 60.2 +/- 5.6, 79 +/- 5.6, 71.4 +/- 3.6, 58 +/- 3.8 Hounsfield units, respectively. HCTD showed positive correlations with liver iron concentration and serum ferritin either in IHC patients or in HD patients. The analysis of the diagnostic efficacy of HCTD in comparison with serum ferritin for the detection of excessive hepatic iron in HD patients demonstrated that HCTD had higher sensitivity, specificity, positive and negative predictive values. Cut-off points were arbitrarily fixed to 66 Hounsfield units for HCTD, 400 micrograms/liter for serum ferritin and 3.6 mumol/100 mg dry weight for liver iron concentration. Seventeen HD patients who possessed the histocompatibility antigens associated with IHC, namely HLA-A3 and/or HLA-B7 and/or HLA-B14, had liver iron concentration, serum ferritin and HCTD values higher than those of the HD patients without these "hemochromatosis alleles".(ABSTRACT TRUNCATED AT 250 WORDS)     

Issues related to iron replacement in dialyzed patients

Correction of renal anaemia by erythropoiesis stimulating agents (ESA) had reduced blood transfusion needs and iron overload risk and nowadays most of end-stage renal disease patients treated with dialysis requires i.v. iron supplementation to optimize the action of ESAs. Recommended targets for iron therapy are serum ferritin > 100 microg/l and hypochromic red cells percentage (HRC) < 10 (or transferrin saturation coefficient [TSAT] > 20% or reticulocyte Hb content [CHr] > 29 pg/cell). If i.v. administration is strongly recommended for all dialysis patients, controversies remain for the mode and rhythm of administration. Follow-up should be done every 1 to 3 months with measurement of serum ferritin in order to keep its level < 500 to 800 microg/l. Potential toxicity of chronic exposure to i.v. iron concerns tissue accumulation, consequences of pro-oxidant effects, cardiovascular damage and increased risk of infection but no clinical data unequivocally confirm that iron overload from parenteral iron contributes to all cause morbidity and mortality. In conclusion, i.v. iron should be used to optimize ESA action and could be used safety if dosage is < or = 100 mg/week and serum ferritin < 500 a 800 microg/l.     

肝硬化脾功能亢进患者肝组织中铁过载及铁调素mRNA表达的意义

目的 探讨肝硬化合并不同程度脾功能亢进(脾亢)患者肝组织中铁过载及铁调素(hepcidin)mRNA表达的意义.方法 收集肝硬化合并轻、中及重度脾亢患者肝活检标本各10例,共30例(肝硬化组),外伤性肝破裂手术标本10例(对照组),采用原子分光光度计检测肝组织铁元素含量;采用化学发光法检测血清铁蛋白的含量;采用逆转录-聚合酶链反应(RT-PCR)检测肝组织hepcidin mRNA的表达.结果 肝硬化脾亢患者按脾功能亢进程度分为轻、中及重度3组,其肝组织中铁元素含量明显递增,分别为(0.1205±0.0021)、(0.1624±0.0028)和(0.1716±0.0032)mmol/g,均明显高于正常肝组织(0.0639±0.0025)mol/g(P<0.05),表现为铁过载;肝硬化组血清铁蛋白的含量为(436.2±51.6)μg/L,显著高于对照组的(152.5±38.7) μg/L(P<0.01);肝硬化组hepcidin mRNA的表达水平为1.73±0.26,明显高于对照组的0.68±0.22(P<0.01);而且各组的hepcidin mRNA表达水平与血清铁蛋白含量之间具有显著相关性(肝硬化组r=0.735,对照组r=0.648,P<0.01).结论 肝硬化脾亢患者的肝组织中存存铁过载,并随脾亢程度加重而明显增加;hepcidinmRNA是调节铁代谢平衡并影响肝硬化进程的重要因素.     

Serial ferritin concentrations in hemodialysis patients receiving intravenous iron

BACKGROUND: Treatment of the anemia of chronic renal failure with intravenous iron and erythropoietin is highly effective, but frequently leads to ferritin levels which are much higher than those seen in the general population. High ferritin concentrations raise concern about the potential toxicity of increased body iron stores. PATIENTS AND METHODS: We retrospectively evaluated parameters of iron metabolism over a 4-year period among all our chronic hemodialysis patients who had been receiving intravenous iron and erythropoietin. Initially, patients received intermittent infusions of 300 mg intravenous iron x 3 doses for a low ferritin or low percent saturation of total iron binding capacity (TIBC), but this protocol was subsequently changed to weekly or biweekly infusions of 50-100 mg. RESULTS: We observed an improvement in average hemoglobin values, modest increases in serum iron and saturation of iron binding capacity, and a 125% increase in ferritin levels over 4 years. TIBC decreased. Overall, ferritin values increased 79 microg/l for each 1% increase in TIBC saturation. Ten patients with ferritin concentration greater than 1,000 pg/l received a three month course of vitamin C with no decline in the ferritin concentration. CONCLUSION: Current protocols for iron delivery may result in progressive increases in ferritin levels. Concern about the risks of iron overload should temper the quantity of iron used in dialysis programs.     

Melatonin corrects reticuloendothelial blockade and iron status in haemodialysed patients

AIM: Treatment of anaemia in haemodialysed patients in the setting of inflammation usually displays high levels of serum ferritin (>800 ng/mL) and low transferrin saturation (TSAT) (<20%) despite i.v. iron supplementation, thus proving iron trapping in the reticuloendothelial system. Melatonin has been reported to reduce cytokine production and, in dialysis patients, to prevent oxidative stress resulting from iron and erythropoietin treatment. METHOD: In this study, we evaluated a group of 10 patients undergoing haemodialysis who displayed elevated serum ferritin (981 +/- 44.6 ng/mL) and TSAT <20% (15.6 +/- 3.8%) after having received 1.2 g of i.v. iron dextran over a period of 8 weeks. These patients received oral melatonin, 6 mg/day at night for 30 days. RESULTS: After this treatment, all of them markedly increased TSAT values, reaching 35.5 +/- 6.7% (P < 0.0001 vs basal values). In addition, ferritin values decreased to 754.4 +/- 263.7 ng/mL (P < 0.05), and serum iron dramatically increased in all of the patients under study (42.4 +/- 9.4 vs 109.7 +/- 24.3 microg/dL; P < 0.0001). Values for haematocrit (28.6 +/- 2.7 vs 31.9 +/- 3.57%; P < 0.05) and haemoglobin (9.19 +/- 0.97 vs 10.04 +/- 1.29 g/dL; P < 0.05) were also improved. Measurements were then repeated 2 weeks after melatonin withdrawal, showing an impressive decrease in TSAT (16.4 +/- 5.3%; P < 0.00001) and serum iron (48 +/- 14.7 microg/dL; P < 0.0001) values and an almost significant increase in ferritin values (954.4 +/- 86 ng/mL; P < 0.054). CONCLUSION: The present study demonstrates that melatonin may strongly correct the reticuloendothelial blockade seen in dialysis patients under an inflammatory status, thus allowing a better management of iron derangements and renal anaemia.     

Comparison of intravenous ascorbic acid versus intravenous iron for functional iron deficiency in hemodialysis patients

The effect of intravenous ascorbic acid was compared with that of intravenous iron in the treatment of functional iron deficiency, as defined as serum ferritin levels over 300 ng/ml and serum iron levels below 50 microg/dl, in patients on chronic hemodialysis. Thirteen patients on chronic hemodialysis with functional iron deficiency received intravenous injections of ascorbic acid, 100 mg, three times a week, after hemodialysis. The therapy was continued until serum ferritin decreased to below 300 ng/ml (3 months at the maximum). The iron and control group were composed of patients who had serum iron levels below 50 microg/dl within 3 months after serum ferritin rose to over 300 ng/ml. Seven patients with the iron group received more than a total of 10 intravenous injections of saccharated ferric oxide (40 mg/dose) after hemodialysis, and seven patients with the control group received no iron preparation during the 3 months. In the ascorbic acid group, while hemoglobin did not change from 10.9 +/- 0.5 g/dl (mean +/- SE) during the three-month period, serum iron increased significantly from 37 +/- 4 microg/dl to 49 +/- 4 microg/dl after one month (p<0.01), and remained elevated until the end of the three-month period. Serum ferritin decreased significantly from 607 +/- 118 ng/ml to 354 +/- 30 ng/ml after 3 months (p<0.01). In the iron group, hemoglobin and serum iron increased significantly from the respective pre-treatment levels during the 2-month period, and serum ferritin rose significantly after 3 months. In the control group, hemoglobin, serum iron and ferritin levels decreased significantly from the respective pre-treatment levels during the 3 months. The recombinant erythropoietin dose remained stable for three months in the ascorbic acid, iron, and control groups, respectively. These results suggest that in hemodialysis patients with a functional iron deficiency, treatment with intravenous ascorbic acid can prevent iron overload due to treatment with intravenous iron, and provide a useful adjuvant means of maintaining hemoglobin and serum iron levels.     

Iron supplementation in haemodialysis - practical clinical guidelines

Background. The aim of this prospective study was to test a new protocol for iron supplementation in haemodialysis patients, as well as to assess the utility of different iron metabolism markers in common use and their 'target' values for the correction of iron deficiency. Methods. Thirty-three of 56 chronic haemodialysis patients were selected for long-term (6 months) i.v. iron therapy at 20 mg three times per week post-dialysis based on the presence of at least one of the following iron metabolism markers: percentage of transferrin saturation (%TSAT) <20%; percentage of hypochromic erythrocytes (%HypoE) >10% and serum ferritin (SF) <400 &mgr;g/l. Reasons for patient exclusion were active inflammatory or infectious diseases, haematological diseases, psychosis, probable iron overload (SF ⩾400 &mgr;g/l) and/or acute need of blood transfusion mostly due to haemorrhage and change in renal replacement treatment. Results. More than half (51.8%) of the patients of our dialysis centre proved to have some degree of iron deficiency in spite of their regular oral iron supplementation. At the start of the study the mean haemoglobin was 10.8 g/dl and increased after the 6 months of iron treatment to 12.8 g/dl (P<0.0001). The use of erythropoietin decreased from 188 units/kg/week to 84 units/kg/week. The criterion for iron supplementation with the best sensitivity/specificity relationship (100/87.9%) was ferritin <400 &mgr;g/l. Patients with ferritin <100 &mgr;g/l and those with ferritin between 100 &mgr;g/l and 400 &mgr;g/l had the same increase in haemoglobin but other parameters of iron metabolism were different between the two groups. Conclusions. Routine supplementation of iron in haemodialysis patients should be performed intravenously. Target ferritin values should be considered individually and the best mean haemoglobin values were achieved at 6 months with a mean ferritin of 456 &mgr;g/l (variation from to 919 &mgr;g/l). The percentage of transferrin saturation, percentage of hypochromic erythrocytes and ferritin <100 &mgr;/l, were not considered useful parameters to monitor routine iron supplementation in haemodialysis patients. No significant adverse reactions to iron therapy were observed. Keywords: erythropoietin; ferritin; haemodialysis; iron; intravenous      

The effect of an iron supplement on serum aluminum level and desferrioxamine mobilization test in hemodialysis patients.

BACKGROUND: The serum aluminum (Al) measurement with desferrioxamine (DFO) mobilization is a screening test for uremic patients with an Al overload. In these patients, body iron status is one of the factors affecting the serum Al level. This study is designed to elucidate the effects of iron supplements on the serum Al and the DFO mobilization test. METHODS: Our study featured ten hemodialysis patients with iron deficiency anemia. The iron supplement was given intravenously with saccharated ferric oxide, 40 mg three times weekly, at the end of each hemodialysis. The total amount of iron supplement was 1,000 mg. All the patients underwent a DFO test at a dose of 5 mg/kg. The same test was repeated two weeks after completion of the iron supplement. RESULTS: After the iron supplement, patients' iron deficiency anemia improved with a serum ferritin elevation from 312.4 +/- 589.5 to 748.2 +/- 566.2 microg/L (p < 0.01), and iron saturation from 21.6 +/- 20.3 to 41.1 +/- 21.7% (p = 0.06). The basal serum Al level decreased from 34.3 +/- 13.8 to 21.8 +/- 8.5 microg/L (p = 0.01). In the DFO mobilization test, the peak serum Al level decreased from 63.4 +/- 19.3 to 50.7 +/- 20.5 microg/L (p < 0.01). The amount of Al increment (deltaAl) in DFO test was not changed (29.1 +/- 12.0 vs. 28.9 +/- 15.9 microg/L, p = 0.86). The change in basal Al level tended to negatively correlate with the percentage of increment in iron saturation (r = -0.628, p = 0.05). CONCLUSION: Results in this study suggest that iron supplements may significantly reduce the basal serum Al and peak Al in DFO mobilization test, without significant change of the mean deltaAl. The data presented indicate that in the interpretation of serum aluminum levels the iron status should be taken into account.     

Use of deferasirox (Exjade) for iron overload in peritoneal dialysis patients

A 54 year old male with b‐Thalassemia major developed ESRD and was managed with continuous ambulatory peritoneal dialysis. Although not able to be transfused due to high titre red cell antibodies he did require management of iron overload. Deferasirox (Exjade) was administered orally. There was concern that excretion of iron via the peritoneal dialysate may raise the risk of iron‐dependent infections (Yersinia and Rhizopus).Whilst receiving Exjade 1000mg /day, a total collection of 12.7L of peritoneal dialysate was collected over a 24 hour period by the patient. The dialysate total iron levels were measured by ICP‐MS at 0.46mmol/L which equates to 0.33mg of Fe in total. Over a 6 month period his serum ferritin fell from 3869μg/l to 1545μg/l. There were no episodes of peritonitis. Since only 7‐8% of the deferasirox and iron complex is excreted through the urine, the amount of Fe seen in the patient's dialysate might be expected to be up to 1.5‐1.6mg. Yet, the results of the Fe levels in the patient’s PD fluid was a meagre 0.33mg, about five times lower than expected.Whilst only moderately effective at a dosage of 1000mg/day, deferasirox may be a safe agent for iron removal in iron overloaded peritoneal dialysis patients, as relatively low dialysate iron levels reduces the risk of Yersinia and Rhizopus infection.     

Diagnosis and treatment of iron overload in paediatric patients on chronic haemodialysis

In this study the incidence and contributing factors of iron overload in paediatric patients treated with intermittent haemodialysis were evaluated. Particular attention was given to the diagnostic value of serum ferritin in the assessment of body iron stores in patients with hepatocellular damage. The results of treatment of secondary haemosiderosis with desferrioxamine (DFO) are reported. Serum ferritin levels were measured in 18 children and adolescents undergoing long-term haemodialysis; 8 of these had biochemical evidence of hepatocellular damage. In all patients a good correlation was found between serum ferritin levels and the amount of iron stored in the reticuloendothelial system. Six patients developed iron overload. Patients with secondary haemosiderosis were younger at the start of haemodialysis and received significantly more blood. Although not significant, more patients with haemochromatosis-associated alleles and bilateral nephrectomy had iron overload, and the duration of dialysis was obviously longer for overloaded patients (40 months versus 26 months). The patients with iron overload were treated with DFO. The data from all patients showed that DFO was ineffective when administered at a dose of 25 mg/kg during dialysis and that in individual patients changes in serum ferritin correlated with changes in the amount of blood transfusions administered.     

Acute renal failure after cardiopulmonary bypass in related to decreased serum ferritin levels.

Acute renal failure (ARF) requiring dialysis occurs in up to 4% of patients after cardiopulmonary bypass (CPB). CPB leads to the generation of intravascular free hemoglobin, resulting in increased endothelial and renal tubular cell free iron, which is associated with renal injury. Conversely, renoprotection is conferred by processes that upregulate heme and iron sequestration pathways, such as ferritin. This study evaluates the influence of free hemoglobin generation during CPB and the capacity to sequester free iron on the occurrence of post-CPB renal insufficiency. Thirty consecutive patients undergoing CPB were enrolled in the study. Serum creatinine, free hemoglobin, and ferritin were measured preoperatively, at the end of bypass, and 24 and 48 h after surgery. Renal injury, as determined by an increase in the serum creatinine of > or =25% (ARF) by 48 h after surgery, occurred in 40% (12 of 30) of patients, and dialysis was necessary in 6.6% (2 of 30). Free hemoglobin levels increased in all patients but did not correlate with postoperative ARF. However, patients with preoperative serum ferritin levels < or =130 microg/L, the median value for the group, had a sixfold greater likelihood of developing ARF compared to patients with levels above this value (P = 0.03). Lower serum ferritin levels appear to be associated with the development of ARF. Serum ferritin levels may signify intravascular as well as endothelial and renal epithelial cell ability to bind free iron generated during CPB-induced hemolysis, and thus may help provide information regarding the risk for ARF.     

Time-dependent associations between iron and mortality in hemodialysis patients

The independent association between the indices of iron stores or administered intravenous iron, both of which vary over time, and survival in patients who are on maintenance hemodialysis (MHD) is not clear. It was hypothesized that the observed associations between moderately high levels of three iron markers (serum ferritin, iron, and iron saturation ratio) or administered intravenous iron and all-cause and cardiovascular death is due to the time-varying confounding effect of malnutrition-inflammation-cachexia syndrome (MICS). Time-dependent Cox regression models were examined using prospectively collected data of the 2-yr (July 2001 to June 2003) historical cohort of 58,058 MHD patients from virtually all DaVita dialysis clinics in the United States. After time-dependent and multivariate adjustment for case mix, administered intravenous iron and erythropoietin doses, and available surrogates of MICS, serum ferritin levels between 200 and 1200 ng/ml (reference 100 to 199 ng/ml), serum iron levels between 60 and 120 microg/ml (reference 50 to 59 microg/ml), and iron saturation ratio between 30 and 50% (reference 45 to 50%) were associated with the lowest all-cause and cardiovascular death risks. Compared with those who did not receive intravenous iron, administered intravenous iron up to 400 mg/mo was associated with improved survival, whereas doses >400 mg/mo tended to be associated with higher death rates. The association between serum ferritin levels >800 ng/ml and mortality in MHD patients seems to be due mostly to the confounding effects of MICS. For ascertaining whether the observed associations between moderate doses of administered intravenous iron and improved survival are causal or due to selection bias by indication, clinical trials are warranted.     

Recombinant human erythropoietin and phlebotomy in the treatment of iron overload in chronic hemodialysis patients

Five long-term hemodialysis patients with clinical iron overload were treated with 300 U/kg of recombinant human erythropoietin (rHuEPO) intravenously (IV) after each hemodialysis. The patients were phlebotomized after each hemodialysis at any time the predialysis hematocrit was 35% or greater. Over a period of 1 year, the average phlebotomy rate varied from 0.5 to 1.1 U/wk with a mean phlebotomy rate of 45.8 +/- 5.6 U/yr (range, 27 to 57 U). The mean serum ferritin decreased from 8,412 +/- 1,599 micrograms/L (ng/mL) to 3,007 +/- 1,129 micrograms/L (ng/mL), and the mean iron removal over this period was 9.5 g. Liver iron deposition, as measured by density on computed tomographic (CT) scan, improved, while skin color lightened significantly. Patients tolerated phlebotomy with no major symptoms or complications and exhibited no change in the hemogram or serum chemistries. In patients with severe iron overload, changes in serum ferritin with erythropoietin treatment alone may not reflect true change in iron burden. Use of high-dose erythropoietin and phlebotomy is an effective and safe (at least for 1 year) method of reducing iron overload in long-term hemodialysis patients.     

Serum ferritin and survival of renal transplant recipients: a prospective 10-year cohort study

Increased serum ferritin is frequent in renal transplant recipients. This reflects iron overload due to blood transfusions given to treat renal anaemia. Previous studies suggested excess mortality in non-renal transplant recipients with iron overload. We hypothesized that serum ferritin levels above 1100 ng/ml may be associated with increased long-term mortality in renal transplant recipients. Twenty consecutive renal transplant recipients with high levels of serum ferritin and 20 renal transplant recipients with normal serum ferritin levels, matched for age and gender, were prospectively studied for 10 years. Nine patients (45%) with increased serum ferritin died during follow-up, compared to four controls (20%). Univariate and multivariate analysis identified multiple blood transfusions (>40 units) prior to transplantation as being associated with higher mortality in renal transplant recipients (risk ratio (RR): 3.1, confidence interval (CI): 1.1-9.2; P=0.03). These data suggest that serum ferritin levels above 1100 ng/ml due to multiple blood transfusions causing iron overload is a relevant factor that increases mortality.     

Intravenous ascorbic acid in hemodialysis patients with functional iron deficiency: a clinical trial

BACKGROUND: Hemodialysis (HD) patients with functional iron deficiency (FID) often develop resistance to recombinant human erythropoietin (rHuEpo). In these patients, iron therapy may be a hazard, leading to iron overload and consequently to hemosiderosis. Recent studies suggest that intravenous ascorbic acid (IVAA) may circumvent rHuEpo resistance. The aim of our study was to show the effects of IVAA on FID and whether this results in a better correction of anemia in HD patients with stable hemoglobin (Hb) concentration and FID. METHODS: Twenty-seven HD patients with serum ferritin >300 microg/l, transferrin saturation (TS) <20% and hemoglobin (Hb) <10 g/dL were selected andrandomly divided into two groups to enter a cross-over trial with IVAA. In group I IV vitamin C 500 mg was administered three times a week for three months and discontinued in the next three months of the study. Vitamin C was not given the first three months in group II (control group, first three months of the study), who then received 500 mg IV three times a week for the next three months. RESULTS: Hb and TS% significantly increased (baselines vs 3 months, Hb 9.2 +/- 0.2 vs 10.0 +/- 0.3 g/dL, TS% 17.5 +/- 0.6 vs 25.7 +/- 1.7, respectively p < 0.01 and p <0.001) in group I after three months; ferritin fell significantly from 572 +/- 40 to 398 +/- 55 microg/L (p<0.004). Ten patients completed the study: mean Hb and TS% fell significantly (3 months vs final, Hb 9.9 +/- 0.3 vs 8.9 +/- 0.2 g/dL, TS% 25.1 +/- 1.2 vs 19.1 +/- 1.1, respectively p < 0.01 and p <0.001), while mean ferritin did not change. Mean Hb, ferritin and TS% remained unchanged in group II after three months. Hb and TS% mean values rose significantly (3 months vs final, Hb 9.0 +/- 0.2 vs 9.9 +/- 0.2 g/dl, TS% 18.4 +/- 1.0 vs 27.0 +/- 1.0, respectively p < 0.005 and p <0.001), and ferritin markedly decreased from 450 +/- 50 to 206 +/- 24 microg/L (p < 0.001) at the end of the study. The rHuEpo dose was kept unchanged throughout the study. Differences were analyzed after three months. Mean Hb rose (0.8 +/- 0.2 g/dL) in group I but dropped (-0.1 +/- 0.1 g/dL) (p< 0.009) in group II. Ferritin dropped in both groups (group I vs group II, -173 + /-48 vs - 33 +/- 21 microg/L) (p < 0.01) while TS% increased (group I vs group II, 8.2 +/- 1.5 vs 0.4 +/- 0.7) (p < 0.001). CONCLUSION: IVAA may partially correct FID and consequently help rHuEpo hyporesponsive anemia.     

Intraperitoneal deferoxamine therapy for iron overload in children undergoing CAPD

We treated three children with renal failure and chronic iron overload with intraperitoneal deferoxamine therapy. Each child had an elevated serum ferritin level, a dense liver as measured by computerized tomography (Hounsfield Units) and one had dialysis related porphyria cutanea tarda. Deferoxamine therapy (10 to 17.5 mg/kg) was given in the overnight exchange for three to six months. Prior to therapy, iron was not detected in the dialysate; during the course of therapy, daily dialysate iron removal averaged 5652 micrograms, 2241 micrograms and 4028 micrograms in the three children. The serum ferritin level fell during the course of therapy in two children who were estimated to be in negative iron balance, and was unchanged in the third who was estimated to be in positive iron balance due to frequent transfusions. In 10 children with chronic renal failure, there was a linear correlation (r = 0.855; P less than 0.01) between the serum ferritin and the liver density, suggesting that an increased serum ferritin correlates with hepatic iron content. Interestingly, in each of the three children who received deferoxamine therapy, the liver density increased during therapy regardless of the estimated iron balance and the change in the serum ferritin level. We conclude that intraperitoneal deferoxamine therapy results in substantial iron losses in peritoneal dialysate, can result in negative iron balance but, in this study, did not result in lower liver iron content as measured by density on computerized tomography scan.     

Impairment of phagocyte oxidative metabolism in hemodialyzed patients with iron overload

In order to study the influence of iron overload on the polymorphonuclear leucocyte (PMN) metabolism of patients on chronic hemodialysis, generation of superoxide anion (O2-) by PMN in whole blood was compared in two groups of hemodialyzed patients: group A consisted of twenty-one individuals with serum ferritin levels above 1000 ng/ml and group B of nineteen individuals with serum ferritin levels below 1000 ng/ml. Whereas basal production of O2- was similar in the two groups (6.3 +/- 4.6 vs 11.5 +/- 8.3 nmoles O2- 10(6) granulocytes-1 15 min-1) (mean +/- s.e.m.), PMN response to opsonized zymosan was significantly lower in group A as compared with group B (86.5 +/- 6.3 vs 120.4 +/- 8.2 nmoles O2- 10(6) granulocytes-1 15 min-1) (p less than 0.01). Superoxide anion generation induced by the dialysis procedure was reduced in eight patients from group A (89.2 +/- 32.1) as compared with eight patients from group B (374.3 +/- 100.0 nmoles O2- 10(6) granulocytes-1 15 min-1) (p less than 0.05). These data suggest that iron overload may be involved in the impairment of neutrophil phagocytosis in patients on chronic hemodialysis.     

Dietary iron overload in southern African rural blacks

A survey conducted in rural southern African black subjects indicated that dietary iron overload remains a major health problem. A full blood count, erythrocyte sedimentation rate, serum concentrations of iron, total iron-binding capacity, ferritin, C-reactive protein (CRP), gamma-glutamyltransferase (GGT) and serological screening for hepatitis B and human immunodeficiency virus (HIV) infections were carried out in 370 subjects (214 inpatients and 156 ambulatory Mozambican refugees). The fact that the geometric mean (SD range) serum ferritin concentration was much higher in the male hospital patients than in subjects living in the community [1,581 micrograms/l (421-5,944 micrograms/l) and 448 micrograms/l (103-1,945 micrograms/l) respectively] suggested that dietary iron overload was not the only factor raising the serum ferritin concentration. The major additional factor appeared to be inflammation, since the geometric mean (SD range) serum CRP was significantly higher in male hospital patients [21 mg/l (8-53 mg/l)] than in subjects in the community [3 mg/l (1-5 mg)]. Alcohol ingestion, as judged by history and by serum GGT concentrations, was also associated with significantly raised serum ferritin concentrations. This finding was ascribed to the fact that traditional brews are not only associated with alcohol-induced hepatic damage but are also a very rich source of highly bio-available iron. The role of iron overload in the genesis of the raised serum ferritin concentrations are confirmed in the diagnostic liver biopsy study. The majority of biopsies showed heavy siderosis, with varying degrees of hepatic damage.(ABSTRACT TRUNCATED AT 250 WORDS)