Validation of serum ferritin values by magnetic susceptometry in predicting iron overload in dialysis patients

BACKGROUND: Guidelines for treating anemia in dialysis patients accept, as high-end range of serum ferritin useful to optimize erythropoietin therapy, values high as 500 to 900 microg/L, on the hypothesis that ferritin might be not representative of iron overload. METHODS: A superconducting quantum interference device (SQUID) was used to make direct noninvasive magnetic measurements of nonheme hepatic iron content in 40 dialysis patients treated with intravenous iron, and liver iron content was compared with biochemical markers of iron status. RESULTS: Only 12/40 (30%) patients showed normal hepatic iron content (SQUID <400 microg/g), while 32.5% had mild (400 to 1000 microg/g) and 37.5% severe (>1000 microg/g) iron overload, although 28/40 patients (70%) had serum ferritin below 500 microg/L. Among many parameters, hepatic iron content was only correlated with ferritin (r= 0.324, P= 0.04). The receiver operating characteristic (ROC) analysis showed the best specificity/sensitivity ratio to identify iron overload for ferritin >340 microg/L (W = 0.716). Multivariate logistic regression analysis demonstrated that an increase in serum ferritin of 100 microg/L and female gender were independent variables associated with moderate to severe hepatic iron overload: OR 1.71 (95% CI 1.10 to 2.67) and OR 10.68 (95% CI 1.81 to 63.15), respectively. CONCLUSION: Hepatic iron overload is frequent in dialysis patients with ferritin below currently proposed high-end ranges, and the diagnostic power of ferritin in indicating true iron stores is better than presumed. Safety concerns should prompt a reevaluation of acceptable iron parameters, focusing on potential gender-specific differences, to avoid potentially harmful iron overload in a majority of dialysis patients, mainly females.     

Comparative study of intravenous ascorbic acid versus low-dose desferroxamine in patients on hemodialysis with hyperferritinemia

BACKGROUND: In patients on hemodialysis (HD), parenteral iron improves the response to recombinant human erythropoietin (rhuEPO) therapy, but in some subjects it produces an iron overload, increasing their morbidity and mortality rates. In these cases, iron administration must be discontinued. This study aimed to investigate the efficiency of treatment with ascorbic acid (AA) or desferroxamine (DFO) to mobilize and reduce iron stores, and to determine the effect of these compounds on erythropoiesis. METHODS: We performed a prospective and randomized trial over 6 months, which included 27 patients with serum ferritin levels >800 ng/mL, TSAT >30% and stabilized hemoglobin (Hb) and rhuEPO doses. All patients had previously received parenteral iron (Ferlecit). Nine patients received 200 mg of intravenous (i.v.) AA 3 times/week and nine patients received 1 mg/Kg/week of DFO; the remaining nine patients were the control group. RESULTS: There were no significant differences in iron loss or mobilization due to dialysis. When Ferlecit was discontinued, functional iron did not vary and the epoetin resistance index (rhuEPO dose/Hb) was reduced by 21% in the i.v. AA group. In the DFO and control groups, functional iron levels fell. In the DFO group the epoetin resistance index increased by 20%, with no modifications in the control group. There was a positive correlation between transaminases and serum ferritin. CONCLUSIONS: In HD patients with an iron overload, neither i.v. AA administration or low-dose DFO increased iron mobilization or iron loss due to dialysis. I.v. AA administration allows elimination of iron from stores without any drop in the functional iron produced by discontinuing parenteral maintenance iron; it also improves the response to rhuEPO. DFO did not elicit any positive effects on erythropoiesis.     

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.     

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.     

Association between serum ferritin and measures of inflammation, nutrition and iron in haemodialysis patients.

BACKGROUND: Serum ferritin is a frequently used marker of iron status in dialysis patients. Iron administration is to be withheld for ferritin values >800 ng/ml according to K/DOQI guidelines. We hypothesized that such non-iron-related factors as elements of the malnutrition-inflammation complex syndrome (MICS) may increase serum ferritin concentration independently of iron status. METHODS: We studied 82 prevalent maintenance haemodialysis (MHD) patients (including 43 men), aged 55.7 +/- 15.3 years. The inflammatory and nutritional status was evaluated by serum C-reactive protein (CRP), Subjective Global Assessment (SGA) and its newer, fully quantitative versions, i.e. Dialysis Malnutrition Score (DMS) and Malnutrition-Inflammation Score (MIS). RESULTS: All but six patients had been on maintenance doses of intravenous iron dextran (between 100 and 200 mg/month) during the 10 weeks prior to the measurements. Serum ferritin levels were increased across SGA categories: (ANOVA P-value 0.03). Both unadjusted and multivariate adjusted correlation coefficients (r) for serum ferritin and CRP vs pertinent values were statistically significant for DMS and MIS and some other measures of nutritional status and iron indices. After deleting 10 MHD patients with either iron deficiency (ferritin <200 ng/ml) or iron overload (ferritin >2000 ng/ml), in the remaining 72 MHD patients both bivariate and multivariate correlations were much stronger and statistically significant (r = -0.33 and -0.29, respectively, P < 0.01). A multivariate model showed simultaneous, significant correlations between serum ferritin and both markers of inflammation and iron status independent of each other. After dividing the 72 MHD patients into two groups of serum ferritin based on a K/DOQI recommended serum ferritin cut-off of 800 ng/ml, the MIS and logarithm of serum CRP were significantly higher in the higher ferritin group. CONCLUSIONS: Serum ferritin values in the range of 200-2000 ng/ml may be increased due to non-iron-related factors including elements of MICS.     

Intermittent versus maintenance iron therapy in children on hemodialysis: a randomized study

In patients with renal anemia, iron therapy can be administered intermittently or regularly at a low dose. We performed a randomized clinical trial in pediatric patients with end-stage renal failure on hemodialysis and absolute or functional iron deficiency. The study group received maintenance iron therapy according to the ferritin serum levels and the control group received intermittent 10-weekly doses. Success was defined as stabilization of ferritin levels between 100 and 800 g/l and transferrin saturation (TSAT) between 20% and 50%, in addition to an increase in the hemoglobin level. The major reason for exclusion was iron overload. The study group received 6 mg/kg per month of parenteral iron [95% confidence interval (CI) 3.3–8.8] and the control group 14.4 mg/kg per month (95% CI 12–16.8) (P<0.001). After 4 months of treatment, ferritin levels increased to 66 g/l (95% CI 69–200) in the study group and to 334 g/l (95% CI 145–522) in the control group (P=0.009). Maintenance therapy and intermittent weekly doses were successful in 73% and 38%, respectively. After 3 months of treatment, hemoglobin levels increased to 10 g/dl, with no difference between the groups. However, in the control group the increase in hemoglobin levels was unsustained, and 3 patients needed transfusion. Patients in the control group had a higher risk of iron overload than patients in the study group (70% vs. 19%). Thus, the regimen based on assessment of serum ferritin levels was more efficient than the intermittent regimen because it increased and maintained the hemoglobin levels with lower iron doses and a lower risk of iron overload.     

Continuous intravenous sodium ferric gluconate improves efficacy in the maintenance phase of EPOrHu administration in hemodialysis patients

Although intravenous iron has proved to optimize the efficacy of EPOrHu in hemodialysis patients, hitherto no consensus exists with respect to the best regimen of intravenous iron administration. We started a prospective randomized study in 26 patients undergoing chronic hemodialysis who had adequate iron metabolism indices (serum ferritin >100 microg/l; %TSAT >20%; %HypoE <10% and CHr >26 pg) and were in the maintenance phase of EPOrHu administration (target hemoglobin obtained >10 g/dl). All patients were receiving sodium ferric gluconate (Ferrlecit) intermittently prior to the study and after a 1-month wash-out period where iron was not administered patients were randomized to receive the same previous dose of intravenous iron either in a continuous (6.25-21.3 mg in every hemodialysis session) or an intermittent regimen (62.5 mg every 1-4 weeks, not modifying the previous schedule of administration). At 16 weeks, the continuous group showed a significant increment in serum Hb (11.83 +/- 1.12 g/dl) with respect to baseline (10.96 +/- 1.31 g/dl) (p < 0.05), whereas no differences were obtained in intermittent group (baseline: 11.16 +/- 1.03 g/dl; 16 weeks: 11.14 +/- 0.90 g/dl, NS). In contrast with the intermittent group, serum ferritin increased significantly in the continuous group (16 weeks: 508 +/- 157 microg/l; baseline: 368 +/- 56 microg/l; p < 0.05), whereas %TSAT and CHr did not modified during the study in both groups. %HypoE increased significantly with respect to baseline values in the continuous group (p < 0.05) and close to significantly different in the intermittent group (p = 0.06). Our study suggests that hemodialysis patients in the maintenance phase of EPOrHu administration would obtain further benefit in terms of serum hemoglobin level with a continuous intravenous serum ferric gluconate regimen, at least in the short term.     

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.     

Upper limit of serum ferritin: misinterpretation of the 2006 KDOQI anemia guidelines

Intravenous iron treatment in hemodialysis patients improves response to recombinant human erythropoietin and facilitates achievement of targets for hemoglobin and hematocrit. Excessive treatment, however, could expose patients to risks related to iron overload and oxidative stress. Therefore, international treatment guidelines generally recommend that intravenous (i.v.) iron be discontinued when serum ferritin is >500-1,000 ng/ml. In the current review, relevant issues that inform decisions as to what levels of serum ferritin should be used as the upper limit for treatment are considered. A conclusion is reached that the current published literature is inadequate for developing evidence-based guidelines on this issue. Instead, clinical judgment is critical to properly weigh risks and benefits of i.v. iron treatment, and to determine whether iron treatment is appropriate for a given patient with higher levels of iron tests.     

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.     

A prospective crossover trial comparing intermittent intravenous and continuous oral iron supplements in peritoneal dialysis patients.

BACKGROUND: Concomitant iron supplementation is required in the great majority of erythropoietin (Epo)-treated patients with end-stage renal failure. Intravenous (i.v.) iron supplementation has been demonstrated to be superior to oral iron therapy in Epo-treated haemodialysis patients, but comparative data in iron-replete peritoneal dialysis (PD) patients are lacking. METHODS: A 12-month, prospective, crossover trial comparing oral and i.v. iron supplementation was conducted in all Princess Alexandra Hospital PD patients who were on a stable dose of Epo, had no identifiable cause of impaired haemopoiesis other than uraemia, and had normal iron stores (transferrin saturation >20% and serum ferritin 100-500 mg/l). Patients received daily oral iron supplements (210 mg elemental iron per day) for 4 months followed by intermittent, outpatient i.v. iron infusions (200 mg every 2 months) for 4 months, followed by a further 4 months of oral iron. Haemoglobin levels and body iron stores were measured monthly. RESULTS: Twenty-eight individuals were entered into the study and 16 patients completed 12 months of follow-up. Using repeated-measures analysis of variance, haemoglobin concentrations increased significantly during the i.v. phase (108+/-3 to 114+/-3 g/l) compared with each of the oral phases (109+/-3 to 108+/-3 g/l and 114+/-3 to 107+/-4 g/l, P<0.05). Similar patterns were seen for both percentage transferrin saturation (23.8+/-2.3 to 30.8+/-3.0%, 24.8+/-2.1 to 23.8+/-2.3%, and 30.8+/-3.0 to 26.8+/-2.1%, respectively, P<0.05) and ferritin (385+/-47 to 544+/-103 mg/l, 317+/-46 to 385+/-47 mg/l, 544+/-103 to 463+/-50 mg/l, respectively, P=0.10). No significant changes in Epo dosages were observed throughout the study. I.v. iron supplementation was associated with a much lower incidence of gastrointestinal disturbances (11 vs 46%, P<0.05), but exceeded the cost of oral iron treatment by 6.5-fold. CONCLUSIONS: Two-monthly i.v. iron infusions represent a practical alternative to oral iron and can be safely administered to PD patients in an outpatient setting. Compared with daily oral therapy, 2-monthly i.v. iron supplementation in PD patients was better tolerated and resulted in superior haemoglobin levels and body iron stores.     

Importance of iron supply for erythropoietin therapy

BACKGROUND.: rHuEpo and iron therapy corrects renal anaemia. However, dosage,route of administration, and monitoring of iron and rHuEpo therapyin uraemic patients remains controversial. METHODS.: Therefore a 22-month i.v. iron substitution trial, subdividedinto four study periods, was initiated in 64 iron-depleted chronichaemodialysis (HD) patients receiving i.v. rHuEpo therapy. Withinthe first period (6 months) patients were treated with high-doseiron (100mg at the end of HD treatment, mean cumulative i.v.iron saccharate dosage was 2538±810 mg per patient) inorder to replete the iron stores. During the 2nd period (6 months)the available iron pool was maintained with low-dose iron byadministration of 10, 20, or 40 mg iron at each HD, dependingon haemoglobin, serum ferritin and transferrin saturation levels.During the 3rd period (4 months), the iron-replete patientswere randomized to i.v. or s.c. route of rHuEpo administration.During the 4th period (3 months) iron substitution was omittedto exclude severe iron overload. RESULTS.: In the first study period, high-dose iron therapy dramaticallyreduced the weekly rHuEpo requirement by 70% of the initialdose (from 217±179 to 62.6±70.2 U/kg/week). Inthe 2nd period iron storage pools were easily maintained. Serumferritin and transferrin saturation levels remained stable duringthis study period. Randomization for thrice-weekly i.v. or s.c.administration of rHuEpo in the 3rd study period revealed comparableefficacy for both administration routes in iron-replete patients.In well-nourished patients (serum albumin >40 g/1) withouthyperparathyroidism (parathyroid hormone levels < 100 pg/ml),50–60 U/kg/week rHuEpo were required in contrast to >100 U/kg/week in patients with hyperparathyroidism. In the 4thstudy period, withdrawal of iron administration led to a rapiddecrease of serum ferritin and transferrin saturation levels,indicating the absence of severe iron overload. CONCLUSIONS.: Long-term thrice-weekly i.v. low-dose iron therapy (10–20mg per HD treatment) proved to be a very effective, economicaland safe treatment schedule for iron-replete HD patients. Intravenousand s.c. rHuEpo therapy was equally efficacious in iron-replete,well-nourished patients. HD patients with increased parathyroidhormone levels require significantly more rHuEpo than HD patientswith parathyroid hormone levels values <100 pg/ml).     

Monitoring of iron requirements in renal patients on erythropoietin

We studied 38 patients (9 haemodialysis, 18 peritoneal dialysis,11 advanced renal failure) over the first 12 weeks of erythropoietintherapy. In 14 iron-overloaded patients (ferritin >500 µg/l)the haemoglobin (±SEM) increased from 6.74±0.27to 9.85±0.36 g/dl (P<0.0001) entirely by mobilizingiron reserves (reduced from 1,220±73 to 739±111mg, P<0.0001). In the 24 non-overloaded patients (ferritin<500µg/l) the haemoglobin rose similarly from 7.04±0.18to 10.70±0.36 g/dl (P<0.0001), partly from iron reserves(depleted from 200±74 to –44±77mg, P=0.016)and partly from oral iron supplements (305±110 mg). Inthe overloaded patients the ferritin declined from 1057 µg/l(geometric mean, range 504–3699) to 317 µg/l (42–1505,P<0.0001). In the non-overloaded patients it declined from82 µg/l (8–461) to 45 µg/l (5–379, P=0.016).The transferrin saturation (TS) in the overloaded patients appearedto decline from 38.3±7.2% to 24.0±3.7% but thiswas not statistically significant. In the non-overloaded theTS was unchanged (23.3±2.4 before and 28.1±3.6%after treatment). Considering all 38 patients together, thehaemoglobin correlated negatively with the ferritin (r=0.3731,P<0.001) but not with the TS. The TS correlated with theserum ferritin initially (r=0.75, P<0.001) but not afterthe first 4 weeks. At 12 weeks, eight of 15 patients with irondeficiency (ferritin<50 µg/l) had a TS >20%, whereastwo of five patients with persistent iron overload (ferritin>500 µg/l) had a TS <20%. We conclude that (a) inpatients with iron overload, stored iron is utilizable for erythropoiesis;(b) oral iron supplements are necessary and sufficient for mostpatients without iron overload; (c) the serum ferritin is abetter indicator of iron status than the TS for renal patientson erythropoietin.     

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      

Experience of iron saccharate supplementation in haemodialysis patients treated with erythropoietin

We assessed the efficacy of intravenous (i.v.) iron saccharate (VENOFER) vs oral iron supplementation in haemodialysis patients treated with low-dose erythropoietin (EPO). Twenty haemodialysis patients with serum ferritin >200 ng/mL and transferrin saturation >30% were assigned to one of the two groups. In Group 1, 10 were given i.v. iron saccharate (100 mg i.v. twice weekly) post dialysis. In Group 2, oral ferrous sulphate 200 mg was given thrice daily. In both groups, subcutaneous EPO 25 units/kg body weight (BW) was started simultaneously, twice weekly. After 3 months (study completion) the mean haemoglobin and haematocrit was significantly increased in Group 1 than in Group 2 (Hb 11.60±0.64 G/dL vs 10.5 G/dL±1.14 P <0.01). The final mean EPO dose was 25% lower in Group 1 than in Group 2 (3400±1356 U/week vs 4600±1356 U/week P =0.10) and the mean serum ferritin was higher in the i.v. iron group than the oral group (671 ng/mL±388 vs 367 ng/mL±238 P =NS). The same was also observed with transferrin saturation (44.6%±19.8 in Group 1 vs. 29%±11.0 in Group 2 P =NS). No adverse effects were seen during the study. In conclusion, we observed that regular use of i.v. iron had a significantly enhanced haemoglobin response, better maintained serum ferritin and lower EPO dosage requirement than the oral iron group.     

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.     

Treatment of iron deficiency in predialysis state by low molecular weight iron dextran high doses intravenously

Anemia is a common complication of chronic kidney disease (CKD) in predialysis stage. Iron deficiency is more common than in normal patients and plays a key role in the genesis of anemia. Its correction avoids the use of erythropoiesis stimulating agents (ESA) or reduces their dosage. Treatment with oral iron is often poorly tolerated and ineffective, necessitating the use of intravenous iron. New forms of injectable iron allow the use of high doses and correct iron deficiency in a single administration with consequent preservation of venous capital and lower costs. We studied the effectiveness of iron dextran of low molecular weight (LMWID) in high doses to correct iron deficiency and treat anemia in predialysis CKD patients. Twenty-nine doses of 500 to 1600 mg were administered to 25 patients followed for CKD (GFR between 60 and 10 ml/min per 1.73 m²), selected on biological criteria of iron deficiency defined by a ratio of transferrin saturation (TSAT) < 20% and/or serum ferritin of less than 100 μg/L. Patients received treatment by ESA in 16 cases out of 29. One month after treatment, hemoglobin (Hb) increased significantly (11.4 ± 1.6 vs 10.4 ± 1.4 g/dL, P = 0.0003) along with a significant increase in TSAT (21.3 ± 7.3 vs 13.3 ± 3.8%, P = 0.000003) and serum ferritin (286 ± 253 vs 91 ± 60 μg/L, P = 0.00005). Six patients had a serum ferritin greater than 500 μg/L after treatment, which may put them at risk of iron overload. Their serum ferritin was higher than the rest of the population before treatment, while the TSAT was no different, reflecting a functional deficiency. Their hemoglobin did not increase after treatment in contrast to the rest of the population suggesting the unavailability of iron for erythropoiesis with accumulation in the reticuloendothelial system. Renal function did not change significantly and there were no cases of acute renal failure. No immediate side effect was observed. Three patients presented delayed reactions to such self-limiting myalgia and arthralgia. No venous inflammatory reaction was noted. The administration of high doses of LMWID is effective in treating anemia of CKD in the predialysis stage with a satisfactory tolerance, without affecting kidney function and helps preserve the venous capital. It should be reserved for patients whose serum ferritin is less than or equal to 150 μg/L.     

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 an 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 ⩽5.0% in 28 patients, >5.0 and ⩽10.0% in 25 patients and >10.0% in 17 patients, suggesting functional iron deficiency in at least 42 patients, suggesting functional iron deficiency in at least 42 patients. Nine patients had serum ferritin values <100 &mgr;g/l; 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 ⩽5.0%, by 11.3% in patients with hypochromic RBC>5.0 and ⩽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 &mgr;g/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 &mgr;g/l after iron supplementation. We found that the percentage of hypochromic RBC is the most sensitive parameter for predicting hyporesponsiveness in CPR-positive patients. Finally our data indicate that 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. Conclusions. Two different aspectsshould 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 no i.v. iron should be given and to monitor this type of therapy in HD patients.     

Iron Overload: Predictor of Adverse Outcome in Hematopoietic Stem Cell Transplantation

Introduction

Iron overload is an important problem in candidates for and survivors of hematopoietic stem cell transplantation (HSCT), and affects long-term outcome and survival. The objective of the present study was to determine the effect of iron overload on early toxic or infectious complications and survival.

Patients and Methods

We retrospectively reviewed the medical records for 250 adult patients (162 men and 88 women; median [range] age, 34 [16-71] years who underwent HSCT between September 2003 and August 2008. The HSCT grafts were autologous in 102 patients, and allogeneic in 148.

Results

Follow-up was 315 (1-1809) days. Mean (SD) pre-HSCT serum ferritin concentration was 1402.6 (5016.2) ng/mL in the entire group, 647.6 (1204.3 ng/mL in autologous recipients, and 1410.6 (2410.4) ng/mL in allogeneic recipients. Twenty-eight autologous graft recipients (27.4%) and 102 allogeneic recipients (68.9%) demonstrated serum ferritin concentrations of 500 ng/mL or greater, and were classified as the high-ferritin group. High ferritin concentrations were significantly associated with toxic or infectious complications including mucositis, fungal infections, pneumonia, and sinusoidal obstruction syndrome in the early post-HSCT setting. A significant effect of pre-HSCT ferritin concentration on overall survival and transplant-related mortality was observed. The effect of pre-HSCT ferritin on survival was independent of the comorbidity index at Cox regression analysis. In the entire study population, the probability of survival was significantly lower when ferritin concentration was greater than 500 ng/mL.

Conclusion

Transplant-related mortality has decreased substantially with the development of supportive treatments. Pretransplantation risk assessment and risk-adapted strategies such as decreasing iron overload might further improve transplant-related complications.     

Experience of iron saccharate supplementation in haemodialysis patients treated with erythropoietin

SUMMARY: We assessed the efficacy of intravenous (i.v.) iron saccharate (VENOFER) vs oral iron supplementation in haemodialysis patients treated with low-dose erythropoietin (EPO). Twenty haemodialysis patients with serum ferritin >200 ng/mL and transferrin saturation >30% were assigned to one of the two groups. In Group 1, 10 were given i.v. iron saccharate (100 mg i.v. twice weekly) post dialysis. In Group 2, oral ferrous sulphate 200 mg was given thrice daily. In both groups, subcutaneous EPO 25 units/kg body weight (BW) was started simultaneously, twice weekly. After 3 months (study completion) the mean haemoglobin and haematocrit was significantly increased in Group 1 than in Group 2 (Hb 11.60 ± 0.64 G/ dL vs 10.5 G/dL ± 1.14 P <0.01). the final mean EPO dose was 25% lower in Group 1 than in Group 2 (3400 ± 1356 U/week vs 4600 ± 1356 U/week P =0.10) and the mean serum ferritin was higher in the i.v. iron group than the oral group (671 ng/mL ± 388 vs 367 ng/mL ± 238 P =NS). the same was also observed with transferrin saturation (44.6%± 19.8 in Group 1 vs. 29%± 11.0 in Group 2 P =NS). No adverse effects were seen during the study. In conclusion, we observed that regular use of i.v. iron had a significantly enhanced haemoglobin response, better maintained serum ferritin and lower EPO dosage requirement than the oral iron group.