Iron supplementation in adolescent hemodialysis patients

AIMS: Iron supplementation is necessary in children on hemodialysis, but the optimal protocol remains unknown. We studied the effects of changing our unit's protocol from oral iron with periodic doses of parenteral iron dextran to routine administration of parenteral sodium ferric gluconate on anemia and iron parameters. METHODS: We followed seven hemodialysis patients aged 15 20 years (mean 17 years). Hemoglobin, hematocrit, serum iron, transferrin saturation, ferritin, erythropoietin dose, total elemental iron dose and total iron cost for the six months prior to the protocol change were compared to the same variables during the six months following the change. RESULTS: There was no statistically significant difference between the doses of parenteral iron between the two protocols; however, the total dose of elemental iron administered in the oral iron plus iron dextran protocol was greater than in the sodium ferric gluconate protocol (19.6+/-13.1 (mean+/-SD) mg/kg/week versus 1.1+/-0.3 mg/kg/week; p = 0.03). Both protocols had equivalent efficacy with respect to hemoglobin, ferritin and other measures of iron stores. On the other hand, the costs of sodium ferric gluconate were significantly higher than those of oral iron plus intermittent iron dextran (157.75+/-45.94 $/patient/month versus 52.08+/-49.88 $/patient/month; p = 0.01). CONCLUSIONS: Routine administration of sodium ferric gluconate is equivalent if not superior to use of oral iron plus iron dextran for maintenance of iron stores in adolescents on hemodialysis, but more expensive.     

A trial of two iron-dextran infusion regimens in chronic hemodialysis patients

AIM: To test the ability to elicit a hemoglobin (Hb) response in patients on chronic hemodialysis, we prospectively compared two regimens of iron dextran administration, 100 mg once weekly (QW) or 100 mg once every dialysis (QD), both given for 10 doses. PATIENTS AND METHODS: Twenty-three consecutive patients on chronic hemodialysis received iron dextran intravenously if they had absolute or functional iron deficiency. There was no difference in the Hb response between regimens. RESULTS: Both groups had a significant increase in Hb from 10.5+/-1.5 g/dl at baseline, to 11.1+/-1.7 g/dl at 1 month, 1.4+/-2.1 g/dl at 2 months and 11.6+/-1.9 g/dl at 3 months. The increment in Hb at 1 month was similar (QD 0.62+/-1.245 g/dl vs. QW 0.64+/-1.464 g/dl) between the two groups despite a large difference in the amount of iron received. Serum ferritin, transferrin saturations or epoetin dose did not change significantly. At the end of 3 months 12 patients did not need further iron therapy as judged by the serological markers of iron stores. Of these 12 patients, 3 had serum ferritins of > 1,000 ng/ml. Weekly dosing of iron was associated with more medication errors than dosing every dialysis. Baseline iron stores could not predict the responsiveness to intravenous iron therapy as judged by an increase in Hb concentration at 1 month or at 3 months. CONCLUSION: This study confirms the efficacy of 1,000 mg of intravenous iron administered over a 3-month period in patients with functional iron deficiency. It underscores the importance of careful monitoring of iron stores and highlights the need for developing better parameters of functional iron stores in hemodialysis patients.     

Serum ferritin as a guide for iron stores in chronic hemodialysis patients

The serum ferritin (SF) level was measured in 58 chronic hemodialysis (CHD) patients (46 living and 12 deceased subjects) and compared to bone marrow iron concentrations, cytological bone marrow iron stores (BMIS), and histological BMIS. In the 12 deceased subjects, liver iron concentrations, histological liver parenchymal, and Kupffer cell iron stores were also studied. The mean SF level of the whole group was 302 +/- 251 ng/ml (mean +/- SD). No close relationship was found between transferrin saturation and cytological BMIS. A high correlation was found between SF level and cytological BMIS (Spearman rank rs = 0.74). In the deceased CHD patients a close correlation was observed between histological parenchymal liver iron stores and histological Kupffer cell iron stores, but not between liver and bone marrow iron stores. A good correlation was found between SF levels and liver iron concentrations. It is concluded that in CHD patients SF levels are higher than in healthy controls, even in the absence of iron therapy (except in the form of blood transfusions); in some of these patients iron is disproportionately stored in the bone marrow and the liver. Although the level of BMIS cannot be estimated unequivocally from an SF measurement in every CHD patient, SF levels provide useful estimates of BMIS.     

A randomized trial of iron deficiency testing strategies in hemodialysis patients.

BACKGROUND: Diagnosis of iron deficiency in hemodialysis patients is limited by the inaccuracy of commonly used tests. Reticulocyte hemoglobin content (CHr) is a test that has shown promise for improved diagnosis in preliminary studies. The purpose of this study was to compare iron management guided by serum ferritin and transferrin saturation to management guided by CHr. METHODS: A total of 157 hemodialysis patients from three centers were randomized to iron management based on (group 1) serum ferritin and transferrin saturation, or (group 2) CHr. Patients were followed for six months. Treatment with intravenous iron dextran, 100 mg for 10 consecutive treatments was initiated if (group 1) serum ferritin <100 ng/mL or transferrin saturation <20%, or (group 2) CHr <29 pg. RESULTS: There was no significant difference between groups in the final mean hematocrit or epoetin dose. The mean weekly dose of iron dextran was 47.7 +/- 35.5 mg in group 1 compared to 22.9 +/- 20.5 mg in group 2 (P = 0.02). The final mean serum ferritin was 399.5 +/- 247.6 ng/mL in group 1 compared to 304.7 +/- 290.6 ng/mL in group 2 (P < 0.05). There was no significant difference in final TSAT or CHr. Coefficient of variation was significantly lower for CHr than serum ferritin and transferrin saturation (3.4% vs. 43.6% and 39.5%, respectively). CONCLUSIONS: CHr is a markedly more stable analyte than serum ferritin or transferrin saturation, and iron management based on CHr results in similar hematocrit and epoetin dosing while significantly reducing IV iron exposure.     

Therapy of iron deficiency anemia in patients on maintenance dialysis.

A controlled, prospective study compared the effectiveness of oral ferrous sulfate to intravenous iron dextran, each with and without concurrent intramuscular androgen for therapy of iron deficiency anemia in patients with chronic renal failure treated with maintenance hemodialysis. During the 12-week period of therapy, the patients who received oral ferrous sulfate and androgens showed an increment in their mean hematocrit of 16.3% and those who received oral ferrous sulfate alone had an increase of 8.3%. Patients treated with intravenous iron dextran androgens showed an increment in their mean hematocrit of 9.4% and those given iron dextran alone showed an increase of 3.5%. Serum ferritin levels increased with iron repletion but correlated inversely with the erythropoietic response. The serum ferritin assay provides a simple and reliable method to demonstrate iron repletion, and oral ferrous sulfate is the preferred method of iron repletion in compliant patients.     

Dialysate iron therapy: infusion of soluble ferric pyrophosphate via the dialysate during hemodialysis

BACKGROUND: Soluble iron salts are toxic for parenteral administration because free iron catalyzes free radical generation. Pyrophosphate strongly complexes iron and enhances iron transport between transferrin, ferritin, and tissues. Hemodialysis patients need iron to replenish ongoing losses. We evaluated the short-term safety and efficacy of infusing soluble ferric pyrophosphate by dialysate. METHODS: Maintenance hemodialysis patients receiving erythropoietin were stabilized on regular doses of intravenous (i.v.) iron dextran after oral iron supplements were discontinued. During the treatment phase, 10 patients received ferric pyrophosphate via hemodialysis as monthly dialysate iron concentrations were progressively increased from 2, 4, 8, to 12 micrograms/dl and were then sustained for two additional months at 12 micrograms/dl (dialysate iron group); 11 control patients were continued on i.v. iron dextran (i.v. iron group). RESULTS: Hemoglobin, serum iron parameters, and the erythropoietin dose did not change significantly from month 0 to month 6, both within and between the two groups. The weekly dose of i.v. iron (mean +/- SD) needed to maintain iron balance during month 6 was 56 +/- 37 mg in the i.v. iron group compared with 10 +/- 23 mg in the dialysate iron group (P = 0.001). Intravenous iron was required by all 11 patients in the i.v. iron group compared with only 2 of the 10 patients receiving 12 micrograms/dl dialysate iron. The incidence of adverse effects was similar in both groups. CONCLUSIONS: Slow infusion of soluble iron pyrophosphate by hemodialysis may be a safe and effective alternative to the i.v. administration of colloidal iron dextran in maintenance hemodialysis patients.     

Low-dose intravenous iron administration in chronic hemodialysis patients treated with recombinant human erythropoietin

We conducted a prospective study to determine the effect of intravenous low-dose iron administration in chronic hemodialysis patients treated with recombinant human erythropoietin (rHuEPO). Sixteen hemodialysis patients (8 males and 8 females; mean age 63.1+/-9.8 years) on maintenance rHuEPO therapy were included in the study. Patients with <100 ng/ml of ferritin received 50 mg iron during every hemodialysis session. Patients with 100-200 ng/ml of ferritin were given 50 mg iron fortnightly. Iron was not supplemented in patients with ferritin levels >200 ng/ml. Mean hematocrit, serum iron levels and transferrin saturations were significantly higher at 6 and 12 months. There was a significant reduction in weekly rHuEPO doses between the start and the 6th and 12th months. Our study shows intravenous iron administration of 100 mg/month may be sufficient to achieve a satisfactory iron status in dialysis patients on maintenance rHuEPO therapy.     

Effect of an intravenous iron dextran regimen on iron stores, hemoglobin, and erythropoietin requirements in hemodialysis patients

Iron deficiency is a common cause of delayed or diminished response to erythropoietin (EPO) in hemodialysis patients. Although oral iron is often prescribed to replete iron stores, this approach to iron supplementation may not be adequate with chronic EPO therapy. Intravenous (IV) iron dextran may be an effective alternative approach to replete iron stores and may facilitate more cost-effective use of EPO. The purpose of this study was to evaluate an IV iron dextran regimen that consisted of a loading dose phase followed by monthly maintenance doses of iron dextran. The effect of this regimen on iron stores, hemoglobin, and EPO doses was evaluated. This was an open prospective study in adult hemodialysis patients who were iron deficient as defined by a serum ferritin less than 100 ng/mL or transferrin saturation (TSAT) of less than 20%. Patients were loaded with 1 g iron dextran in five divided doses and then received monthly maintenance doses of 100 mg for the 4-month study period. Values of serum ferritin, TSAT, hemoglobin, and EPO dose were followed for the 4-month study period. Thirty hemodialysis patients receiving EPO were identified as being iron deficient and were enrolled in the study. The mean serum ferritin increased significantly from 49 ng/mL at baseline to 225 ng/mL at the end of the study period (P < 0.0001). Mean TSAT also increased significantly from 27% to 33% (P = 0.002). Values for hemoglobin did not change significantly during the study period; however, there was a significant reduction in EPO dose from a mean baseline dose of 112 U/kg/wk to 88 U/kg/wk at the end of the study period (P = 0.009). Seventeen patients experienced an increase in hemoglobin or a decrease in EPO dose. Economic analysis showed that approximately $580 (Cdn) per patient per year could be saved by use of IV iron dextran. The administration of the IV iron dextran regimen in the iron-deficient hemodialysis population was effective at repleting and maintaining iron stores and reducing EPO use.     

Effects of testosterone and venesection on spinal and peripheral bone mineral in six hypogonadal men with hemochromatosis

To measure the effect of testosterone replacement and venesection on spinal and peripheral bone mineral we prospectively studied six hypogonadal men and six eugonadal men with idiopathic hemochromatosis for 24 months. Venesections were performed every week on all patients, and intramuscular injections of testosterone were administered every 3 weeks to the hypogonadal men only. Bone mineral was measured by quantitative computed tomography in the spine and by single-photon absorptiometry in the forearm. During the 24 month period of observation serum testosterone concentrations and serum ferritin levels became normal. In the hypogonadal men mean lumbar spine bone mineral increased by 13.1 +/- 4.9% (95% CI, 0.5-25.6) and mean forearm bone mineral increased by 4.7 +/- 3.8% (95% CI, -5.1 to 14.6). In contrast in the eugonadal men treated over the same period, mean lumbar spine bone mineral decreased by 3.5 +/- 2.8% (95% CI, -10.9 to 3.8, P less than 0.01) and mean forearm bone mineral remained virtually unchanged (0.07 +/- 0.9%; 95% CI, -1.7 to 3.1, P less than 0.05). These data suggest that bone mineral increases in the lumbar spine and in the forearm in hypogonadal men with hemochromatosis treated by testosterone replacement and venesection.     

Total dose infusion iron dextran therapy in predialysis chronic renal failure patients

BACKGROUND: Intravenous iron therapy is now the standard modality of iron supplementation in hemodialysis patients, but its role in predialysis chronic renal failure patients is less well established. The efficacy and safety of intravenous iron dextran as a total dose infusion in predialysis chronic renal failure patients, not receiving erythropoietin was assessed in this study. METHODS: Fifty-six predialysis chronic renal failure patients with anemia, not receiving erythropoietin were included in the study, after obtaining informed consent. Hemoglobin, serum creatinine, creatinine clearance rate and serum ferritin were assessed in all the patients at baseline. Iron dextran in a dose of 1 g dissolved in 500 mL normal saline was administered to all patients as a total dose infusion over 6 h after a prior test dose. Patients were kept in hospital under observation for at least 24 h. All the parameters were repeated in all the patients at 12 weeks and in 21 patients at 1 year. RESULTS: The mean hemoglobin (g/dL) in the patients at baseline and at 12 weeks was 8.28 +/- 0.57 and 9.22 +/- 0.44 respectively (p < 0.001). The mean serum ferritin (ng/mL) increased from 29.73 +/- 9.38 at baseline to 218.43 +/- 15.66 at 12 weeks (p < 0.00001). The mean ferritin value in the 21 patients at 1 year was 136.5 +/- 23.4 (p < 0.01). There were no major adverse events and only minor side effects were observed in 4.9% patients. CONCLUSION: Iron dextran as a total dose infusion corrects anemia in predialysis patients and is an effective method to replenish iron stores. The effect on serum ferritin are evident even at 1 year after the total dose infusion.     

Prospective evaluation of an anemia treatment algorithm in hemodialysis patients

Current guidelines recommend maintaining the hematocrits of chronic hemodialysis patients in the low to mid-30s. Maintaining patients' hematocrits within a narrow range requires frequent monitoring of their hematocrits and iron studies and periodic adjustment of erythropoietin doses and administration of intravenous iron. We designed a simple anemia treatment algorithm to streamline the management of anemia in hemodialysis patients. The protocol required formal monthly decisions about the administration of intravenous iron or changes in erythropoietin dose. This algorithm was implemented by dialysis nurses and evaluated prospectively for 6 months in a single dialysis unit (30 patients). The proportion of patients whose hematocrits were within the desired target (31% to 35%) increased from 27% at baseline to 61% during months 4 through 6 of the algorithm. Conversely, the proportion of patients whose hematocrit values were below the target decreased from 46% at baseline to 18% during months 4 through 6 of the algorithm (P=0.004). The percentage of patients whose hematocrit values were above the target did not increase. The proportion of patients whose transferrin saturation was less than 18% decreased from 47% at baseline to 20% during months 4 through 6 of the algorithm (P=0.04). The weekly erythropoietin dose administered decreased from 11,200+/-1,400 units at baseline to 9,400+/-1,200 units in month 6 of the algorithm (P=0.06). We conclude that a simple anemia treatment algorithm implemented by dialysis nurses is feasible and efficacious and may increase the proportion of hemodialysis patients whose hematocrit values are within the target range, without increasing erythropoietin requirements.     

Clinical and histologic features of iron-related bone disease in dialysis patients

Forty-eight dialysis patients undergoing bone biopsy were analyzed for clinical history, blood biochemical values, bone histologic findings, bone aluminum content (BAC), bone iron content (BIC), bone iron stores, and histochemical staining of bone aluminum and bone iron. Four patients had significant trabecular bone iron staining alone; eight patients had significant bone iron and bone aluminum staining; 13 patients had significant bone aluminum staining alone; and 23 patients showed no significant bone aluminum or iron staining. Patients with significant bone iron staining were younger (37.4 +/- 5.3 years v 53.2 +/- 2.3 years, P less than 0.01, mean +/- SEM) and were more likely to be anephric (P less than 0.001) and to have a history of prior renal transplantation (P less than 0.10). The 12 patients with significant bone iron staining had received more blood transfusions than those without bone iron staining (96 +/- 22.8 U v 22 +/- 5.8 U, P less than 0.005). Patients with bone iron accumulation had higher levels of serum ferritin (3,594 +/- 1,138.4 micrograms/L [ng/mL] v 265 +/- 60.1 micrograms/L, P less than 0.01) and lower levels of immunoreactive parathyroid hormone (iPTH) (349 +/- 150 microLEq/mL v 1,801 +/- 397 microLEq/mL [386 +/- 166 pmol/L v 1,990 +/- 439 pmol/L], P less than 0.005). BIC was also higher in these patients (1,008 +/- 149 micrograms iron/g bone v 300 +/- 46.5 micrograms iron/g bone, P less than 0.001) and higher than normal BIC (256 +/- 44.2 micrograms iron/g bone, eight normals). Bone marrow iron stores were positively related to serum ferritin levels (P less than 0.01) and trabecular bone iron staining (P less than 0.10). All 13 patients with osteomalacia demonstrated significant bone aluminum staining; seven of these patients demonstrated concomitant significant iron staining. Fourteen of 15 patients with severe hyperparathyroidism showed no significant iron or aluminum staining. Our data indicate that iron will probably not accumulate within bone until all other storage sites (eg, bone marrow) are fully saturated. The presence of lower levels of iPTH in iron-overloaded patients raises the possibility that iron overload may induce a state of relative hypoparathyroidism. The most important determinant for the presence of osteomalacia seems to be the presence of significant aluminum staining. No specific bone histologic finding was related to the presence of bone iron staining, but the rarity of isolated significant bone iron staining makes it difficult to evaluate bone histologic diagnoses that might be solely attributable to iron.     

Intramuscular testosterone enanthate plus very low dosage oral levonorgestrel suppresses spermatogenesis without causing weight gain in normal young men: a randomized clinical trial

The development of a safe, well-tolerated, effective, and reversible male hormonal contraceptive would be a major clinical advance for couples planning their family size and for control of population growth. High-dosage parenteral testosterone (T) esters alone or in combination with a progestogen (eg, depot medroxyprogesterone) have been shown to confer effective and reversible male contraception in clinical trials, but these regimens are associated with weight gain and suppression of serum high-density lipoprotein cholesterol (HDL) levels. We have previously demonstrated that intramuscular T enanthate 100 mg weekly plus oral levonorgestrel (LNG) 125, 250, or 500 microg daily suppresses spermatogenesis to levels associated with effective contraception, but there is a LNG-dosage-dependent effect of weight gain and HDL suppression. We hypothesized that intramuscular T enanthate 100 mg weekly plus a very low dosage of oral LNG would effectively suppress spermatogenesis in normal men without inducing weight gain or HDL suppression. We conducted a randomized trial comparing 6 months of intramuscular T enanthate (100 mg weekly) plus 31.25 microg of oral LNG daily (T+LNG 31; n = 20) or 62.5 microg of oral LNG daily (T+LNG 62; n = 21). The 2 regimens were equally effective in suppressing spermatogenesis to azoospermia, fewer than 1 million sperm/mL and fewer than 3 million sperm/mL (T+LNG 31 [60%, 85%, and 90%] vs T+LNG 62 [62%, 91%, and 95%] for azoospermia, fewer than 1 million and fewer than 3 million, respectively; P = NS). The T+LNG 31 group did not gain weight (0.25 +/- 1.08 kg; P = NS compared with baseline), but the T+LNG 62 group gained 2.5 +/- 0.77 kg (P < .05 compared with baseline). Serum HDL cholesterol levels declined significantly in both groups (percentage decline month 6 of treatment vs baseline: 12.0% +/- 2.6% and 15.1% +/- 3.0%; P < .05 for T+LNG 31 and 62 respectively). Serum low-density lipoprotein cholesterol levels also declined in both groups (percentage decline month 6 of treatment vs baseline: 6.9 +/- 3.9 and 6.0% +/- 4.1%; P < .05 for T+LNG 31 and P = NS for T+LNG 62). There were no clinically significant adverse events or significant changes in hematology or chemistry profiles in either group during the study. We conclude that 1) intramuscular T plus oral LNG has a very potent synergistic effect in suppressing spermatogenesis at LNG dosages equal to or lower than dosages used in common female oral contraceptive regimens and 2) large, long-term contraceptive efficacy trials should be conducted with a variety of androgen-progestogen combinations including long-acting T formulations such as depot T pellets or intramuscular T undecanoate plus depot LNG or very low dosage oral LNG.     

The effects of nandrolone decanoate on nutritional parameters in hemodialysis patients

AIMS: Malnutrition with hypoalbuminemia is an independent predictor of mortality in end-stage renal disease patients. Anabolic steroids reduce protein catabolism and therefore may improve nutritional parameters. This study was undertaken to determine the effects of the anabolic steroid nandrolone decanoate on the nutritional status of hemodialysis patients. Secondary endpoints were to examine the effects of androgen therapy on hematocrit and erythropoietin (EPO) dose. PATIENTS AND METHODS: Medical records of chronic hemodialysis patients who received nandrolone decanoate for greater than 30 days were reviewed. Data collected included: demographics, dose, frequency, duration of treatment and cumulative dose of nandrolone. Baseline albumin, transferrin, dry weight, phosphorus, creatinine, hematocrit and erythropoietin dose were obtained for comparison with values after treatment. RESULTS: Of the 9 patients evaluated (mean +/- SD: age 55+/-28 years, 4/9 male), 2 patients received nandrolone doses of 25 mg intramuscularly (i.m.) every week, while the remaining 7 patients received 100 mg i.m. every 2 weeks. The mean +/- SD duration of treatment was 96+/-43 days, with a mean +/- SD cumulative dose of 656+/-371 mg. The mean +/- SD baseline albumin was 2.9+/-0.6 mg/dl which increased to 3.3+/-0.4 mg/dl after treatment (p = 0.045). Dry weight increased from a mean +/- SD of 64.4+/-11.7 kg to 66.0+/-10.9 kg after nandrolone therapy (p = 0.028). Mean +/- SD hematocrit at baseline was 28.2+/-4.5% and increased to 33.2+/-5.1% (p = 0.033). The dose of EPO was reduced in 4 patients (44%) during nandrolone therapy. CONCLUSIONS: Nandrolone significantly improved markers of nutritional status in our hemodialysis patients. This therapy may also enhance the hematopoietic effects of EPO.     

Iron status in patients receiving erythropoietin for dialysis-associated anemia

Adequate body iron stores are crucial to assuring rapid and complete response to recombinant human erythropoietin (rHuEPO). In the present study, markers of iron storage were examined in 27 patients with normochromic, normocytic anemia undergoing acute rHuEPO (150 to 300 U/kg t.i.w.) treatment for anemia. We calculated projected iron needed for new hemoglobin synthesis from the difference between initial and target hemoglobin concentrations, initial iron reserves available from initial serum ferritin levels, and net projected surplus or deficit from the difference between needs and reserves. Of 22 patients predicted to develop iron deficiency (mean projected deficit 268 +/- 70 mg), 20 developed evidence of exhausted iron stores (transferrin %sat less than 16 or ferritin less than 30 micrograms/liter) before reaching target hemoglobin; two predicted to become deficient (projected deficit less than 100 mg) did not; and all five predicted to avoid iron deficiency (mean projected surplus 177 +/- 20 mg) remained iron replete. During acute rHuEPO therapy net body iron balance remained neutral in patients receiving no iron supplements and increased 5 mg/kg in patients prescribed oral ferrous sulfate. However, in patients given iron dextran i.v. less than 60% of elemental iron administered became measurable as iron stores or usable for hemoglobin synthesis.     

Correction of deficient phagocytosis during erythropoietin treatment in maintenance hemodialysis patients.

Studies on the influence of erythropoietin (EPO) on granulocyte or monocyte function are scant. In this study, the effect of EPO on polymorphonuclear cell (PMN) respiratory burst activity was evaluated in a double-blind, placebo-controlled study in 22 patients on maintenance hemodialysis. As an index of phagocyte respiratory burst activity, the increase in 14CO2 production from labeled glucose-1-C, after challenge with latex and zymosan, was measured on predialysis whole blood samples, before and after EPO-treatment. As controls, 56 nonuremics and 49 non-EPO-treated hemodialysis patients were evaluated. Before EPO treatment 14CO2 production was depressed to 75.7% (latex) and 54.6% (zymosan) of healthy controls (P less than 0.01). A marked improvement was observed after a mean treatment period of 4 months (latex, 115 +/- 12 to 172 +/- 14; zymosan, 178 +/- 19 to 412 +/- 36 dpm/10(3) PMN, P less than 0.01). Placebo treatment induced no changes. The improvement became more pronounced with prolongation of treatment. A significant correlation between hematocrit and 14CO2 production was observed in the EPO treatment group (latex: n = 44, r = 0.47, P less than 0.05; zymosan: n = 44, r = 0.57, P less than 0.001). No correlation was found with serum ferritin. We conclude that the depressed phagocyte glycolytic activity of hemodialyzed uremics is normalized during correction of anemia by EPO. This may be attributed to factors other than a reduction in the body iron stores.     

Combined treatment with an LHRH agonist and testosterone in man. Reversible oligozoospermia without impotence

We have previously shown that LHRH agonist [D-Trp6,Pro9-NEt]LHRH (LHRHA) results in reversible oligozoospermia when given to normal subjects for up to ten weeks. A fall in plasma testosterone was accompanied by loss of libido and potency. We now report six subjects who were evaluated by semen analysis and hormone profile at two-week intervals during ten-week basal, 20-week treatment, and post-treatment periods lasting at least ten weeks. Treatment consisted of LHRHA (50 microgram subcutaneously daily), and testosterone enanthate (100 mg intramuscularly every two weeks). Sperm density (mean basal 76.7 +/- 8.7 x 10(6)/ml) fell consistently in each subject to a mean nadir of 12.3 +/- 4.5 x 10(6)/ml (p less than 0.001). This is similar to the mean nadir of 11.6 +/- 5.8 x 10(6)/ml achieved when LHRHA was given alone. In each individual subject, sperm density returned to his basal level after cessation of treatment. No consistent changes were seen in sperm motility of morphology, or in semen volume. Libido and potency were maintained in all subjects. An additional three subjects received testosterone enanthate alone in identical dosage for 20 weeks. No change in sperm density was observed. In contrast to treatment with LHRHA alone, combination treatment produces reversible oligozoospermia without attendant change in potency.     

Reduction in erythropoietin doses by the use of chronic intravenous iron supplementation in iron-replete hemodialysis patients

BACKGROUND: Iron deficiency is the most common cause of suboptimal response to recombinant human erythropoietin (rHuEPO) in chronic hemodialysis (HD) patients. Iron supply can correct this situation, however, optimal dosage, route of administration, and monitoring of iron status during rHuEPO therapy in maintenance HD patients remains controversial. METHODS: We conducted a 12-month intravenous iron substitution trial in 149 iron-replete chronic HD patients receiving subcutaneous rHuEPO therapy. The available iron pool was maintained with 100 mg iron every 2 weeks or 1 month depending on serum ferritin and transferrin saturation levels, the rHuEPO dosage titrated depending on hematocrit (Hct) levels. RESULTS: After 12-month protocol, the Hct increased (28.7 +/- 4.1 vs 27.7 +/- 2.6, p = 0.003), rHuEPO requirement reduced 25% (46.1 +/- 28.9 vs 61.5 +/- 67.8 U/kg/week, p = 0.006), serum ferritin increased (1,383 +/- 727 vs 930 +/- 857 ng/ml, p < 0.001), so did the transferrin saturation (36.1 +/- 12.7 vs 27.5 +/- 12.8%, p < 0.001). The serum albumin decreased slightly but reached statistical significance (4.1 +/- 0.48 vs 4.2 +/- 0.36 g/dl, p = 0.006), so did the cholesterol levels (166 +/- 41 vs 173 +/- 38 mg/dl, p = 0.044) and pre-dialysis creatinine (11.3 +/- 2.3 vs 11.5 +/- 2.4 mg/dl, p = 0.015). Besides, the iPTH levels did not interfere with the rHuEPO dosage reduction and Hct increment in our patients. CONCLUSION: We conclude that maintaining high levels of serum ferritin and transferrin saturation could further reduce the requirement of rHuEPO in chronic HD patients, but the long-term effect of iron overloading to patients' nutritional status must be further evaluated in contrast to the economic saving.     

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.