Deferoxamine test and bone disease in dialysis patients with mild aluminum accumulation

Aluminum bone disease is a frequent complication of dialysis patients. The deferoxamine (DFO) test has been advocated as a noninvasive procedure for the diagnosis of AI bone lesion. However most of these studies have been performed in symptomatic patients with significant AI bone disease. Whether this test may provide similar data at an earlier stage of AI toxicity is not known. The present study evaluates prospectively 28 patients with mild AI load. Patients studied ranged in age from 21 to 65 years; duration of dialysis was 5.6 +/- 3.2 years; deferoxamine, 40 mg/kg body weight, was infused at the end of dialysis. Serum AI was measured before DFO administration and before the next dialysis treatment. Bone biopsies were performed in all patients. Cortical bone AI was determined biochemically; trabecular and cortical bone AI were also determined histochemically. Mean basal serum AI (43.2 +/- 30.8 micrograms/L) and cortical bone AI (25.7 +/- 35.2 micrograms/g) were moderately increased. Basal serum AI correlated (r = 0.77) with the increment in serum AI after DFO infusion. After DFO, stainable trabecular and cortical bone AI correlated in a similar manner with both basal serum AI and increment in serum AI. Only biochemically determined cortical bone AI was not significantly related to basal serum AI. Nineteen of the 28 patients had evidence of osteitis fibrosa on bone biopsy. Stained AI surfaces but not trabecular AI were different in patients with low and patients with high bone formation rates. The bone findings, assessed as bone formation rates and resorption surfaces, did not correlate with biochemically or histochemically determined bone AI.(ABSTRACT TRUNCATED AT 250 WORDS)     

Accelerated removal of deferoxamine mesylate-chelated aluminum by charcoal hemoperfusion in hemodialysis patients

Although deferoxamine mesylate (DFO) is effective in removing aluminum (Al) in hemodialysis patients, treatment with this drug is associated with a number of adverse effects. In order to limit the exposure of patients to DFO-Al complexes, the efficacy of colloidin-coated microencapsulated charcoal cartridges added in series to conventional dialyzers was investigated. The clearances of Al by the sorbent system were initially 116 +/- 4.7 mL/min, but decreased to 42.5 +/- 6.6 mL/min after 120 minutes of treatment. Thereafter, the Al clearances remained constant. In contrast, the Al clearances of the dialyzer were 29.5 +/- 1.8 mL/min initially and did not change during the treatment period. Both the percent and absolute decrease in Al levels after four hours of dialysis were greater with the dialyzers plus carbon cartridges than with the dialyzers alone. This resulted in an increase in the minimum net Al removal from 1,862 +/- 174 micrograms/treatment to 3,007 +/- 43 micrograms/treatment (P less than 0.05). Treatment with sorbent hemoperfusion should be considered in selected hemodialysis patients being treated with DFO for Al overload.     

Deferoxamine and aluminum clearance in pediatric hemodialysis patients

Mobilization of aluminum by deferoxamine and the subsequent clearance from plasma by hemodialysis with or without charcoal hemofiltration was studied in four pediatric patients. Deferoxamine, 10–20 mg/kg, followed by dialysis with a Travenol CA50 dialyzer produced reductions in mean plasma aluminum levels from 2433±729 nmol/l (65.5±19.6 g/l) to 1727±554 nmol/l (46.5±14.9 g/l) during dialysis. The use of a charcoal cartridge in the circuit resulted in a reduction in mean plasma aluminum levels 2459±591 nmol/l (66.2±15.9 g/ml) to 1380±106 nmol/l (35.8±2.9 g/l). In one patient, high-flux dialysis produced a reduction from 2140 nmol/l (55.6 g/l) to 1134 nmol/l (29.4 g/l). No patients suffered direct adverse reactions to low-dose deferoxamine, although two patients had previously exhibited potential aluminum neurotoxicity after rapid increases in plasma aluminum levels with deferoxamine in higher doses. Aluminum levels must be monitored closely during deferoxamine therapy in uremic children to minimize the risk of exacerbating aluminum neurotoxicity.     

Deferoxamine therapy and mucormycosis in dialysis patients: report of an international registry

Fifty-nine cases of mucormycosis in dialysis patients have been reported to the registry (25 new cases and 34 previously reported cases). The presenting forms of mucormycosis included disseminated in 44%, rhinocerebral in 31%, and other forms in 25%. The diagnosis was made during life in only 39%, while the diagnosis was discovered at autopsy in 61% of the cases. The fungus, cultured in only 36%, was always Rhizopus. The infection was fatal in 86% of cases. No known risk factors for fungal infections, eg, diabetes mellitus, liver disease, splenectomy, neutropenia, steroid therapy, or other immunosuppressive therapy, were present in 70% of patients, but 78% of patients were being treated with deferoxamine. The role played by this drug and more particularly by its iron chelate, feroxamine, in the pathogenesis of mucormycosis in these patients is underscored. Because of this risk, deferoxamine therapy in dialysis patients should be limited to severe aluminum toxicity, the deferoxamine should be given at the lowest possible dose, and dialytic methods to augment the removal of feroxamine should be studied.     

Repeat charcoal hemoperfusion treatments in life threatening carbamazepine overdose

A 16-month-old female experienced a massive carbamazepine ingestion resulting in a peak serum carbamazepine concentration of 55 μg/ml. Clinical manifestations included generalized seizures, coma, shock, and gastrointestinal hypomotility. Gut decontamination was attempted using multiple-dose activated charcoal and cathartics. Because of the severity of illness, charcoal hemoperfusion was initiated. The patient underwent three sessions of charcoal hemoperfusion, each utilizing a fresh cartridge, with one session immediately following the other. Serum carbamazepine and carbamazepine-10,11-epoxide concentrations decreased from 54 μg/ml to 23 μg/ml, and 30 μg/ml to 17 μg/ml, respectively, during charcoal hemoperfusion. There were no complications. The patient recovered completely and was discharged on the 4th hospital day. Charcoal hemoperfusion should be considered for life-threatening carbamazepine intoxication, especially when drug-induced gastrointestinal hypomotility prevents elimination via the gut. Received: 12 October 1998 / Revised: 11 December 1998 / Accepted: 17 December 1998     

Combined high-efficiency hemodialysis and charcoal hemoperfusion in severe N-acetylprocainamide intoxication.

Several extracorporeal techniques have been used to remove N-acetylprocainamide (NAPA), the major metabolite of procainamide, in patients intoxicated with this substance. We report a patient with life-threatening NAPA intoxication who was rapidly and successfully treated with combined high-efficiency hemodialysis and charcoal hemoperfusion. The hemodialyzer and hemoperfusion cartridge were placed in series such that the patient's blood was dialyzed before reaching the cartridge. Overall clearance of NAPA was 153 mL/min, with clearance due to hemodialysis averaging 102 mL/min and that due to hemoperfusion averaging 88 mL/min. Thus, addition of the hemoperfusion cartridge into the extracorporeal circuit resulted in a 50% increase in clearance over that obtainable by high-efficiency hemodialysis alone. In comparison to other modalities, this technique is more effective than either hemodialysis or charcoal hemoperfusion alone and can achieve a more rapid reduction of serum NAPA levels than that observed with slow continuous hemofiltration or hemodiafiltration.     

Chlorpropamide overdose in renal failure: management with charcoal hemoperfusion

A potentially lethal chlorpropamide overdose in a patient with chronic renal failure on long-term hemodialysis was treated by two courses of charcoal hemoperfusion. Hemoperfusion shortened the half-life clearance of the drug from a mean value of 93.6 to 3.4 hours. Calculation of the fractional extraction indicated that hemoperfusion reduced the body burden of the drug by 24% and 19% (mean values) during the first and second hours of treatment, respectively. We conclude that charcoal hemoperfusion should be considered a definitive therapeutic option in such cases.     

Removal of aluminoxamine and ferrioxamine by charcoal hemoperfusion and hemodialysis.

We studied the removal of aluminoxamine (AlO) and ferrioxamine (FO) by (i) hemoperfusion/hemodialysis using an AluKart in combination with either a Cuprophan F-120 or a Hemophan FH-160 membrane, or (ii) hemodialysis with a high-flux F-60 polysulfone membrane. The same six dialysis patients underwent in a random order dialysis by the three set-ups after i.v. infusion of 30 mg/kg of desferrioxamine (DFO) during the last half an hour of the preceding dialysis session. The mean +/- SD plasma AlO and FO clearances of the AluKart combined with either a F-120 or FH-160 membrane were 194.3 +/- 25.8 ml/min (AlO) and 164.2 +/- 41.3 ml (FO) at the start of dialysis declining to respectively 76.6 +/- 27.3 and 68.5 +/- 42.6 ml/min at the end of dialysis. With a high-flux dialysis membrane the intra-dialytic plasma clearance remained constant at 81.5 +/- 6.8 ml/min for AlO and 60.0 +/- 2.8 ml/min for FO. In the presence of an AluKart combined with a FH-160 up to 84 +/- 27% and 84 +/- 19% of the available AlO and FO could be removed during a four-hour hemoperfusion/hemodialysis session. During the first hour of dialysis, respectively 59 and 58% of the total amount of AlO and FO extracted by the AluKart was removed compared to only 9 and 16% during the last hour.(ABSTRACT TRUNCATED AT 250 WORDS)     

Percutaneous hepatic venous isolation and extracorporeal charcoal hemoperfusion for high-dose intraarterial chemotherapy in patients with colorectal hepatic metastases

The results of treating 12 consecutive patients with unresectable colorectal hepatic metastases with a hepatic arterial infusion of high-dose Adriamycin, 100–120 mg/m², using hepatic venous isolation (HVI) and charcoal hemoperfusion (CHP) are reported herein. Adriamycin was administered over 5–15 min under extracorporeal drug elimination by HVI-CHP. HVI was percutaneously accomplished by either the double-balloon technique using a Fogarty occlusion catheter (8/22F) or a balloon-tipped catheter (16F). During the infusion, isolated hepatic venous blood was filtered by CHP and pumped into the left axillary vein. There were no lethal complications, and good hemodynamic tolerance to HVI-CHP was confirmed. Tumor liquefaction accompanied by a sharp decrease in serum carcinoembryonic antigen levels by more than 50% of pretreatment levels was observed in 6 of the 12 patients 1 month after treatment. Apart from chemical hepatitis, which developed in 11 (92%) of the patients, the Adriamycin toxicities were well controlled following the development of nausea and vomiting in 2 patients (17%), leukopenia <2,000/mm³ in 3 (25%), and gastric ulcer in 1 (8%). These results indicate that this method is a safe and useful procedure for otherwise hazardous high-dose intraarterial chemotherapy in patients with unresectable hepatic tumors.     

Elevated bone aluminum and suppressed parathyroid hormone levels in hypercalcemic dialysis patients

We studied 21 dialysis patients who became hypercalcemic without vitamin D or calcium therapy and compared them to 28 dialysis patients who were not hypercalcemic. In the hypercalcemic group, the mean ionized-calcium level was elevated compared to normal subjects (5.4 +/- 0.4 vs. 4.9 +/- 0.1; p less than 0.001), while the ionized-calcium level in the control dialysis patients was below normal (4.5 +/- 0.4 vs. 4.9 +/- 0.1; p less than 0.001). Bone biopsies were performed in all patients. Two thirds of the hypercalcemic patients had low-turnover osteodystrophy (LTO, predominantly osteomalacia), a fraction significantly higher than in the control dialysis patients (13/21 vs. 8/28, respectively; p less than 0.05). The hypercalcemic patients with LTO had markedly elevated surface bone aluminum (63 +/- 24% of all trabecular surfaces). In contrast, the nonhypercalcemic dialysis patients with LTO and all patients with osteitis fibrosa had minimal surface bone aluminum. Hypercalcemic patients with osteitis fibrosa had a significantly lower mean N-terminal parathyroid hormone (PTH) value than did nonhypercalcemic patients with osteitis fibrosa (149 +/- 81 vs. 278 +/- 135 pg/ml, respectively; p less than 0.005). Both mean values were markedly elevated in comparison with those obtained in normal subjects (16 +/- 5 pg/ml). In contrast, patients with LTO, irrespective of the calcium level, had mean PTH values that were not significantly different from those of normal subjects. A PTH level greater than 100 pg/ml was 95% sensitive and 87% specific for osteitis fibrosa, as demonstrated by histomorphometry in nonhypercalcemic dialysis patients. However, this level was only 62% sensitive and 77% specific for a diagnosis of osteitis fibrosa in hypercalcemic dialysis patients.(ABSTRACT TRUNCATED AT 250 WORDS)     

A prospective study of pyrogenic reactions in hemodialysis patients using bicarbonate dialysis fluids filtered to remove bacteria and endotoxin.

Pyrogenic reactions (PR) are a well-recognized complication of hemodialysis and have been associated with dialyzer reuse, high-flux dialysis, and bicarbonate dialysate. However, the roles of bacteria and endotoxin in dialysate for producing PR are not well defined. To determine the effect of removing most bacteria and endotoxin from the dialysate on the incidence of PR, a cohort of chronic hemodialysis patients receiving high-flux, high-efficiency, or conventional hemodialysis at three centers with bicarbonate dialysis fluids that had been filtered with a polysulfone high-flux hemodialyzer was prospectively studied. Unfiltered bicarbonate concentrate had median bacterial and endotoxin concentrations of 479,000 CFU/mL and 39,800 pg/mL, respectively. After filtration of the bicarbonate concentrate at the central proportioner, dialysate had a median 9.2 CFU/mL of bacteria and 17.8 pg/mL of endotoxin. Dialysate filtered at individual proportioning dialysis machines had a median 0.001 CFU/mL of bacteria and 0.19 pg/mL of endotoxin. Nine PR were identified among 303 patients after 28,007 hemodialysis treatments (0.3 PR/1,000 treatments). The rate of PR was similar for the three hemodialysis treatment modalities and for first-use compared with reused dialyzers. Although the PR rate in this study was lower (P = 0.046) than the PR rate of a previous study with unfiltered dialysis fluids (0.7 PR/1,000 treatments), it represents a difference of only 10 PR in over 28,000 treatments. It was concluded that filtration of hemodialysis fluids is efficacious in removing bacterial and endotoxin contamination and can result in a lower incidence of PR in patients receiving high-flux, high-efficiency, or conventional hemodialysis.     

Microcytic anemia in dialysis patients: reversible marker of aluminum toxicity

Improvement of microcytic anemia after deferoxamine treatment is described in eight long-term dialysis patients with high serum aluminum concentration and other clinical signs of aluminum toxicity. Hematocrit increase of 3 to 19 vol% was associated with correction of microcytosis, significant reduction in abnormal levels of free erythrocyte protoporphyrins, and amelioration of the bone-related symptoms and neurologic signs of aluminum intoxication. Increase in hematocrit, reversal of microcytosis, and reduction in protoporphyrin levels all correlated with the aluminum burden as indicated by the pretreatment serum aluminum levels and by the peak serum aluminum levels during mobilization with deferoxamine. Furthermore, deferoxamine resulted in marked improvement in anemia despite significant reduction in serum ferritin levels. This reversal of microcytosis with deferoxamine provides objective evidence verifying the toxicity of aluminum, and suggests that microcytosis may be an easily detected marker for both clinical diagnosis as well as response to treatment in some cases of aluminum intoxication.     

Aluminum removal with hemodialysis, hemofiltration and charcoal hemoperfusion in uremic patients after desferrioxamine infusion. A comparison of efficiency

In order to compare the effectiveness of aluminum removal in uremic patients during extracorporeal treatment, 17 patients with endstage renal failure were given a desferrioxamine infusion of 40 mg/kg body weight after an ordinary dialysis treatment. Forty-eight hours later 7 patients were treated with hemodialysis, 6 with hemofiltration and 4 with a combination of hemodialysis and hemoperfusion. The clearance of aluminum was measured at different intervals. It was found that the aluminum clearance was 75 +/- 18 ml/min in hemofiltration compared to 30 +/- 10 ml/min in hemodialysis (p less than 0.001). A combination of hemodialysis and hemoperfusion with a charcoal column containing 100 g activated charcoal in series gave a total aluminum clearance of 56 +/- 11 ml/min. The total amount of aluminum in the ultrafiltrate after hemofiltration was found to be approximately 3 times as high (1,728 +/- 156 micrograms) as the total amount of aluminum in the hemodialysis water that had passed a single pass system during a 4-hour dialysis (576 +/- 104 micrograms). Our results indicate that hemofiltration or a combination of hemodialysis and hemoperfusion should be used to remove aluminum in patients with signs of severe aluminum accumulation such as encephalopathy or painful bone disease, because these methods are 2-3 times as effective as ordinary hemodialysis. In patients where aluminum has been accumulated but no severe symptoms occur hemodialysis gives a significant clearance of the aluminum desferrioxamine complex.     

Non-invasive prediction of aluminum bone disease in hemo- and peritoneal dialysis patients.

Between October 1987 and October of 1989, we conducted a prospective study to evaluate non-invasive test strategies for predicting aluminum bone disease (ABD) in a group of largely unselected dialysis patients based on their deferoxamine (DFO) test alone, or the combined results of their DFO test and intact 1-84 parathyroid hormone (PTH) levels. These test parameters were evaluated against the pathological diagnosis of ABD based on bone biopsy ("gold standard"). A total of 445 patients in three dialysis centers in Toronto were serially followed for their clinical, laboratory and risk parameters for renal osteodystrophy during the study, and 259 (142 PD and 117 HD) patients underwent a series of investigations which included the DFO test, measurement of intact 1-84 PTH levels, and an iliac crest bone biopsy. Serum aluminum ([Al]) level greater than or equal to 3700 nM (or 100 micrograms/liter) had a positive predictive value (PPV) of 75% for ABD in our PD and 88% in our HD patients, but its sensitivity was low (10 and 37%). Delta [Al] (that is, incremental rise of serum [Al] from baseline post-DFO) was useful in predicting ABD in our PD but not HD patients. Test combination based on delta [Al] greater than or equal to 5550 nM (or 150 microgram/liter) and PTH levels less than 20 pM (or 200 pg/ml) yielded the best PPV greater than or equal to 95% for ABD in both PD and HD patients. This test cut-off would remain highly predictive of ABD even if the prevalence of ABD decreases to as low as 5% for the PD patients and 10% for the HD patients.(ABSTRACT TRUNCATED AT 250 WORDS)