Aluminium intoxication in renal disease.

Aluminium intoxication in renal failure occurred over weeks or months when dialysis fluid or parenteral solutions were heavily contaminated and over many years when the main source was oral administration of aluminium-containing phosphate binders. Encephalopathy was common during subacute intoxication but in slow aluminium poisoning the main brunt was borne by the bones. However, in both tempos of intoxication several organs or systems were involved. Encephalopathy was usually accompanied by bone disease, bone disease by parathyroid suppression and both by anaemia. The heart and the lymphocytes are probably damaged by aluminium overload. Among the many questions left unanswered 15 years after the incrimination of aluminium as the cause of this multi-system illness are: (1) does low level aluminium overload in renal failure cause gradual deterioration in cerebral function? And, if so, (2) does it resemble Alzheimer's disease or a slow-onset version of dialysis encephalopathy? The evidence we review suggests that the answer to (1) is 'yes' and to (2) 'probably the latter'.

Correction of subclinical ascorbate deficiency in patients receiving dialysis: effects on plasma oxalate, serum cholesterol, and capillary fragility.

Whole blood ascorbate, plasma oxalate, serum cholesterol, and capillary fragility were measured at monthly intervals for 3 mth in 7 patients receiving continuous ambulatory peritoneal dialysis and 4 receiving haemodialysis, to whom ascorbate supplements had not been prescribed for at least 12 mth. Ascorbate supplements, 25 mg/day, were prescribed for the first month and 50 mg/day for the second month; in the final month patients received no supplements. Whole blood ascorbate was below normal in 6/11 patients at the start of the study but was normal in 10/11 patients when taking ascorbate 50 mg/day. No significant changes in plasma oxalate were observed with these doses of ascorbate, and correction of ascorbate deficiency had no effect on serum cholesterol, mean cell volume, or the results of capillary fragility tests. In a supplementary study, ascorbic acid 500 mg/day was administered for 3 wk to 11 patients. This resulted in a significant rise in mean plasma oxalate from 30.3 (SEM 3.5) to 48.4 (SEM 20.3) mumol/l.

Effect of pyridoxine supplementation on plasma oxalate concentrations in patients receiving dialysis.

Plasma oxalate and erythrocyte glutamic oxaloacetate transaminase activity (EGOT) (an indicator of nutritional status with respect to pyridoxine) were measured in 21 patients maintained on regular continuous ambulatory peritoneal dialysis or haemodialysis before and after a 4-month period of supplementation with pyridoxine, 100 mg day-1. Prior to supplementation 10/21 patients showed subnormal EGOT activity, although the increment in activity on addition of pyridoxal-5-phosphate in vitro was within the normal range in all cases. Mean plasma oxalate was 31.5 mumol l-1 (SEM 2.9) prior to supplementation and did not change significantly with supplementation, despite normalization of EGOT activity in all but 2/21 patients. We conclude that pyridoxine deficiency does not contribute significantly to hyperoxalaemia in patients receiving dialysis and that 100 mg of pyridoxine daily is insufficient to reduce oxalate generation by a pharmacological action on glycine transamination.

The determination of plasma oxalate concentrations using an enzyme/bioluminescent assay. 2. Co-immobilisation of bioluminescent enzymes and studies of in vitro oxalogenesis.

An inexpensive, continuous flow assay for the determination of oxalate in plasma is described. The assay is based on the bioluminescent determination of NADH, a product of the degradation of oxalate by oxalate decarboxylase and formate dehydrogenase, using bioluminescent enzymes immobilized on cyanogen bromide-activated sepharose. The detection limit of the assay is 0.8 mumol/l. Intra-batch CV values of 5.2 and 3.8% were obtained at oxalate concentrations of 18 and 60 mumol/l. Recovery of added oxalate averaged 100.7%. Plasma oxalate ranged from less than 0.8 to 2 mumol/l in 14 healthy subjects, and from 6 to 134 mumol/l in 125 patients with renal disease treated by continuous ambulatory peritoneal dialysis. Ascorbic and dehydroascorbic acid did not directly interfere in the assay. In vitro oxalogenesis was observed in blood from 12 healthy subjects, but only after samples had stood at room temperature for more than 6 h. No significant oxalate generation occurred in blood from 24 patients with impaired renal function, even after standing at room temperature for 24 h. Oxalate generation was inhibited by the addition of oxalate to plasma, but the addition of urea and creatinine was without effect.

Plasma oxalate concentration and secondary oxalosis in patients with chronic renal failure.

To examine the association between hyperoxalaemia and secondary oxalosis, measurement of plasma oxalate concentration was combined with a search for tissue deposition of calcium oxalate crystals in patients with chronic renal disease. Two groups of patients were studied. In the first, samples of the inferior epigastric artery were taken from 35 patients at the time of renal transplantation. In the second, sections taken at necropsy from 23 patients with chronic renal failure in whom plasma oxalate had been measured before death were examined. Though plasma oxalate concentrations ranged between 6 and 116 mumol/l (four to 78 times greater than the upper limit of the reference range), no extrarenal deposits of oxalate were found in either study. Renal deposition of oxalate was associated with a plasma oxalate concentration of greater than 20 mumol/l. This study gives no support to the suggestion that hyperoxalaemia of the degree seen in patients with the type of chronic renal failure that is not due to primary hyperoxaluria confers an appreciable risk of extrarenal oxalosis.

Plasma oxalate in patients receiving continuous ambulatory peritoneal dialysis.

Plasma oxalate has been measured in 125 patients maintained on continuous ambulatory peritoneal dialysis using an enzyme/bioluminescent assay. Values ranged between 6 and 134 mumol/l, with a positively skewed distribution. Multiple linear regression analysis with plasma oxalate as the dependent variable showed highly significant associations with the dose of ascorbic acid, dose of alfacalcidol, and plasma creatinine, and weaker associations with serum phosphate, serum calcium, and body weight. When the presence of other potential risk factors was taken into account, no significant relationship could be found between the presence of clinically evident cardiac or vascular disease and plasma oxalate.

Critical evaluation of a commercial enzyme kit (Sigma) for determining oxalate concentrations in urine.

The Sigma reagent kit for urinary oxalate determination is reportedly simple, rapid, and specific for oxalate. We evaluated the kit and identified a number of shortcomings. Our investigations suggest that the recommended time for chromophore development is too short and should be doubled. Oxalate recovery during the extraction procedure depends strongly on urine pH. For complete extraction, urine should be acidified to pH 1.8-2.4. We also observed positive interference from ascorbate in urine. This interference was substantial, absorbances produced from ascorbate standards being approximately 80% of those obtained from oxalate standards of similar concentration. Our investigations also indicate the presence of a substance on the Sigma adsorbent that is eluted during the extraction procedure and interferes in the color reaction. These interferences represent potentially major sources of imprecision in the assay.

The determination of plasma oxalate concentrations using an enzyme/bioluminescent assay.

An enzyme/bioluminescent assay for the determination of oxalate in plasma is described in which NADH, a reaction product of the enzymic degradation of oxalate by oxalate decarboxylase and formate dehydrogenase, is determined using a commercially available bioluminescent system. In contrast to most previously documented methods, this sensitive and specific assay requires minimal sample preparation allowing oxalate concentrations to be determined within 2 h of sample collection. The limit of detection for plasma samples is 0.8 mumol/l. The recovery of oxalate added to plasma averaged 99%. The inter-batch coefficient of variation, calculated by analysis of a plasma sample from a uraemic patient (oxalate concentration = 45.8 mumol/l) on 8 occasions, over a period of 5 wk, was 3.2%. Plasma oxalate concentrations in 35 normal subjects ranged from less than 0.8-1.5 mumol/l, which is in excellent agreement with values obtained by in vivo isotope dilution studies. Plasma oxalate was found to be strikingly elevated in a group of uraemic patients maintained on regular haemodialysis.

Aluminum in the dialysis fluid.

The major source of aluminum in patients with chronic renal failure treated by hemodialysis is the hemodialysis fluid. The aluminum is derived from both the water and the chemical concentrate used in the preparation of the hemodialysis fluid. Due to the complex physico-chemistry of aluminum in water and dialysis fluid, both the total aluminum concentration and the proportion of aluminum species able to cross the hemodialysis membrane may vary from water supply to water supply and from day to day within a supply. A "safe" level of aluminum in dialysis fluid, which will prevent aluminum transfer from dialysis fluid to blood, and promotes aluminum removal from blood, has yet to be determined.

Raised serum nickel concentrations in chronic renal failure.

We have measured serum nickel concentrations using flameless atomic absorption spectrophotometry. In 71 normals the median concentration was 1.0 micrograms/L, range less than 0.6-3.0 micrograms/L. Increased concentrations (p less than 0.05) were found in patients with chronic renal failure (CRF) treated conservatively (median 1.6 micrograms/L, range less than 0.6-3.6 micrograms/L). Significantly increased concentrations (p less than 0.001) were found in patients treated by continuous ambulatory peritoneal dialysis (CAPD) (median 8.6 micrograms/L, range 5.4-11.4 micrograms/L) and haemodialysis. In patients on haemodialysis, post-dialysis concentrations (median 8.8 micrograms/L, range 3.0-21.4 micrograms/L) were significantly higher (p less than 0.001) than pre-dialysis values (median 8.6 micrograms/L, range 0.6-16.6 micrograms/L).

A method for the routine determination of aluminium in serum and water by flameless atomic absorption spectrometry.

A simple but reliable method for the routine determination of aluminium in serum and water by flameless atomic absorption spectrometry is described. No preparatory procedures are required for water samples, although serum is mixed with a wetting agent (Triton X-100) to allow complete combustion of the samples and to improve analytical precision. Precautions to prevent contamination during sample handling are discussed and instrumental parameters are defined. The method has a sensitivity of 35.5 pg and detection limits of 2.3 micrograms Al/l for serum and 1.3 micrograms Al/l for water. The method was used to determine the aluminium concentration in serum of 46 normal subjects. The mean aluminium content was 7.3 micrograms/l (range 2--15 micrograms/l.

Fracturing dialysis osteodystrophy and dialysis encephalopathy. An epidemiological survey.

A survey of 1293 patients in eighteen dialysis centres in Great Britain showed a highly significant rank correlation of the incidence of both fracturing dialysis osteodystrophy (osteomalacic dialysis osteodystrophy) and dialysis encephalopathy with the aluminium content of water used to prepare dialysate.

Evidence for aluminium accumulation in renal failure.

There is increasing evidence that aluminium accumulation in patients with impaired renal function has pathological consequences. The serum aluminium content of 45 patients with chronic renal failure was found to be significantly elevated when compared with normal subjects. A further rise in serum aluminium concentration was seen in patients with chronic renal failure when they were taking aluminium-containing phosphate binding agents. Patients with stable but moderately impaired renal function who are taking aluminium-containing phosphate binders for several years may be at risk from aluminium accumulation and the development of osteomalacia and encephalopathy as seen in patients on intermittent haemodialysis.

Osteomalacic dialysis osteodystrophy: Evidence for a water-borne aetiological agent, probably aluminium.

In patients maintained on regular haemodialysis in Newcastle upon Tyne the development of osteomalacia is substantially reduced when water used to prepare dialysate is deionised. After 1--4 years of dialysis, osteomalacia was evident in 15% of patients on deionised water in 70% of patients on softened water from the same source. The close association of dialysis encephalopathy and osteomalacia suggests a common aetiology. Both diseases occur in centres with a high tap-water aluminium content. Serum-aluminium concentrations were raised in patients undergoing regular haemodialysis in the Northern Region of England. Those using softened water had higher concentrations than those using deionised water. Patients on softened water who had encephalopathy or dementia had serum-aluminium concentrations similar to those of patients using the same water-supplies without symptoms of these diseases, but they had been treated for longer. The evidence that aluminium absorption from dialysate causes osteomalacia and encephalopathy is strong enough to justify the expense of treating water by deionisation, reverse osmosis, or both in centres where tap-water aluminium is high.

Brain-aluminium concentration in dialysis encephalopathy.

Brain-aluminium concentrations were found to be significantly higher in 7 patients dying with dialysis encephalopathy (mean 15.9 microgram aluminium/g dry weight) than in 11 dialysed controls (4.4 microgram/g) and in 2 uraemic patients who were not dialysed (2.7 microgram/g). The grey matter from the patients with dialysis encephalopathy contained about three times as much aluminium as white matter. The results suggest that dialysis with untreated and/or softened tap-water (aluminium concentration 0.1-1.2 mg/1) makes the major contribution to brain-aluminium levels; dialysis with deionised water (aluminium concentration normally less than 0.02 mg/1) and intake of phosphate-binding AL(OH)3 gel are less important. Brain aluminium levels remain elevated for up to four years after restoration of good renal function by transplantation. The association of dialysis encephalopathy with high levels of aluminium in the brain and in the dialysis water emphasises the potential neurotoxicity of aluminium in man.