Non-aluminic adynamic bone disease in non-dialyzed uremic patients: a new type of osteopathy due to overtreatment?

Adynamic bone disease, characterized by a low bone formation rate with normal or reduced amount of unmineralized osteoid, is supposed to be the consequence of aluminum intoxication in uremic patients. However, the emergence of adynamic bone disease has been recently reported in hemodialyzed patients in the total absence of aluminum overload. This study was aimed to assess whether such a histological pattern of adynamic bone disease was already present in uremic patients not yet on dialysis. Twenty-seven asymptomatic uremic patients (mean age +/- SD 43 +/- 10 years, mean creatinine clearance 19 +/- 3 ml/mm) were studied and bone biopsies were repeated in 16 of them after 18 +/- 10 months of treatment with oral calcium carbonate (1-3 g of elemental calcium/day) and calcidiol (21 +/- 14 micrograms/day). None of the patients received aluminum hydroxide, and the search for bone aluminum deposits was negative in all patients both before and after treatment. Two patients fulfilled the criteria of adynamic bone disease on their post-treatment biopsies. They originated from patients classified as having normal bone histology before treatment. Comparison with the other patients showed that they had comparable plasma C-terminal PTH but higher plasma creatinine than patients with normal bone histology and lower plasma C-terminal PTH than patients with osteitis fibrosa but comparable plasma creatinine. The plasma levels of 1,25(OH)2D reached values above normal after treatment in these two patients. It is suggested that adynamic bone disease not related to aluminum intoxication can develop in uremic patients independently of dialysis, and is favored by a relative hypoparathyroidism for the degree of renal failure, possibly induced by elevated plasma concentrations of calcitriol.     

Aluminum-associated bone disease in chronic renal failure: high prevalence in a long-term dialysis population

Twenty-seven asymptomatic patients treated with hemodialysis longer than 8 years (mean 12.9 +/- 3.1 years) underwent bone biopsy to determine the prevalence of aluminum-associated bone disease. None had excess aluminum exposure from the dialysate. Ten patients (37%) had aluminum-associated bone disease as defined by a bone formation rate (BFR) below normal in the presence of stainable bone aluminum that covered more than 25% of the trabecular surface. The predominant type of bone histology in this group was the aplastic lesion characterized by low bone turnover, a decreased number of osteoblasts, and lack of excess unmineralized osteoid. Osteoblastic osteoid was highly correlated with stainable surface bone aluminum (r = -.82, p less than .001). Among the dynamic bone parameters, the double-tetracycline labeled surface was a more sensitive indicator of impaired bone function than was the bone apposition rate (BAR), since half of the patients with aluminum-associated bone disease had a normal BAR. In all of the biopsies the extent of double-labeled surfaces was inversely proportional to the amount of stainable aluminum on the bone surface (r = -.71, p less than .001), whereas stainable bone aluminum did not correlate with BAR. In seven of the patients with aluminum-associated bone disease, amino-terminal PTH levels were in the normal range while only one patient had a normal plasma mid-region PTH. PTH correlated directly with osteoblastic osteoid, BFR, and double-labeled surfaces. These results indicate that long-term oral aluminum intake in hemodialysis patients results in a high prevalence of aluminum-associated bone disease.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of fluoride on aluminum-induced bone disease in rats with renal failure.

Aluminum (Al) accumulation in renal failure is an etiological factor in the pathogenesis of low turnover bone disease. Aluminum-induced impairment of mineralization has been related to a reduced extent of active bone-forming surface. The present study investigated the effect of fluoride, a potent stimulator of osteoblast number, on the toxicity of aluminum in rats with renal failure (Nx). Following a large parenteral aluminum load (3.2 mg/kg x day) over a period of nine weeks, bone histomorphometry of vertebral cancellous bone revealed a severe low-turnover osteodystrophy as evidenced by a fall in osteoblastic osteoid surfaces and mineral apposition rates. Concurrent administration of fluoride [20 mg/liter (F20) or 40 mg/liter (F40) supplied with the drinking water] resulted in a significant increase in the number of osteoblasts (Nx+Al+F40 vs. Nx+Al, 33.75 +/- 2.83 vs. 1.81 +/- 0.43 mm-1, P less than 0.001) together with an overall reduced deposition of aluminum in bone (469.3 +/- 24.6 vs. 592.2 +/- 28.3 micrograms/g, P less than 0.01). However, there was an increase in the fraction of osteoid surface exhibiting stainable aluminum at the bone-osteoid interface (70.7 +/- 7.1 vs. 44.3 +/- 6.0%, P less than 0.005). Fluoride-exposed rats accumulated a significantly larger osteoid volume, suggesting an exacerbation of the osteomalacic lesion, and furthermore, dynamic histomorphometric parameters remained depressed. These results indicate that fluoride has a distinct effect on the pattern of aluminum deposition in bone. In addition, fluoride antagonizes the aluminum-induced reduction in osteoblast number but provides no amelioration of the impaired mineralization in aluminum-intoxicated rats. Thus, in this model a decrease in the extent of osteoblast surface does not account for the development of aluminum-related bone disease.(ABSTRACT TRUNCATED AT 250 WORDS)     

Increased bone aluminum deposition after subtotal parathyroidectomy in dialyzed patients

Ten dialyzed patients underwent a systematic bone biopsy before and 19 +/- 9 months after subtotal parathyroidectomy (PTX). At the end of the follow-up period all the patients, except two, who complained of proximal myalgia, were asymptomatic. Compared to the bone biopsy specimen obtained prior surgery, decreased bone formation without mineralization impairment was observed after PTX. Despite an average decrease in aluminum gels intake after PTX, an increase in stained aluminum was observed (0.69 +/- 0.79 versus 1.20 +/- 0.95 mm/mm2, P less than 0.050). Aluminum accumulation depended on the pre-PTX bone aluminum load: pre- and post-PTX bone aluminum loads were correlated (r = 0.78, P less than 0.01). Bone aluminum accumulation was not related to the amount of aluminum gel intake after PTX; however, only two patients free of both bone aluminum deposit prior to PTX and aluminum gel intake after PTX had no stainable aluminum on the second bone biopsy after PTX. The only patient who had no decrease in bone formation after PTX had no increase in bone aluminum. Assuming that the patients had no aluminum deposit prior to dialysis, we measured the rate of bone aluminum accumulation. It rose from 0.11 +/- 0.09 mm/mm2/year prior to PTX to 0.40 +/- 0.25 mm/mm2/year after PTX (P less than 0.05) in the six patients who were maintained on phosphate binders and who had a decrease in bone formation after PTX. These six patients had unchanged aluminum gel intake.(ABSTRACT TRUNCATED AT 250 WORDS)     

The evolution of osteomalacia in the rat with acute aluminum toxicity

Aluminum toxicity is the presumed cause of aluminum-associated osteomalacia. In animal models, osteomalacia has been produced after a prolonged course of aluminum. In the present study, rats with renal failure received 20 mg intraperitoneal aluminum during a 2 day period. This model allows sequential observations in the development of osteomalacia. Rats were sacrificed and studied 5, 12, 25, and 40 days after aluminum administration. No differences were observed in serum calcium, phosphorus, or creatinine as a consequence of aluminum administration. Compared with control rats, parathyroid hormone was decreased at 12 and 25 days. A direct correlation was present between plasma and bone aluminum at 12 days (r = 0.92, p less than 0.01), 25 days (r = 0.85, p less than 0.005), and 40 days (r = 0.88, p less than 0.001) but not 5 days after aluminum administration. Plasma aluminum peaked at 5 days (727 +/- 89 micrograms/liter, mean +/- SEM) and bone aluminum at 40 days (273 +/- 40 micrograms/g). Aluminum had profound effect on bone histology. At 5 days there was a decrease in osteoblast surface and osteoid surface; at 12 days osteoblast surface and osteoid surface returned to normal but osteoclast surface decreased. Subsequently there was a progressive increase in osteoid surface and osteoid volume. Bone formation rate measured at 12, 25, and 40 days was decreased at these intervals. In conclusion, (1) high plasma aluminum may be directly toxic to the osteoblast; (2) progressive osteoid accumulation is secondary to matrix (osteoid) deposition, which exceeds the depressed bone formation rate; (3) the progressive decrease in plasma aluminum and increase in bone aluminum suggest that bone has a high affinity for aluminum but may have a relatively slow rate of uptake at any given time; (4) aluminum may directly decrease parathyroid hormone; (5) the correlation between plasma and bone aluminum suggest an exchange is present; and (6) aluminum toxicity may independently affect the osteoblast and bone mineralization.     

Substitution of calcium carbonate for aluminum hydroxide in patients on hemodialysis. Effects on acidosis, on parathyroid function, and on calcemia

Substitution of calcium carbonate for aluminum hydroxide in patients on dialysis: effects on acidosis, parathyroid function, and calcemia. We studied the effects of substituting CaCO3 for aluminum-containing gels on metabolic acidosis and on the response of the parathyroid glands in 11 patients treated with chronic hemodialysis. The 8 men and 3 women were clinically stable, were known to be compliant, and had no clinical evidence of aluminum overload; they were not receiving vitamin D supplements; and they had been on dialysis for an average of 65.6 months (range: 13-188 months). After 3 weeks of CaCO3 administration plasma phosphate concentration remained well controlled, and plasma calcium concentration increased from 9.2 +/- 0.2 (2.3 +/- 0.1 mmol/l) to 10.1 +/- 0.2 mg/dl (2.5 +/- 0.1 mmol/l). Predialysis plasma bicarbonate concentration increased from 19.7 +/- 0.6 to 21.9 +/- 0.6 mmol/l. Plasma aluminum concentration decreased from 78.7 +/- 12.5 to 48.5 +/- 3.9 micrograms/l. Plasma PTH level increased from 2.0 +/- 0.7 to 3.3 +/- 0.8 ng/ml despite the concurrent increase in plasma calcium levels. All values returned to control levels following discontinuation of CaCO3 and resumption of aluminum gels. We conclude: (1) In addition to controlling hyperphosphatemia and increasing plasma calcium concentration, CaCO3 ameliorates metabolic acidosis. (2) Avoidance of oral aluminum intake is followed by prompt lowering of plasma aluminum levels. (3) PTH levels paradoxically increase despite the increment in plasma calcium concentration. The hypercalcemia seen with CaCO3 administration may be due, in part, to transient parathyroid hypersecretion that develops when aluminum administration is discontinued.     

High bone turnover associated with an aluminum-induced impairment of bone mineralization

A hemodialyzed patient showing x-ray and biochemical evidence of apparently pure severe hyperparathyroidism underwent a tetracycline-labeled transiliac bone biopsy. The bone biopsy not only confirmed the hyperparathyroid bone lesions but also revealed an impairment of bone mineralization induced by aluminum. This was demonstrated by a reduction of double-labeled osteoid surfaces, a significant increase in the osteoid seam thickness, and the presence of extensive aluminum deposits in bone. The planned parathyroidectomy was postponed, and deferoxamine (DFO) therapy, 2 g once a week, was initiated. A second bone biopsy, taken 6 months later, showed recovery of normal bone mineralization but the persistence of hyperparathyroid bone lesions. This was associated with a considerable reduction in the extent of aluminum deposits on trabecular bone surfaces. This observation shows that severe and apparently pure hyperparathyroidism can be associated with an impairment of bone mineralization induced by aluminum. This suggests that bone mineralization and aluminum overload should be evaluated in dialyzed patients who are being considered for parathyroidectomy.     

Efficacy and safety of long-term treatment with calcium carbonate as a phosphate binder

The efficacy and safety of calcium carbonate as a phosphate binder was evaluated in 20 patients on chronic hemodialysis who had previously received aluminum hydroxide. During the control period the patients were on aluminum hydroxide and calcitriol therapy and had plasma phosphorus levels less than 6 mg/dL (4.95 +/- 0.8 mg/dL). Aluminum hydroxide was then discontinued and no phosphate binder was prescribed for 1 month. Every patient developed hyperphosphatemia so that calcium carbonate treatment was begun and calcitriol dose was adjusted in relation to plasma calcium changes. After 24 months of calcium carbonate therapy, plasma phosphorus was 4.85 +/- 0.7 mg/dL, using a daily dose of calcium carbonate of 2.57 +/- 1.3 g (range, 1 to 6 g). The daily dose per patient of calcitriol was not different from that prescribed during the control period, but in five patients calcitriol was permanently withdrawn for hypercalcemia. At the end of the study plasma calcium, magnesium, bicarbonate, alkaline phosphatase, and parathyroid hormone values were unchanged in comparison with the control period, whereas a significant reduction in plasma aluminum and plasma aluminum increase induced by deferoxamine infusion was observed. The frequency of hypercalcemic and hyperphosphatemic episodes during the last 12 months of calcium carbonate therapy (6.2% and 16.6%, respectively) was not different from that observed during the 12 months on aluminum hydroxide therapy preceding the control period (4.5% and 14.7%, respectively). It was concluded that calcium carbonate is effective in the control of hyperphosphatemia and secondary hyperparathyroidism in patients on chronic hemodialysis and that the incidence of hypercalcemia is low when the daily dosage is less than 6 g.     

Effect of parathyroidectomy on aluminum toxicity and azotemic bone disease in the rat

In maintenance dialysis patients, low-turnover osteomalacia and aplastic bone disease are generally attributed to aluminum toxicity. Both groups of patients have a relative deficiency of PTH. The reason for the development of osteomalacia versus aplastic bone disease is unclear. The present study was performed to evaluate whether parathyroidectomy (PTX) modifies the effect of aluminum administration on bone histology in renal failure. Seven groups of pair-fed rats were studied: normals (N); renal failure (RF); RF + PTX; PTX; RF + aluminum (AL); RF + PTX + AL; and PTX + AL. Aluminum was administered intraperitoneally 5 days/week for 6 weeks. All groups were sacrificed at 6 weeks. Renal failure increased the serum calcium in both the parathyroid intact (RF versus N, 11 +/- 0.1 versus 10 +/- 0.3 mg/dl, X +/- SEM, P less than 0.05) and calcium-supplemented PTX groups (PTX + RF versus PTX, 9.7 +/- 0.2 versus 9.2 +/- 0.2 mg/dl, P less than 0.05). After PTX, aluminum administration increased the serum calcium (PTX + AL versus PTX, 9.8 +/- 0.3 versus 9.2 +/- 0.2, P less than 0.05, and PTX + RF + AL versus PTX + RF, 10.8 +/- 0.1 versus 9.7 +/- 0.2 mg/dl, P less than 0.05). In rats with renal failure receiving aluminum, PTX decreased osteoid volume and surface but not osteoid thickness. Rats receiving aluminum did not mineralize bone. Additionally, in PTX rats receiving aluminum, renal failure per se increased osteoblast surface, osteoid surface, osteoid volume, and osteoclast number.(ABSTRACT TRUNCATED AT 250 WORDS)     

Bone mineral density and histology in distal renal tubular acidosis

BACKGROUND: Chronic metabolic acidosis in distal renal tubular acidosis (RTA) has been implicated in the pathogenesis of enhanced bone resorption and osteopenia, resulting in a loss of bone mineral content. However, histomorphometric and bone densitometric studies of patients who suffered from long-standing distal RTA have rarely been done. METHODS: A cross-sectional study to determine the alterations of bone mineral density (BMD) and histology was done in 14 nonazotemic RTA patients (11 females and 3 males) who had never received alkaline therapy before enrolling into this study. The mean age was 32.7 +/- 11.9 years. BMD measurements and transiliac bone biopsy were done in all patients. Blood chemistries, intact parathyroid hormone level, and a 24-hour urine collection for the determination of urinary calcium, phosphate, sodium, and potassium were obtained from the RTA patients at the time of bone biopsy. Data from 28 age-, sex-, and body mass index-matched, normal controls who were residents in the same area were also obtained. RESULTS: Urinary excretion of calcium was 2.05 +/- 1.59 mmol/day. No patient had hypercalciuria. The serum intact parathyroid hormone level was 15.92 +/- 8.48 pg/mL. RTA patients had lower BMD in most areas when compared with normal controls. There were two patients who suffered from a pathologic fracture at the femur. Bone histomorphometry from RTA patients shows a significantly decreased bone formation rate (0.02 +/- 0.02 vs. 0.07 +/- 0.045 microm(3)/microm(2)/day, P < 0.05), not significantly decreased osteoblastic surface (0.78 +/- 1.03% vs. 2.6 +/- 1.1%) and osteoclastic surface (0.05 +/- 0.03 vs. 0.13 +/- 0.23%), but significantly increased osteoid surface (31.47 +/- 24.52 vs. 5.79 +/- 4.39%, P < 0.05) and osteoid volume (2.95 +/- 3.09 vs. 0.92 +/- 1.05%, P < 0.05) when compared with those of normal controls. There was no difference in osteoid thickness (10.65 +/- 6.10 vs. 8.69 +/- 2.14 microm). Only one distal RTA patient who had a marked increase in osteoid thickness justified the diagnosis of osteomalacia. CONCLUSIONS: This study demonstrates that low bone mass is common in distal RTA patients. Chronic metabolic acidosis results in suppression of bone formation and resorption, which in turn may contribute to the development of low bone mass in distal RTA patients. Although minor elevations in osteoid surface and osteoid volume are found among distal RTA patients, overt osteomalacia is not the predominant bone lesion.     

Bone turnover and 1,25-dihydroxycholecalciferol during treatment with phosphate binders

The effect of dietary phosphate restriction with high-dose aluminum hydroxide or calcium carbonate on bone disease assessed by histomorphometry and on the plasma levels of 1,25-dihydroxycholecalciferol was investigated in 12 children with chronic renal failure (GFR 8 to 45 ml/min/1.73 m2, age 5 to 15 years) over a one year period. Prior to treatment patients had biochemical and histological hyperparathyroidism with greatly increased bone formation rates. During treatment, plasma phosphate levels decreased from the upper to the lower limit of normal for age (pre, 1.69 +/- 0.06 mmol/liter; 6 months, 1.28 +/- 0.06 mmol/liter; 1 year, 1.34 +/- 0.06 mmol/liter; P less than 0.01). Circulating 1,25-dihydroxycholecalciferol rose to supranormal levels within three months and remained high throughout the period of study (pre, 96 +/- 32 pmol/liter; 6 months, 144 +/- 46 pmol/liter; 1 year, 169 +/- 53 pmol/liter; P less than 0.001). Significant falls in bone formation rate at tissue and cellular levels (P less than 0.005) and in total resorption surface (P less than 0.005) were observed. A mild mineralization defect present before treatment worsened, with a decrease in mineral appositional rate (P less than 0.01) and increase in mineralization lag time (P less than 0.01). Staining for aluminum in post-treatment biopsies was positive in 9 of 11 cases. Phosphate restriction produced suppression of biochemical and histological hyperparathyroidism and sustained elevation of circulating 1,25-dihydroxycholecalciferol. The adverse changes in bone mineralization may be related to aluminum hydroxide therapy; calcium carbonate is therefore recommended.     

Can low-dosage aluminium hydroxide control the plasma phosphate without bone toxicity?

Sixteen patients treated exclusively by haemodialysis using reverse osmosis water treatment for up to 7 years (mean 49.3 +/- 17 months) were assessed for evidence of bone aluminium accumulation and toxicity. All patients were treated with aluminium hydroxide phosphate binders for the duration of dialysis but the dosage was restricted to a maximum of 2.85 g daily (mean daily dose 2.6 +/- 0.8 g). The mean plasma phosphate over the 12 months prior to the study was 1.68 +/- 0.42 mmol/l and in only three patients was adequate control of the plasma phosphate not achieved. No patient had evidence of fracturing bone disease. Bone aluminium staining was present in only two patients but was seen at the calcification front in only one of these. Three patients had histological evidence of osteomalacia, but in none was aluminium staining present. Mean bone aluminium was moderately high at 36.67 +/- 31 micrograms/g and in only three patients exceeded 40 micrograms/g. This study indicates that adequate control of the plasma phosphate can be achieved with low dosage of aluminium hydroxide, and in the medium term is not associated with evidence of bone aluminium toxicity.     

The effect of hemodialysis, vitamin D metabolites and renal transplantation on the skeletal demineralization associated with renal osteodystrophy: a computerized histomorphometric analysis

Twenty-three patients with end-stage renal failure treated by hemodialysis or transplantation were followed for up to 10 years. Sequential full thickness iliac crest bone biopsies were obtained to assess the effects on bone disease of hemodialysis, treatment with 1,25-dihydroxycholecalciferol [1,25-(OH)2D3] and 24,25-dihydroxycholecalciferol [24,25-(OH)2D3] and renal transplantation. The biopsies were analyzed by a computerized histomorphometric technique which allowed accurate measurements of calcified bone and osteoid areas. Serum aluminum and parathyroid hormone concentrations were also monitored. Hemodialysis was associated with a loss of calcified bone and an increase in osteoid areas. The progressive bone loss was arrested but not reversed following treatment with either 1,25-(OH)2D3 or 24,25-(OH)2D3. Osteoid area was unchanged or reduced following treatment with 1,25-(OH)2D3 in all but three patients who had serum aluminum concentrations in excess of 5 mumol/l. 24,25-(OH)2D3 was not effective in reducing osteoid area, and combined treatment with 1,25 and 24,25-(OH)2D3 had no effect beyond that expected with 1,25-(OH)2D3 alone. Bone biopsies showed loss of calcified bone and an increase in osteoid areas one year and more after successful renal transplantation in five patients. Nineteen of the 23 patients developed serum aluminum concentrations greater than 3 mumol/l, probably because of the use of oral aluminum hydroxide as a phosphate binding agent. In these patients serum parathyroid hormone concentrations greater than 600 pg/ml appeared to prevent the development of osteopenia.     

Sporadic aluminum osteomalacia: identification of patients at risk

Chronic dialysis patients at risk for aluminum osteomalacia in areas of low water-aluminum content are not well identified. We, therefore, studied retrospectively a cohort of 59 patients who underwent bone biopsy at two hospital-based dialysis centers in Montreal (water aluminum content less than 10 micrograms/L). Overall, 25% of patients biopsied had aluminum-related osteomalacia defined by aluminum staining of more than 30% of the trabecular surface and low levels of bone formation as measured by tetracycline labeling. Multiple linear regression analysis showed high predialysis serum creatinine (P less than .05) and the amount of aluminum prescribed per month (P less than .05) as the most important determinants of aluminum staining. We conclude that aluminum-related osteomalacia can be a frequent disease entity in areas of low water-aluminum content. Our findings also suggest predialysis serum creatinine and the amount of aluminum prescribed per month are risk factors for the development of aluminum-related osteomalacia. Though the relationship between serum creatinine and aluminum staining of trabecular bone is unclear, serum creatinine is probably a marker for adequacy of dialysis in these patients.     

Aluminum-related bone disease in mild and advanced renal failure: evidence for high prevalence and morbidity and studies on etiology and diagnosis

To study aluminum-related bone disease, bone biopsies and serum biochemical measurements were done in 97 patients on maintenance dialysis and in 100 patients with mild to moderate renal failure. Bone histology, histochemical staining for aluminum and determination of bone aluminum content were done. Stainable bone aluminum was found in 50% of dialyzed patients and in 5% of nondialyzed patients. The finding of stainable bone aluminum in dialyzed patients was associated with high morbidity and mortality; it was not only seen in most patients with low turnover osteomalacia, but also in 47% of patients with mixed uremic osteodystrophy and in 1 patient with predominant hyperparathyroid bone disease. Patients with stainable aluminum had lower bone mass and decreased activity of bone-forming and -resorbing cells. Cumulative doses of aluminum-containing phosphate binders were a major risk factor. Aluminum in drinking water represents an additional risk factor. Neither serum biochemical tests nor single infusion of deferoxamine could be employed as diagnostic tools. Bone biopsies were the only means for diagnosis.     

Stainable aluminum and not aluminum content reflects bone histology in dialyzed patients

Quantitative evaluation of stainable bone aluminum and measurement of bone aluminum content were done in 55 patients on chronic maintenance dialysis. All patients underwent bone biopsies. Histomorphometry of static and dynamic parameters of bone structure, bone formation and resorption, and quantitation of stainable bone aluminum at the osteoid-bone interface were performed. In addition, bone aluminum content was measured by atomic absorption spectrophotometry. Bone aluminum content was elevated in all patients (81 +/- 9.6 vs. 18 +/- 6 micrograms/g dry wt) and stainable aluminum was found in 47% of them. All patients with predominant low-turnover osteomalacia or adynamic bone disease displayed stainable bone aluminum. In contrast, stainable bone aluminum was not present in individuals with predominant-hyperparathyroid bone disease. Patients with stainable aluminum had lower bone mass (P less than 0.05), higher volume and surface of lamellar osteoid (P less than 0.01), less volume and surface of woven osteoid (P less than 0.05 and P less than 0.01), lower osteoblastic and osteoclastic indices (P less than 0.01), less doubly labelled osteoid seams, lower mineral apposition rate and lower bone formation rates (P less than 0.05 to P less than 0.01). Stainable aluminum correlated with volume of lamellar osteoid and cellular parameters of bone formation and resorption, mineral apposition rate, and bone formation rates (P less than 0.05 to P less than 0.001). In contrast, bone aluminum content correlated with volume of lamellar osteoid only (P less than 0.001). These findings indicate that stainable aluminum at the mineralization front and not aluminum content of bone reflects the histopathologic changes found in bone of dialyzed patients.     

Aluminum alters calcium influx and efflux from bone in vitro

Aluminum retention can cause osteomalacia and adynamic lesions of bone in patients undergoing long-term dialysis. It is not known, however, whether aluminum inhibits the mineralization of bone directly or whether alterations in osteoblastic function mediate this response. To examine this issue, the uptake of 45Ca by 14-day embryonic chick calvaria was measured in vitro. Comparative studies were done in living and devitalized tissues to evaluate the role of bone cells in aluminum-related changes in 45Ca uptake. Aluminum was added to serum-free media as the citrate complex, and paired hemicalvaria maintained in equimolar sodium citrate served as controls. Aluminum citrate decreased the uptake of 45Ca into bone during 24 hour incubations to 76 +/- 3% and 38 +/- 2% (x +/- SD) of control values at 10 microM and 100 microM aluminum, respectively. No change in 45Ca uptake was observed at the end of four hour incubations with 100 microM aluminum citrate, whereas 45Ca uptake decreased from 356 +/- 48 to 266 +/- 36 cpm/micrograms bone, P less than 0.05, at eight hours and from 327 +/- 22 to 269 +/- 41 cpm/micrograms bone, P less than 0.05, at 24 hours. The inhibitory effects of 10 microM and 100 microM aluminum on 45Ca uptake were eliminated, however, in devitalized tissues, and reductions in 45Ca uptake during incubations with aluminum were markedly attenuated by lowering the media phosphorus level from 4.0 mM to 2.0 mM.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of aluminum and parathyroid hormone on osteoblasts and bone mineralization in chronic renal failure

Bone aluminum, quantitative bone histology, and plasma parathyroid hormone (PTH) were compared in 29 patients undergoing chronic hemodialysis. Histologic techniques included double tetracycline labeling and histochemical identification of osteoclasts and osteoblasts. Bone aluminum was measured chemically by flameless atomic absorption spectrophotometry, and histochemically. When measured chemically, the bone aluminum was 67 +/- 46 (SD) mg/kg dry weight (normal 2.4 +/- 1.2 mg/kg); histochemically, aluminum was present at 2.9 +/- 4.4% of trabecular surface. The biochemical and histochemical results agreed well (r = 0.80, P less than 0.001). No double tetracycline labels were seen at the mineralization front where aluminum was deposited, indicating cessation of mineralization at these sites. The osteoblast surface correlated positively with plasma PTH (r = 0.67, P less than 0.001) and negatively with bone aluminum level (r = -0.42, P less than 0.05). Multiple linear regression showed a correlation of aluminum with osteoblasts additional to that of PTH, consistent with a direct effect of aluminum in depressing osteoblast numbers. Though a relationship between PTH and chemically determined bone aluminum level could not be demonstrated, there was a negative correlation between osteoclast count and aluminum, and the nine patients with severe hyperparathyroid bone disease had lower chemically determined aluminum levels than the other patients. These results suggest that aluminum (a) directly inhibits mineralization, (b) is associated with decreased PTH activity and hence osteoblast numbers, and (c) directly reduces osteoblast numbers. In addition to inducing severe, resistant osteomalacia, aluminum appears to contribute to the mild osteomalacia commonly seen in renal failure, characterized by extensive thin osteoid and low tetracycline and osteoblast surfaces.     

Continuous ambulatory peritoneal dialysis and bone

We studied the effects of continuous ambulatory peritoneal dialysis (CAPD) on the histological manifestations of uremic bone disease. Twelve patients underwent bone biopsy immediately prior to and after one year of such treatment. Those with larger quantities of non-mineralized bone matrix (osteoid) experienced a reduction in relative osteoid volume, mean osteoid seam width, and total osteoid surface. Moreover, the use of time-spaced kinetic markers of mineralization (tetracycline) enabled us to demonstrate that CAPD usually decreased the amount of non-mineralized bone matrix by shortening mineralization lag time (that is, the interval from organic matrix deposition to its mineralization). The changes in the histomorphology appeared to occur independently of bone aluminum. These data indicate that CAPD generally enhances the mineralizing capacity of individual osteoblasts and suggests that such therapy is beneficial to the uremic skeleton.     

The role of aluminum in the pathogenesis of anemia in an outpatient hemodialysis population

Anemia is a well-defined complication of aluminum overload in chronic dialysis patients which may be present before other manifestations of aluminum toxicity are obvious. Causes of anemia in chronic renal failure are multiple, and at the present time there is no marker for aluminum-induced anemia. Deferoxamine (DFO) treatment can correct aluminum-related anemia and microcytosis, but may be associated with side effects. Because of the possible role of aluminum in red blood cells in causing the anemia associated with aluminum overload, we attempted to test red blood cell (RBC) aluminum as a marker for aluminum-associated anemia and to assess the prevalence of aluminum-associated anemia in an outpatient dialysis population. Both random plasma aluminum and RBC aluminum correlated well with the increase in plasma aluminum seen following DFO challenge. However, RBC aluminum was affected less by changes in oral aluminum intake than plasma aluminum. There were strong correlations of RBC and plasma aluminum to corpuscular volume (MCV) in our patients. Moreover, patients within the highest quartile of RBC aluminum had a lower mean MCV (82.1 +/- 1.7 vs 89.6 +/- 1.7, p less than .01) and hematocrit (HCT) (24.3 +/- 4 vs 28.2 +/- 1.5, p less than .05) than those within the lowest quartile. These data suggest that aluminum toxicity is an important cause of microcytic anemia in outpatient hemodialysis patients. Prospective long-term studies are needed to further define the usefulness of RBC aluminum in diagnosing and following hemodialysis patients with aluminum-induced anemia.