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.     

Metabolic acidosis aggravation and hyperkaliemia in hemodialysis patients treated by sevelamer hydrochloride

Reports on acid-base side effects of sevelamer hydrochloride (SH), a new aluminum (Al)- and calcium (Ca)-free phosphate binder are rare and conflicting. In a retrospective analysis, we evaluated SH impact on metabolic acidosis and serum potassium (K) in hemodialysis (HD) patients. Two groups of stable HD patients were studied. Group A included 17 patients, M/F=15/2, 64 (42-80) years old, dialyzed since 130 (34-253) months, under SH for 24 months. Group B serving as controls was made of 7 patients, M/F=4/3, 67 (48-91) years old, dialyzed since 67 (27-174) months, under CaCO3 and/or Al(OH)3 as phosphate binders also for 24 months. Bicarbonate (BIC), K, Ca, phosphorus (P), Ca x P, alkaline phosphatase (ALP), and intact parathyroid hormone (iPTH) were recorded before (MO) and at the end (M24) of 24-month SH or CaCO3-Al(OH)3 treatment in group A and B patients. In group A, BIC fell from 20.02 +/- 1.43 to 17.89 +/- 2.30 mEq/ L, P=.002; and K rose from 5.45 +/- 0.51 to 5.75 +/- 0.49 mEq/L, P=0.02. In group B, BIC (19.8 +/- 3.03 to 19.0 +/- 3.3 mEq/L) and K (5.01 +/- 0.8 to 4.9 +/- 1.1 mEq/L) had nonsignificant changes. In group A, iPTH rose from 132.82 +/- 124.08 to 326.89 +/- 283.91 pg/mL, P=.0008; P fell from 5.92 +/- 1.48 to 4.9 +/- 1.01, P=.02; and Ca x P decreased from 52.04 +/- 9.7 to 45.58 +/- 10.42 mg2/dL2, P=.04. In group B, changes in iPTH from 240.71 +/- 174.7 to 318.57 +/- 260.2 pg/mL, P from 4.9 +/- 0.5 to 4.8 +/- 1.3 mg/dL, and CaxP product from 44.3 +/- 6.6 to 44 +/- 11.2 mg2/dL2 were nonsignificant. The changes observed in Ca and ALP in both groups were nonsignificant. Correlations in group A between metabolic acidosis (BIC) and SH doses, or iPTH and BIC, Ca, or P changes, were also found to be nonsignificant. Long-term use of SH, effectively controlling serum P levels and Ca x P values, is associated with acidosis aggravation and hyperkaliemia. Worsening of secondary hyperparathyroidism, also noted, needs to be confirmed and could be related to Ca/Al salt discontinuation and to metabolic acidosis aggravation itself.     

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.     

Parathyroid hormone response to hypocalcemia in hemodialysis patients with osteomalacia

The parathyroid hormone response to hypocalcemia was investigated in hemodialysis patients with osteomalacia and compared to those with osteitis fibrosa. Hypocalcemia was induced during hemodialysis by employing a dialysate devoid of calcium. Patients with osteomalacia had a blunted maximum amino terminal parathyroid hormone response (+/- SD) (0.39 +/- 0.33 vs. 0.87 +/- 0.53 ng/ml, P less than 0.05) and maximum carboxy terminal parathyroid hormone response (+/- SD) (0.36 +/- 0.20 vs. 0.84 +/- 0.47, P less than 0.02) to hypocalcemia. The decline in plasma calcium was greater in patients with osteomalacia at 90 (P less than 0.05), 120 (P less than 0.01), and 150 min (P less than 0.01). In osteomalacia patients the surface density of histologically detectable trabecular bone aluminum correlated directly with the percent relative osteoid volume (P less than 0.005) and inversely with the maximum amino terminal parathyroid hormone response to hypocalcemia (P less than 0.025). These results suggest that hemodialysis patients with osteomalacia have diminished secretion of parathyroid hormone and a decreased ability to restore plasma calcium homeostasis during hypocalcemia.     

Differential diagnosis between secondary hyperparathyroidism and aluminum intoxication in uremic patients: usefulness of 99mTc-pyrophosphate bone scintigraphy

Forty-one patients in chronic end-stage renal failure and 4 patients with a functioning kidney transplant presented with spontaneous hypercalcemia or intolerance to vitamin D3 sterols and/or oral calcium supplements. Bone iliac crest biopsy with aluminum staining and Tc-pyrophosphate bone scintigraphy with determination of Fogelman score were performed in all cases. Two patients had aluminum-induced osteomalacia (AL O). Thirty-eight biopsies showed renal osteodystrophy (secondary hyperparathyroidism or various combinations of osteitis fibrosa and osteomalacia): 19 with positive staining for aluminum (RO + AL) and 19 without aluminum deposits (RO). The series also comprised 2 cases of pure osteomalacia (OM), 2 cases of osteoporosis (OP), and 1 case of osteoporosis with aluminum accumulation (OP + AL). Mean Fogelman score in RO patients (9.1 +/- 0.3) was significantly higher than in all other categories (5.9 +/- 0.5 for RO + AL, and scores ranging from 0 to 8 in the last 7 patients, p less than 0.01). Patients with massive aluminum accumulation in bone (greater than 75% of the total trabecular surface) showed no or very low uptake of the isotope by the skeleton. Fogelman scores of 9 or higher were always associated with histological secondary hyperparathyroidism. 99mTc-pyrophosphate bone scintigraphy is helpful to distinguish aluminum intoxication from secondary hyperparathyroidism in uremic patients.     

Plasma bone-specific alkaline phosphatase changes in hemodialysis patients treated by alfacalcidol

Vitamin D derivatives correct high bone remodeling by decreasing plasma iPTH concentration in uremic patients with secondary hyperparathyroidism. However, without bone biopsy, plasma iPTH alone might not provide sufficient information regarding vitamin D-induced bone changes. Plasma bone-specific alkaline phosphatase (bAP) seems more sensitive than iPTH in assessing the degree of bone remodeling. We prospectively studied the evolution of iPTH and bAP in 14 adult hemodialysis patients treated for 1 year by i.v. alfacalcidol pulses. The mean total alfacalcidol dose was 0.08 +/- 0.02 g/kg/week. Ten patients completed the study, 2 patients had to be parathyroidectomized before week 24 because of hypercalcemia and uncontrolled hyperphosphatemia, and 2 other patients died before week 36. Mean iPTH levels diminished from 826 +/- 300 pg/ml (range 507 - 1,500 pg/ml) at baseline to 436 +/- 371 pg/ml (range 18 - 1,095 pg/ml) after 52 weeks of treatment (48% of decrease). Only 2 patients normalized plasma iPTH levels while 8/10 normalized bAP. Five patients remained with plasma iPTH concentrations higher than 5-fold the normal value. In contrast, plasma bAP levels declined from 47.6 +/- 32.2 ng/ml (range 15.4 - 130.0 ng/ml) at baseline to 17.8 +/- 9.9 ng/ml (range 8.0 +/- 38.0 ng/ml) at week 52 (63% of decrease). Bone histomorphometry was available in 6 patients after 15.8 +/- 5.1 months of alfacalcidol treatment. None of them met the criteria of adynamic bone disease as they had increased bone resorption and marrow bone fibrosis. Bone formation rate was normal in 2 patients and unmeasurable in the other 4. Two patients showed signs of osteomalacia. In conclusion, alfacalcidol preferentially reduced bone formation rate rather than the other histological parameters of secondary hyperparathyroidism. It reduced plasma bAP more efficiently than iPTH.     

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)     

The effects of metabolic acidosis on bone formation and bone resorption in the rat

Metabolic acidosis (MA) has been implicated in the pathogenesis of both osteomalacia and osteopenia. Alterations in the secretion of parathyroid hormone and in the metabolism of vitamin D may contribute to such skeletal changes. To minimize the influence of these factors, quantitative bone histology and measurements of bone formation using double tetracycline labeling were done in thyroparathyroidectomized (TPTX) rats with MA induced by ammonium chloride (TPTX-A), and in both non-acidotic TPTX (TPTX-C) and intact (C) controls. To evaluate the response of both cortical and trabecular bone to MA, histologic studies were done at three separate sites in the tibia, cortical bone from the mid-shaft, and trabecular bone from the epiphysis and from the metaphysis. Plasma pH was lower in TPTX-A, 7.24 +/- 0.10, than in either TPTX-C, 7.39 +/- 0.03, or C, 7.43 +/- 0.04, P less than 0.01, and urinary hydroxyproline excretion increased from 89.8 +/- 8.7 in TPTX-C to 150.2 +/- 25.9 micrograms/mg/creatinine in TPTX-A, P less than 0.01. Resorption surface at the epiphysis increased from 1.8 +/- 0.6% in TPTX-C to 4.0 +/- 1.6% in TPTX-A, P less than 0.05, values not different from those in C, 3.1 +/- 1.1%. Resorption surface was unchanged at other skeletal sites, but total bone volume at the metaphysis fell from 15.5 +/- 5.6% in TPTX-C to 9.0 +/- 4.3% in TPTX-A, P less than 0.05. Bone formation was reduced at each skeletal site in TPTX-A vs. TPTX-C, P less than 0.05 for all values, but histologic evidence of osteomalacia was not observed.(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.     

Iron overload and bone disease in chronic dialysis patients

Bone pathology was studied in 27 patients showing either iron or aluminium accumulation in bone. These patients belonged to a group of 120 unselected chronic haemodialysis patients in whom transiliac bone biopsies had been obtained. Group A consisted of 12 patients with bone iron deposits (positive Perls' staining at the calcified bone boundary, CBB) and only minimal aluminium accumulation (bone aluminium below 20 micrograms/g wet weight). Group B included 15 patients with pronounced aluminium accumulation (positive aluminium staining at the CBB and bone aluminium of 20 micrograms/g wet weight or more) and without significant bone iron deposition (negative Perls' staining at the CBB). Bone diseases were classified as early hyperparathyroidism, osteitis fibrosa, mixed disease, osteomalacia, adynamic bone disease or other bone condition using osteoid volume, relative osteoblastic activity (ROBA%), and the presence of fibrosis, as criteria. In group A, 5 of 12 patients showed adynamic bone disease, a fairly uncommon condition in the general population of non-parathyroidectomised dialysis patients. In fact, in a control group of 80 patients without iron and without aluminium overload, only five patients showed adynamic bone disease. In group B, 8 of 15 patients showed osteomalacia, and 2 of 15 presented with mixed disease, which is in agreement with the established relationship between bone aluminium accumulation and the occurrence of defective bone mineralisation. It is concluded that iron overload in dialysis patients is associated with an increased frequency of adynamic bone disease.     

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.     

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)     

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)     

Cortical v trabecular bone aluminum in dialyzed patients

Differences among measurement of cortical and trabecular bone aluminum (AI) have been observed. Furthermore, its relationship to bone histology has been variable. In order to clarify these points, we have evaluated measurements of bone AI in relation to the source of AI and bone lesion in 25 hemodialysis patients. All patients were dialyzed in the same unit since commencement of dialysis and treated by the same physician. Age of the patients ranged from 29 to 66 years; mean duration of dialysis was 6.6 +/- 3.5 years. Dialysate water has been treated by reverse osmosis since 1980. Bone biopsy was performed in all patients after double tetracycline labeling. AI was measured biochemically in cortical bone (bCAI) and histochemically in trabecular (TAI) and cortical bone (CAI). Mean serum AI (36 +/- 21 micrograms/L) and bCAI (59 +/- 44 micrograms/g) were increased. There were significant correlations between: cortical AI and (1) serum AI (r = 0.71, p less than 0.001); (2) duration of dialysis with softened water (AI content, 55 +/- 21 micrograms/L, r = 0.65, P less than 0.001) but not with total duration of dialysis; and (3) AI ingested since commencement of dialysis (r = 0.57, P less than 0.01). Trabecular AI was not correlated with any of these parameters. None of cortical AI measurements were correlated with bone formation rates (BFR), osteoblastic surfaces (ObS), and resorption surfaces (RS) determined on trabecular bone. However, trabecular AI was inversely correlated with BFR (P less than 0.01) and ObS (P less than 0.05). Serum parathyroid hormone (PTH) was positively correlated with BFR (P less than 0.001) and RS (P less than 0.001).(ABSTRACT TRUNCATED AT 250 WORDS)     

Iron overload and mobilization in long-term hemodialysis patients

Iron overload from repeated transfusions of RBCs in long-term hemodialysis patients is a problem of increasing clinical significance. We report on the prevalence of and diagnostic criteria for identification of hemodialysis patients with iron overload. In 150 unselected hemodialysis patients, 62 (41%) had ferritin levels greater than 2,000 ng/mL (normal = 10 to 360 ng/mL). In 16 of these patients, accurate transfusion histories were obtained and ferritin levels correlated with calculated transfusional iron burden (r = 0.553, P less than .05). These patients could be divided into two distinct groups on the basis of their response to a single dose (2 g, IV) of deferoxamine: "high" responders had twice the level of feroxamine (the chelated product of deferoxamine and iron) of the "low" responders (P less than .001). High responders also had significantly higher prevalence of the "hemochromatosis" alleles A3, B7, and B14 than a large group of dialysis patients awaiting transplantation (71% v 37%, P less than .001). In two patients with iron overload and clinically significant bone disease, bone histology revealed prominent iron staining at the calcification front. We conclude that transfusional iron overload is a significant clinical problem in long-term hemodialysis patients, that may also be associated with bone pathology.     

Long-term effects of small doses of calcitriol in hemodialysis patients with moderate secondary hyperparathyroidism

Prevention of secondary hyperparathyroidism (SHPTH) and treatment of the moderate cases by small p.os doses of Vitamin D has not been thoroughly investigated on the long term, while large doses of Vitamin D have been successful in the short term treatment of this entity. We administered calcitriol p.os 0.5-1.0 microgram, according to iPTH levels, after each dialysis session, in 19 patients (group A) for 36 months. They were ten men and nine women, 63 years old (43-81), with iPTH levels > 4N (419 +/- 185 pg/mL). Seven adenomas were found in five of them (group A1). Serum Ca, phosphate (P) and alkaline phosphatase (AP) were measured every 15-30 days. Serum iPTH and aluminum as well as echogram or scanning of the parathyroid glands were checked every 6 months. Ten additional dialysis patients, seven men and three women, 54.5 years old (36-68), non-significantly different to group A in iPTH levels (290 +/- 225 pg/mL) with three adenomas in two of them (group B1) received no calcitriol and served as controls (group B). Calcitriol treatment significantly lowered serum iPTH levels in group A patients (from 419 +/- 185 to 173 +/- 142 pg/mL, p < 0.0001, delta iPTH: -246 +/- 161 pg/mL); iPTH remained stable in group B patients (delta iPTH: +7.9 +/- 116 pg/mL) with an intergroup significant difference at P < 0.0001. All other parameters measured did not show any significant change. No significant correlation of iPTH to Ca, P or AP was found in A. Initial iPTH levels were higher in A1 and B1 patients and decreased by calcitriol in A1 group. Adenomas in A1 patients did not change in number and size in contrast to B1 where new adenomas appeared (5 patients, 10 glands). Small doses of vitamin D lower high iPTH levels and prevent parathyroid gland hyperplasia. Existing hypertrophy is stabilized under calcitriol treatment both morphologically and biologically.     

Low serum iron concentration in acute cholecystitis. A discriminator of severity of infection

This study demonstrates that serum iron levels are significantly depressed during acute cholecystitis. Mean admission serum iron concentration for 18 patients who had required emergency cholecystectomy within 48 hours of hospitalization was 40.9 micrograms/100 ml +/- 27.08 (7.32 mumol/l) while for 108 patients who had undergone elective cholecystectomy in the same 18-month period the mean concentration was 90.5 micrograms/100 ml +/- 34.27 (16.2 mumol/l); a mean difference of 49.6 micrograms/100 ml (3.92 mumol/l) (t = 5.8395, P less than 0.00001). Mean serum iron level in seven patients with culture positive acute cholecystitis was 26.4 micrograms/100 ml +/- 10.45 (4.73 mumol/l), significantly different (P less than 0.05) than in 11 patients with culture negative cholecystitis, 50.3 micrograms/100 ml +/- 30.41 (9.00 mumol/l). Admission serum iron level averaged 25.6 micrograms/100 ml (4.58 mumol/l) in three patients with gangrenous gallbladders and was 18 micrograms/100 ml (3.22 mumol/l) in one patient with empyema of the gallbladder. Determination of serum iron level may help distinguish patients with significant infections requiring urgent surgery from patients with biliary colic.     

Serum aluminum levels as a reflection of renal osteodystrophy status and bone surface aluminum staining.

Twenty eight (14%) out of 196 patients in a regional dialysis population were found to have serum aluminum levels greater than or equal to 5 mumol/L or 135 micrograms/L; 21 consented to undergo a bone biopsy to identify the spectrum of renal osteodystrophy associated with this degree of hyperaluminemia. Both the Aluminon reagent and the acid solochrome azurine (ASA) stain were used to identify aluminum deposits. A control group of 13 patients with biochemical and histological evidence of severe secondary hyperparathyroidism was used to contrast the measured parameters of bone histology in the hyperaluminemic group. Al(OH)3 was used as the principal phosphate binder in all patients. In the hyperaluminemic group, 67% had either dialysis osteomalacia or aplastic bone lesions, and all except one aplastic lesion were positive for bone surface aluminum deposits by the Aluminon stain. The Aluminon stain was also positive in one of three cases of osteitis fibrosa and three of four mild lesions, whereas it was negative in all biopsies from the control group. However, the ASA stain was positive in all biopsies from the hyperaluminemic group and in 11 of 13 control biopsies from the patients with "pure" osteitis fibrosa. For all biopsy data from both groups, there were significant (P less than 0.01) negative correlations between the ASA-stained surface aluminum deposits and resorption indices (total eroded surface, r = -0.68; surface osteoclast counts, r = -0.53) and indices of bone formation (surface osteoblast counts, r = -0.61; mineral apposition rate, r = -0.63; bone formation rate, r = -0.69). These correlations were not significant for Aluminon-stained surface deposits with the exception of the bone formation indices, which had lower correlation coefficients (r = -0.44). These data suggest that hyperaluminemia greater than or equal to 5 mumol/L has a predictive value to identify impaired mineralization in dialysis patients that is high enough to affect clinical decision making. However, the more sensitive ASA stain identifies surface aluminum across the whole spectrum of renal osteodystrophy and is consistent with a toxic role for aluminum at any level of exposure.     

Comparisons between oral pulse alfacalcidol therapy and daily therapy in maintenance hemodialysis patients with secondary hyperparathyroidism: a randomized, controlled, and multicenter study

OBJECTIVE: To investigate the efficacy and safety of 1alpha-(OH)-D3 high-dose pulse therapy or daily low-dose therapy in secondary hyperthyroidism in maintenance hemodialysis patients in China. METHODS: Maintenance hemodialysis patients of both gender with intact parathyroid hormone (iPTH) level above 200 pg/mL were randomly divided into a pulse group and a daily group. They were treated for 20 weeks, with 2 microg oral Alfacalcidol twice weekly or thrice weekly in the pulse group, and 0.5 microg oral Alfacalcidol per day in the daily group. The therapeutic end point was parathyroid hormone level < 200 pg/ mL. The iPTH levels during the study were monitored, and parameters representative of calcium and phosphate metabolism and side effects were also observed. RESULTS: One hundred and fifty-eight patients were initially enrolled, 91 in the pulse therapy group and 67 in the daily therapy group. There was no significant difference in age, hemodialysis duration, proportion of diabetic nephropathy and systemic diseases, proportion of patients who had received active vitamin D therapy previously, mean initial iPTH level (pulse group 570.47 +/- 295.86 pg/mL; daily group 498.33 +/- 207.84 pg/mL), serum calcium, serum phosphate, alkaline phosphatase (AKP), and albumin between two groups. In the pulse therapy group there were more patients with iPTH levels of 500 to approximately 1,000 pg/mL and > 1,000 pg/mL, so stratified analysis according to iPTH level was used. In therapeutic end point, iPTH levels in both groups were significantly lower compared with those before therapy (pulse group 261.29 +/- 234.97 pg/mL, P < .01; daily group 262.17 +/- 274.82 pg/mL, P < .01). After 4 weeks, the ratio of reaching end point in the pulse group was 35.2%, which was significantly higher than that (19.4%) in the daily group (P < .05). More obvious change was seen in the 200 to approximately 500 pg/mL subgroup by stratified analysis (P < .05), whereas there was no significant difference between the 500 to approximately 1,000 pg/mL and > 1,000 pg/mL subgroup (P > .05). At therapeutic end point, the total ratio of reaching end point did not differ between the two groups, and there were no obvious differences between each subgroup. In the iPTH 200 to approximately 500 pg/mL subgroup, mean iPTH%/week in the pulse group was significantly higher than that in the daily group, and no obvious difference was seen in other subgroups. AKP levels decreased significantly in both groups at therapeutic end point (pulse group 98.42 +/- 54.52 vs. 74.21 +/- 30.68 IU/L, P < .01; daily group 103.3 +/- 68.04 vs. 75.40 +/- 34.12 IU/L, P < .01). On the 4th week, AKP level in pulse group (82.39 +/- 35.23 IU/L) was significantly lower than the initial level (98.42 +/- 54.52 IU/L, P < .05), whereas in the daily group there was no difference between each week. The mean serum calcium, phosphate, and [Ca2+] x [P3+] levels in both groups did not change greatly. Nine patients in the pulse group (9.9%) and 8 patients in the daily group (11.9%) suffered hypercalcemia at least once. Persistent hypercalcemia occurred in 8 patients in the pulse group (8.8%) and 9 patients in the daily group (13.4%), but the difference in proportion did not show statistical significance. The serum phosphate in the daily group was higher after the therapy (1.74 +/- 0.36 vs. 1.89 +/- 0.36 mmol/L, P < .05), whereas that in the pulse group remained unchanged. At therapeutic end point, [Ca2+] x [P3+] level in the daily group was higher than that before the therapy (48.04 +/- 11.71 vs. 55.46 +/- 12.66, P < .05), whereas in the pulse group there was no significant difference. Side effects for both groups were minimal and well tolerated. CONCLUSIONS: Alfacalcidol [1alpha-(OH)-D3] has good and safe effects on secondary hyperparathyroidism in maintenance hemodialysis patients. The efficacy and early effects of pulse therapy are superior to those of daily therapy in moderate hyperparathyroidism patients.     

A case of iron and aluminum related osteomalacia in a long-term hemodialysis patient

A 32-year-old woman undergoing hemodialysis for 12 years was referred because of systemic bone pain and pathological fracture of ribs and right tibia. Her serum ferritin was 4800 ng/ml, liver CT level was extremely high and skeletal scintigram by 99 m-Tc-MDP revealed high activity of soft tissue. Her serum aluminum was elevated more than 20 micrograms/dl by deferoxamine infusion test. Osteomalacia and positive staining of both aluminum and iron was observed by bone biopsy examination. After treatment with deferoxamine as a chelating agent of iron and aluminum, bone pain was relieved and second bone biopsy specimen revealed improvement of osteomalacia. But serum aluminum was slightly reduced and serum ferritin level and liver CT level were unchanged.