UMLS:C0020437 - FACTA Search

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Query: UMLS:C0020437 (hypercalcemia)
10,293 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Oral calcium carbonate is an effective phosphate binder in dialysis patients. Its use minimizes aluminium intake, and by maintaining a high-normal serum ionized calcium, suppresses serum parathyroid hormone levels. However, the dose required to control hyperphosphataemia may cause hypercalcaemia. We performed prospective studies in 50 previously undialysed patients starting CAPD (28 study group, 22 control group). Calcium carbonate was the only phosphate binder used in the study group which utilized a low calcium PD fluid (calcium 1.25 mmol/l), whilst the control group used standard PD solution (calcium 1.75 mmol/l) with calcium carbonate plus aluminium hydroxide phosphate binders as clinically indicated. The study group was able to take larger doses of oral calcium carbonate with no increase in episodes of hypercalcaemia compared to the control group. There were no instances of hypocalcaemia in any patient using the low-calcium dialysis fluid. Phosphate control was better in the study group, despite the additional use of aluminium-containing phosphate binders by some patients in the control group. Serum aluminium levels in the study group were maintained at < 11.5 mumol/l, but increased significantly in the control group from 3 months onward. Mean serum parathyroid hormone in the study group declined significantly from baseline values over the first 6 months, and remained at the lower level. Bone histology showed a tendency towards improvement over the 12 months, in terms of osteoclast numbers and activity. We conclude that using dialysis fluid with a reduced calcium concentration in compliant, well-monitored patients is safe.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Low-calcium dialysis fluid and oral calcium carbonate in CAPD. A method of controlling hyperphosphataemia whilst minimizing aluminium exposure and hypercalcaemia. 133 63

Twelve patients (median age 44.5 years) on CAPD, who had previously used a dialysate calcium concentration of 1.75 mmol/l (for a median time of 11.5 months) were started on a low calcium dialysate (LCD) with a calcium concentration of 1.25 mmol/l and followed up for 24 weeks. During the first eight weeks, no changes in the doses of oral phosphate binders were made and serum ionized calcium decreased from 1.30 +/- 0.02 (mean +/- SE) mmol/l to 1.17 +/- 0.02 (p < 0.0001) and serum PTH (1-84) rose from 68 (median, range 16-397) ng/l to 147 (70-449, p = 0.005). After week 8, increasing doses of calcium carbonate were used to achieve target calcium levels of 1.20-1.30 mmol/l. No aluminum-containing binders were used. Calcium carbonate doses were increased from 2.3 (median, range 0.75-12) g/d to 6.8 (3.8-15.0, p = 0.0004) and serum phosphorus concentrations decreased from 2.00 mmol/l (median, range 1.25-2.67) at 8 weeks to 1.61 (1.18-2.39) at 24 weeks (p = 0.023). Serum intact PTH(1-84) values remained elevated despite the gradually increasing serum calcium concentrations. Hypercalcemia was recorded in 20/36 (56%) of blood samples during a period of four weeks before the start of LCD, and such episodes were observed in 15/89 (17%) of samples (p < 0.001) on LCD during the period when calcium carbonate doses were increased. It is concluded that on LCD 1) the number of episodes of hypercalcemia was markedly reduced, 2) higher calcium carbonate doses could be used, and thus 3) the control of serum phosphorus improved.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:CAPD with low calcium dialysate and calcium carbonate: results of a 24-week study. 136 22

Calcium carbonate (CaCO3) is an effective phosphate (PO4) binder in uremics, and its use reduces aluminum (AI) intake. By maintaining high serum Ca2+ levels, it decreases serum parathyroid hormone (PTH) levels. Hypercalcemia, however, often limits the dosage. To evaluate the effects of a low Ca2+ peritoneal dialysis solution (PDS; 1.25 mmol/L) on calcium metabolism, the following were studied in continuous ambulatory peritoneal dialysis (CAPD) patients with hypercalcemia (six with high PTH levels, and high turnover bone disease [Group 1], and six with low PTH levels, and low turnover bone disease [Group 2] documented by bone biopsies): 1) serum Ca2+ and PO4 levels; 2) serum PTH levels; 3) serum AI levels; and 4) bone morphology. The follow-up was 12 months. In both groups, within the third month, there was a decrease in serum Ca2+. In Group 2, serum PTH increased, reaching the norm, and in Group 1 it further increased, exceeding the norm. Because in both groups serum Ca2+ was normal, it was possible to give oral CaCO3 (10.5 +/- 2.5 g/day) to control PO4 levels while stopping AI gels. This did not induce any increase in serum Ca2+, whereas serum AI fell significantly. In Group 1, to avoid a further rise of serum PTH, the low Ca2+ PDS was supplemented with calcitriol (mean 3.5 +/- 0.5 microgram/day); this was followed by a reduction in serum PTH with no increase in serum Ca2+ or PO4.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Low calcium peritoneal dialysis solution. Effects on calcium metabolism and bone disease in CAPD patients. 145 29

Control of phosphorus accumulation in chronic renal insufficiency is crucial to the prevention of secondary hyperparathyroidism and metastatic calcification. In early renal failure, calcitriol levels are normal and parathyroid hormone levels are elevated. The phosphorus levels are maintained in the normal range by the phosphaturia induced by hyperparathyroidism. In this situation, dietary phosphorus restriction increases calcitriol levels and suppresses parathyroid hormone secretion. As renal failure progresses into late stages, hyperphosphatemia is evident along with low levels of calcitriol and worsening hyperparathyroidism. Phosphorus restriction will not affect calcitriol concentrations, yet parathyroid levels may decline. During long-term dialysis, urinary excretion of phosphorus is usually minimal. Therefore, phosphorus balance is determined primarily by the net amount absorbed by the bowel and the quantity removed during dialytic therapy. Given an adequate diet, no form of conventional dialysis is able to fully compensate for the gastrointestinal absorption of phosphorus. Hence, compounds that bind phosphorus in the bowel are often necessary. With the realization that the use of phosphorus binders containing aluminum leads to aluminum accumulation and its sequelae: osteomalacia, dementia, myopathy, and anemia, other phosphorus binders have been evaluated. Calcium carbonate has been investigated the most thoroughly and is in wide use. It is inexpensive and contains a high percent of elemental calcium. However, it is only modestly potent in the binding of phosphorus, and large doses are often necessary to attain satisfactory control of phosphorus. This may lead to hypercalcemia. One approach to this problem is to decrease the concentration of calcium in the dialysate. Alternatively, a more effective phosphorus binder may be used. Calcium acetate has been shown in acute studies to have twice the binding capacity of phosphorus per calcium absorbed than calcium carbonate. Whether use of this compound decreases the incidence of hypercalcemia is unproven. Calcium citrate increases the gastrointestinal absorption of aluminum and offers no advantage over calcium carbonate. Other compounds, such as calcium ketoacids and calcium alginate, have not been extensively studied and are not generally available. The use of phosphorus binders containing magnesium in conjunction with a dialysate low in magnesium may be efficacious. Large doses of magnesium will cause diarrhea and thus limit its use as a single agent. Reasons for failure to control hyperphosphatemia include poor compliance, improper prescription of binders, poor dissolution rates seen with some generic brands of calcium carbonate, and the presence of severe hyperparathyroidism. Optimal control of serum phosphorus in dialysis patients should always be viewed in the context of adequate nutrition and protein intake.
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PMID:Hyperphosphatemia: its consequences and treatment in patients with chronic renal disease. 156 18

The effects of calcium carbonate and aluminium hydroxide as phosphate binders were investigated in nine patients on chronic hemodialysis. Aluminium hydroxide, 1 g X 3, was given during four weeks followed by a period of four weeks without any phosphate binders and after this calcium carbonate, 2.5 g X 3, was introduced for four weeks. Calcium carbonate resulted in lowering of bioactive PTH in serum from 22.4 to 16.4 pM and a rise of serum calcitriol from 8.0 to 11.5 pg/ml with maintained control of phosphate and without significant difference in the calcium-phosphate product. Calcium in serum rose from 2.27 to 2.57 mM and mild hypercalcemia (less than 3.0 mM) in five of the patients could be controlled by dose reduction of calcium carbonate without losing control of serum phosphate levels. We conclude that calcium carbonate offers advantages as a phosphate binder compared to aluminium hydroxide in that it offers equal control of serum phosphate and elevates serum calcium which helps to control the hyperparathyroidism secondary to uremia.
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PMID:Serum concentrations of calcitriol and PTH in hemo-dialysis patients on treatment with calcium carbonate. 163 7

Calcium carbonate is frequently used in large doses as a phosphorus binder in hemodialysis patients, which often results in hypercalcemia. In most studies in which calcium carbonate is prescribed to control serum phosphorus levels the patients are not given calcitriol. However, calcitriol may be necessary for suppression of parathyroid hormone. The risk of hypercalcemia when calcium supplements are used in conjunction with calcitriol has not previously been examined in detail. We reviewed the charts of 74 hemodialysis patients (119 patient dialysis years) to determine the relationship of serum calcium to calcitriol, calcium therapy, and PTH levels. Twenty-eight patients (38%) were hypercalcemic at some point. Calcitriol therapy significantly increased the risk of hypercalcemia, independently of calcium therapy (p = 0.032). However, patients on a low dose of calcitriol were more than twice as likely to be hypercalcemic than patients on higher doses. Mean PTH levels were lower in the patients on the lower doses of calcitriol, indicating less severe hyperparathyroid disease. We conclude that hypercalcemia is a common complication in hemodialysis patients on calcitriol and calcium carbonate. Whether lowering the dialysate calcium, as suggested by other investigators, will successfully decrease the risk of hypercalcemia without worsening hyperparathyroidism remains to be determined.
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PMID:Iatrogenic hypercalcemia in hemodialysis patients. 175 77

Calcium carbonate has been successfully used as a phosphate binder in patients with chronic renal failure; however, a high frequency of hypercalcaemia has been reported. To study the effects of calcium carbonate preparations with different dissolution characteristics on the incidence of this side effect, we conducted a double-blind, crossover trial in 21 patients undergoing chronic haemodialysis. Aluminum hydroxide therapy was replaced with calcium carbonate. The subjects then randomly received either an enteric-coated or a gastric-coated preparation. Calcium carbonate (3.1-3.6 g/d) controlled serum phosphate concentrations as effectively as aluminium hydroxide (2.9 g/d). Concurrently, there was a significant rise in mean serum calcium and a fall in serum concentrations of both parathyroid hormone and osteocalcin, the latter suggesting a decrease in bone turnover. Overall, hypercalcaemic episodes developed in 9 patients (43%) and occurred at a considerable frequency (33 episodes per 100 patient-months) during treatment with the gastric-coated formulation. Following conversion to enteric-coated calcium carbonate (3.6 g/d) patients had fewer occurrences of hypercalcaemia (12 episodes per 100 patient-months, P less than 0.05) and, as compared to the gastric-coated preparation, increases in serum calcium greater than 3.00 mmol/l were not observed at all. Hyperaluminaemia was regressive during therapy with calcium carbonate, but addition of small doses of aluminium hydroxide caused a large rise in serum aluminium concentrations after infusion of desferrioxamine, indicating an enhanced rate of absorption or aberrant compartmentalization of aluminium. We conclude that calcium carbonate can control hyperphosphataemia in dialysis patients.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Calcium carbonate as a phosphate binder in dialysis patients: evaluation of an enteric-coated preparation and effect of additional aluminium hydroxide on hyperaluminaemia. 202 71

Eight children with terminal renal insufficiency on continuous ambulatory peritoneal dialysis were followed for 12 months to evaluate laboratory parameters of mineral ion and bone metabolism. Calcium carbonate (range 47-295 mg/kg body weight per day) was given in combination with low doses of either vitamin D or 1,25(OH2D3. Blood urea nitrogen and serum phosphate concentrations remained well controlled throughout the observation period. A significant increase in serum calcium levels from 2.35 +/- 0.18 to 2.61 +/- 0.22 mmol/l (mean +/- SD) was observed during the first 6 months. Alkaline phosphatase activity and mid-C-regional parathyroid hormone, both indirect parameters of bone metabolism, revealed no evidence of severe secondary hyperparathyroidism. Our data indicate that calcium carbonate may be sufficient to induce relative hypercalcaemia in uraemic children, and thus reduce the risk of developing renal osteodystrophy. Unwanted side-effects of vitamin D preparations, i.e. increased intestinal phosphate absorption and hypercalcaemia after successful renal transplantation, may thus be avoided.
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PMID:Efficacy of calcium carbonate and low-dose vitamin D/1,25(OH)2D3 in reducing the risk of developing renal osteodystrophy in children on continuous ambulatory peritoneal dialysis. 208 63

This study evaluates the use of calcium carbonate in chronic renal failure. Forty-eight patients (25 male, 23 female, mean age 54.3 years, six pre-dialysis. 12 CAPD, 30 haemodialysis) on phosphate restriction and requiring aluminum hydroxide (mean 2.4 +/- 0.8 g/day) to control serum phosphate, were converted to an equivalent dose of calcium carbonate (2.5 +/- 0.6 g/day). None received vitamin D analogues. Three months post-conversion there was a significant decrease in mean (+/- SEM) serum phosphate (1.86 +/- 0.08 versus 1.66 +/- 0.05 mmol/l P less than 0.01) and serum aluminum (28.3 +/- 5.4 versus 13.2 +/- 3.0 micrograms/l, P less than 0.0001): calcium/phosphate product was unchanged. Post-conversion there was an increase in serum bicarbonate, (20.6 +/- 0.5 versus 22.1 +/- 0.6 mmol/l, P less than 0.01) and serum calcium (2.32 +/- 0.02 versus 2.45 +/- 0.03 mmol/l, P less than 0.0001). No change in serum creatinine, alkaline phosphatase or parathormone occurred. No adverse effects were reported but nine (18%) patients became hypercalcaemic (2.7 to 2.93 mmol/l), eight of whom responded to dose reduction. Hypercalcaemia did not correlate with pre-conversion serum calcium, parathyroid hormone, alkaline phosphatase or aluminium. Calcium carbonate is an effective alternative to aluminium-based phosphate binders. It produces a beneficial increase in serum calcium and bicarbonate and a significant decrease in serum aluminium. Hypercalcaemia is unpredictable but is easily reversible in the majority of patients.
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PMID:The use of calcium carbonate to treat the hyperphosphataemia of chronic renal failure. 251 82

With increasing recognition of problems regarding the use of aluminum hydroxide as a phosphate binder, calcium carbonate has become the medication of choice. Use of calcium has, however, frequently been associated with development of hypercalcemia. At this institution, calcium carbonate powder as a phosphate binder, examination of its efficacy, and the frequency of hypercalcemia with its use were of great interest. Calcium carbonate powder (CalCarb-HD, 2.4 gms elemental calcium/packet) (CalCarb-HD, Lafayette Pharmacal Inc., Fort Worth, TX) was used in the study. Twenty-one end-stage renal disease (ESRD) patients (17 hemodialysis and 4 chronic ambulatory peritoneal dialysis) were chosen and converted from their previous binder (primarily, calcium carbonate tablets) to calcium powder. The dosage was adjusted to keep phosphorus levels at 3.5 to 5.5 mg/dl and calcium less than 11.5 mg/dl. At 2 months, the average calcium level in the 16 patients remaining in the study was 9.2 mg/dl, and the average phosphorus level was 5.2 mg/dl with an average calcium dose of 1.4 packets/day. By 7 months, the 8 patients remaining in the study had an average calcium level of 9.9 mg/dl with an average phosphorus level of 5.5 mg/dl; average calcium dose was 1.8 packets/day. Total episodes of hypercalcemia (calcium greater than 11.5 mg/dl) were two. Calcium carbonate powder appears to be an effective phosphate binder in the ESRD population. The relatively few episodes of hypercalcemia may be related to possible enhanced bioavailability of the compound secondary to its powdered form.
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PMID:Calcium carbonate powder as a phosphate binder. 259 73

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