Active absorbable calcium as a phosphate binder in dialysis patients

Summary Recently we reported a better effect of oyster shell electrolysate (active absorbable calcium, AACa) than CaCO₃ in normalizing hypocalcemia in patients with hypoparathyroidism and secondary hyperparathroidism due to renal failure. We now report the phosphate binding effect of AACa in 20 dialysis patients, AACa treatment resulted in a significantly lower blood phosphate levels as compared with those of CaCO₃ treatment when each agent was administered so that elementary calcium content remains the same. It was concluded that AACa may be an alternative as a phosphate binder in patients under chronic hemodialysis.     

Calcium-containing phosphate binder use associated with accelerated atherosclerotic coronary calcification.

OBJECTIVE: To report parameters and outcomes of phosphorus management in a maintenance hemodialysis patient who experienced atherosclerotic coronary calcification leading to myocardial infarction; to evaluate the role that high calcium intake over 6 years may have played in his coronary artery disease before the dangers of excess calcium intake in phosphorus management were recognized; and to describe an optimized therapeutic approach that provided improved mineral control. DESIGN: Case study. SETTING: A large outpatient in-center hemodialysis treatment unit. Main Outcome Measures: Serum calcium, serum phosphorus, Ca x P product. RESULTS: The year before his cardiac event, the patient's mean serum calcium was 9.6 mg/dL, mean serum phosphorus was 5.9 mg/dL, and mean Ca x P product was 57 mg2/dL2. Serum calcium peaked at 10.8 mg/dL shortly before his cardiac event. Treatment phases included high-dose calcium acetate (10 g Ca/day), low-dose calcium acetate (4 g Ca/day), low-dose calcium acetate plus low-dose sevelamer hydrochloride (4 g Ca/day plus 2.4 to 4.8 g sevelamer/day), and low-dose calcium acetate plus higher-dose sevelamer hydrochloride (4 g Ca/day plus 4.0 to 12.0 g sevelamer/day). With calcium acetate and sevelamer doses optimized, serum phosphorus levels and Ca x P products continued decreasing, with mean values of 5.99 mg/dL and 50.7 mg2/dL2, respectively, and serum calcium remained stable at a mean of 8.5 mg/dL. The patient has had no further myocardial infarctions. CONCLUSIONS: This case illustrates how our growing understanding of phosphorus management and the addition of a calcium-free binder to our therapeutic armamentarium have improved phosphorus and calcium balance, reducing the risk of cardiovascular calcification.     

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.     

Mortality effect of coronary calcification and phosphate binder choice in incident hemodialysis patients

The risk of death in hemodialysis patients treated with calcium-containing phosphate binders or sevelamer is not known. We assessed all-cause mortality in 127 patients new to hemodialysis assigned to calcium-containing binders or sevelamer after a median follow-up of 44 months from randomization. This was a predetermined secondary end point of a randomized clinical trial designed to assess progression of coronary artery calcium (CAC) scores in the two treatment arms. Thirty-four deaths occurred during the follow-up period: 23 in subjects randomized to calcium-containing phosphate binders and 11 in subjects randomized to sevelamer. Baseline CAC score was a significant predictor of mortality after adjustment for age, race, gender, and diabetes with increased mortality proportional to baseline score (P=0.002). Mortality was borderline significantly lower in subjects randomized to sevelamer (5.3/100 patient years, confidence interval (CI) (2.2-8.5) compared to those randomized to calcium-containing binders (10.6/100 patient years, CI 6.3-14.9) (P=0.05). The greater risk of death for patients treated with calcium-containing phosphate binders persisted after full multivariable adjustment (P=0.016, hazard ratio 3.1, CI 1.23-7.61). In subjects new to hemodialysis baseline CAC score was a significant predictor of all-cause mortality. Treatment with sevelamer was associated with a significant survival benefit as compared to the use of calcium-containing phosphate binders.     

Two year comparison of sevelamer and calcium carbonate effects on cardiovascular calcification and bone density.

BACKGROUND: Calcium-based phosphate binders may induce tissue calcification, and little is known about their effects on bone density. We compared the effects of a calcium with a non-calcium phosphate binder on both arterial calcification and bone density measured by computed tomography. METHODS: Seventy-two adult haemodialysis patients were randomized to treatment with calcium carbonate (CC) or sevelamer (SEV) for 2 years. Electron beam CT scans were performed at baseline and at 6, 12 and 24 months. Serum phosphorus, calcium, calcium x phosphorus product and intact parathyroid hormone (iPTH) were measured and other routine laboratory tests were also carried out. RESULTS: The average calcium x phosphorus product was similar in the two treatment groups. However, patients receiving CC had significantly lower average iPTH (P<0.01), were more likely to have hypercalcaemic episodes (P = 0.03) and had significantly greater increases in coronary artery (CC median 484, P<0.0001, SEV median 37, P = 0.3118, between-group P = 0.0178) and aortic (CC median 610, P = 0.0003, SEV median 0, P = 0.5966, between-group P = 0.0039) calcification scores. The CC group also had a significant decrease in trabecular bone density (CC median -6%, P = 0.0049, SEV median +3%, P = 0.0296, between-group P = 0.0025). However, there was no significant difference in cortical bone density between the two groups. CONCLUSIONS: This 2 year study shows that calcium carbonate use is continuously associated with progressive arterial calcification in haemodialysis patients. In addition, it suggests that it is also associated with decreased trabecular bone density. However, this latter finding requires confirmation by a study specifically devoted to this issue.     

Long-term use of magnesium hydroxide as a phosphate binder in patients on hemodialysis

The long-term use of magnesium hydroxide [Mg(OH)2] as a phosphate binder was investigated in 18 patients on chronic hemodialysis. All patients received a basal treatment with oral calcium carbonate. Vitamin D supplements were not used. In period I each patient ingested aluminum hydroxide [Al(OH)3], in period II Mg(OH)2 and in period III Mg(OH)2 and Al(OH)3 together. During period II and III a dialysate devoid of Mg was used. Mg(OH)2 doses were adjusted to prevent severe hypermagnesemia and diarrhea. The mean dose of Mg(OH)2 in period II was 2.4 +/- 0.6 and in period III 2.6 +/- 1.2 g/day. Serum phosphate increased significantly in period II and fell again in period III. Despite a halving of the Al(OH)3 dose in period III, serum Al was similar in period I and period III (55.8 +/- 19.1 vs 57.1 +/- 27.3 microg/l). Parathyroid hormone (PTH) concentration fell in period II and decreased even further in period III. We conclude that oral Mg(OH)2 may reduce the required Al(OH)3 dose, however, without an effect on serum Al concentration. The observed suppression of parathyroid activity needs further study.     

长期使用低钙透析液对腹膜透析患者钙磷代谢的影响

目的 观察规律性腹透患者使用低钙腹透液的有效性和安全性。方法 在规律性 随访的患者中选择高血钙和(或)高血磷,iPTH<150 pg／ml的患者25例,改用Baxter PD4透析液 (钙1．25 mmol／L,其余成分不变),同时增加碳酸钙用量。使用低钙透析液期间每1～2个月检测 血总钙、血磷、iPTH和血白蛋白,同时观察患者使用低钙透析液有何不适。结果 在使用标准钙 透析液的1年中,血钙浓度逐渐升高,血iPTH逐渐下降,并差异有统计学意义。换用低钙透析液 治疗后,第1个月的血钙值明显下降(P<0．05),且维持在正常范围。腹透治疗开始时每日碳酸 钙(2．83±0．53)g,低钙透析液治疗后每日碳酸钙为(3．57±0．74)g(P<0．05)。治疗后2个月和3 个月,血磷浓度较治疗前略有下降,差异有统计学意义。iPTH值同样在第1个月时显著升高(P <0．05),以后未观察到再进行性升高,并维持在200 pg／ml左右。血清白蛋白在治疗前后差异无 统计学意义。在整个治疗过程中,1例患者治疗2周后出现低钙,iPTH升高明显而停用低钙透析 液。其余患者能很好地耐受低钙透析,没有低血压、抽搐等情况发生。结论 在高钙、高磷、低转 运骨病的腹膜透析患者中使用钙浓度为1．25 mmol／L的透析液透析同时注意钙的补充,有助于 钙磷代谢和骨病的改善。     

Effects of oyster shell electrolysate (active absorbable calcium) as a phosphate binder

Effect of oral calcium load on calcium metabolism was studied in 6 healthy subjects. Calcium carbonate (3.75 g) and Oyster Shell Electrolysate (OSE, 3.0 g) were orally administrated in a cross-over design to provide 1.5 g elementary calcim to each subject twice at 1 week interval. No significant differences were found in the increments of serum calcium, blood ionized calcium and urinary calcium excretion and in the decrements of serum PTH and urinary phosphorus excretion. The decrease in serum phosphorus level after OSE administration, however, was significantly greater than that after calcium carbonate administration. OSE thus appears to have a more potent phosphate binding capacity than calcium carbonate despite indistinguishable immediate effects on the increments of serum calcium and suppression of serum PTH. OSE may therefore represent a new candidate for a potent phosphate binder with a prospect for replacing calcium carbonate currently on use in chronic renal failure.     

Lanthanum: a safe phosphate binder

Accumulation of inorganic phosphate due to renal functional impairment contributes to the increased cardiovascular mortality observed in dialysis patients. Phosphate plays a causative role in the development of vascular calcification in renal failure; treatment with calcium-based phosphate binders and vitamin D can further increase the Ca x PO(4) product and add to the risk of ectopic mineralization. The new generation of calcium-free phosphate binders, sevelamer and lanthanum, can control hyperphosphatemia without adding to the patients calcium load. In this article, the metabolism of lanthanum carbonate and its effects in bone, liver and brain are discussed. Although lanthanum is a metal cation its effects are not comparable to those of aluminum. Indeed, in clinical studies no toxic effects of lanthanum have been reported after up to four years of follow-up. The bioavailability of lanthanum is extremely low. The effects observed in bone are due to phosphate depletion, with no signs of direct bone toxicity yet observed in rats or humans. The liver is the main route of excretion for lanthanum carbonate, which can be localized in the lysosomes of hepatocytes. No lanthanum could be detected in brain tissue.     

Lanthanum carbonate: a new phosphate binder

PURPOSE OF REVIEW: Hyperphosphatemia remains an important aspect in the management of end-stage renal disease patients. Consequently, there is a need for new, efficient and well-tolerated phosphate binders. In this review, a new phosphate-binding drug, lanthanum carbonate, with an attractive preclinical efficacy profile compared with existing binders, is discussed. Although the available human efficacy and safety data over 3 years are encouraging, the consequences of low-level tissue deposition continue to be evaluated in longer-term clinical studies. RECENT FINDINGS: Lanthanum carbonate has been shown in clinical studies of up to 3 years to be an effective, well-tolerated phosphate binder. Reported adverse effects are mainly gastrointestinal, and do not differ from those of calcium carbonate. The gastrointestinal absorption of lanthanum is very low. Whereas the element is mainly excreted by the liver, renal excretion of the absorbed fraction is less than 2%. Bone lanthanum levels seen after long-term treatment (up to 4 years) seem not to affect the physicochemical process of mineralization, or osteoblast number/function. Preliminary data on the localization of lanthanum in bone have shown the element to be present at both active and quiescent sites of bone mineralization, independent of the type of renal osteodystrophy, a profile distinct from aluminum, as well as diffusely distributed throughout the mineralized bone matrix especially in rats/humans with an increased bone turnover. A randomized, comparator-controlled, parallel group, open-label study comparing lanthanum carbonate with calcium carbonate in dialysis patients showed no evolution towards low bone turnover in the lanthanum group, and no aluminum-like effect on bone. SUMMARY: Lanthanum carbonate seems to be a potent phosphate-binding drug, minimally absorbed from the gut, with an encouraging safety profile, and no deleterious effects on bone.     

Long-term comparison of sevelamer hydrochloride to calcium-containing phosphate binders

AIM: In patients with end-stage renal disease (ESRD), hyperphosphataemia and an elevated calcium-phosphorus (Ca-P) product contribute to morbidity and mortality. Suggested target goals for serum phosphorus concentration and calcium-phosphorus product have recently been lowered. As a result, long-term comparative studies of the efficacy of phosphate binders are critical. This study compares the long-term efficacy of sevelamer hydrochloride to calcium-containing binders (CCB). METHODS: A retrospective chart review was conducted in 30 patients receiving sevelamer hydrochloride for >1 years and 25 patients receiving CCB. RESULTS: Patients on sevelamer hydrochloride had lower serum bicarbonate concentration than those on CCB, 18.6 +/- 2.7 versus 20.3 +/- 1.8 mmol/L (P = 0.0017). Serum phosphorus concentration was higher in patients on sevelamer hydrochloride compared to CCB 2.10 +/- 0.87 versus 1.74 +/- 0.28 mmol/L (P = 0.0013), as was the Ca-P product 4.97 +/- 0.94 mmol2L2 (62.1 +/- 11.8 mg2/dL2) versus 3.97 +/- 1.18 mmol2/L2 (49.7 +/- 14.7 mg2/dL2), P = 0.0009). Only 36% of patients on sevelamer hydrochloride compared with 68% on CCB (P = 0.015) met the serum phosphorus goal of < or =1.78 mmol/L. CONCLUSION: Patients on sevelamer hydrochloride for >1 years compared to those on CCB had a lower serum bicarbonate concentration, a higher serum phosphorus concentration and a higher Ca-P product. Clinicians should balance the increase in calcium load with CCB versus the cost and effectiveness of sevelamer hydrochloride in choosing a phosphate binder for ESRD patients.     

Calcium acetate versus calcium carbonate as oral phosphate binder in pediatric and adolescent hemodialysis patients

Calcium carbonate is widely used as an oral phosphorus binder to control hyperphosphatemia in children on maintenance hemodialysis. Intestinal calcium absorption may induce hypercalcemia, particularly if calcitriol is given simultaneously. In adults, calcium acetate binds phosphorus more effectively than calcium carbonate, while reducing the frequency of hypercalcemic events. We therefore compared calcium acetate with calcium carbonate in nine pediatric patients on long-term maintenance hemodialysis. Following a 1-week withdrawal of phosphorus binders, calcium carbonate was administered for 7 weeks; after a second withdrawal, calcium acetate was given for another 7 weeks. All patients received calcitriol regularly. Both agents lowered the serum phosphorus concentration significantly (calcium carbonate 5.7±1.4 vs. 7.7±2.1 mg/dl, P<0.005; calcium acetate 5.8±1.4 vs. 7.8±2.0 mg/dl, P<0.005). Significantly less elementary calcium was ingested with calcium acetate than with calcium carbonate: 750 (375 – 1,500) vs. 1,200 (0 – 3,000) mg calcium/day, P<0.0001. With calcium carbonate serum calcium increased significantly. The number of episodes of hyperphosphatemia or hypercalcemia did not differ between treatments. Intact plasma parathyroid hormone (PTH) decreased significantly with both phosphate binders, and serum 25-hydroxyvitamin D₃ increased. There was a close relationship between serum phosphorus and PTH in prepubertal but not in pubertal patients. We conclude that hyperphosphatemia can be controlled effectively by both calcium acetate and calcium carbonate in pediatric hemodialysis patients. The oral load of elementary calcium is reduced significantly by binding phosphorus with calcium acetate instead of calcium carbonate; nevertheless, hypercalcemic episodes remain equally frequent with both phosphate binders. Received May 9, 1995; received in revised form and accepted February 23, 1996     

Klotho as a regulator of fibroblast growth factor signaling and phosphate/calcium metabolism

PURPOSE OF REVIEW: This review summarizes the most recent findings on Klotho in the regulation of fibroblast growth factor-23 (FGF23) signaling and phosphate/calcium homeostasis. RECENT FINDINGS: The klotho gene encodes a single-pass transmembrane protein and functions as an aging-suppressor gene, which extends life span when overexpressed and accelerates the development of aging-like phenotypes when disrupted in mice. FGF23 is a hormone that suppresses phosphate reabsorption in renal proximal tubules. Recent studies have shown that Klotho mice and Fgf23 mice exhibit identical phenotypes including hyperphosphatemia and hypercalcemia in addition to the aging-like syndrome. This may be explained by the fact that Klotho binds to multiple FGF receptors and increases their affinity to FGF23. Another Klotho protein function is to activate transient receptor potential vanilloid-5 - a calcium channel involved in calcium reabsorption in the kidney. Klotho protein can modify sugar chains on transient receptor potential vanilloid-5 through its activity as a beta-glucuronidase, preventing the calcium channel from internalization and inactivation. SUMMARY: Klotho protein binds to fibroblast growth factor receptors and functions as a regulator of FGF23 signaling. It also functions as an enzyme that modifies sugar chains of transient receptor potential vanilloid-5 and regulates its activity. Klotho is a multi-functional protein that regulates phosphate/calcium metabolism as well as aging.     

Effects on calcium and phosphate metabolism and on parathyroid function of acute administration of tricalcium phosphate

The effects of the ingestion of tricalcium phosphate on calcium and phosphate metabolism and on parathyroid function were evaluated in 10 young adults. Each subject was studied during a control period of two hours before and during an experimental period of four hours after ingestion of a single oral dose of tricalcium phosphate containing 1500 mg of calcium and 770 mg of phosphorus. Serum and urinary calcium and phosphate and the nephrogenous cAMP fraction were measured. Significant rises in serum (from 2.32 ± 0.05 to 2.44 ± 0.08 mmol/l) and urinary (from 1.08 ± 0.65 to 3.43 ± 1.38 μmol/l GF) calcium and in serum phosphate (from 1.05 ± 0.18 to 1.28 ± 0.14 mmol/l) occurred. Unexpectedly, the acute supply of calcium in the form of tricalcium phosphate did not provoke significant alteration of nephrogenous cAMP level. In order to assess the respective effects of calcium and of phosphate, similar tests with ingestion of similar amounts either of calcium (as a glucoheptogluconate salt) or of phosphate were subsequently performed in the same subjects. Significant increases in serum total calcium were observed after calcium glucoheptogluconate as after tricalcium phosphate. However, the effects on parathyroid function differed, since a significant (p < 0.001) decrease in nephrogenous cAMP followed the ingestion of calcium glucoheptogluconate. Otherwise, a stimulating effect of phosphate on parathyroid function was observed. These findings suggest that the respective effects of calcium and of phosphate are counterbalanced when administered as tricalcium phosphate, resulting in the absence of parathyroid suppression.     

Evaluation of a new calcium containing cardioplegic solution in the isolated rabbit heart in comparison to a calcium-free,low sodium solution

Isolated perfused rabbit hearts were studied to compare the effects of 3 hour ischemic arrest following either calcium-free or calcium-containing cardioplegia, on the recovery of isovolumic function of the left ventricle, coronary flow, release of creatine phosphokinase and myocardial water content. The hearts perfused with the calcium-containing solution (Ca 0.5 mmol/L) showed better recovery of the developed pressure in the left ventricle, and its first derivative and compliance. Coronary flow at a constant perfusion pressure was better restored during reperfusion in the hearts with calcium-containing solution. The release of less CPK and a lower water content were also observed in the hearts reperfused with calcium-containing solution. We concluded that calcium-containing cardioplegic solution with a high concentration of magnesium (10 mmol/L) was superior to calcium-free solution for myocardial protection.     

Evaluation of a new calcium containing cardioplegic solution in the isolated rabbit heart in comparison to a calcium-free, low sodium solution

Isolated perfused rabbit hearts were studied to compare the effects of 3 hour ischemic arrest following either calcium-free or calcium-containing cardioplegia, on the recovery of isovolumic function of the left ventricle, coronary flow, release of creatine phosphokinase and myocardial water content. The hearts perfused with the calcium-containing solution (Ca 0.5 mmol/L) showed better recovery of the developed pressure in the left ventricle, and its first derivative and compliance. Coronary flow at a constant perfusion pressure was better restored during reperfusion in the hearts with calcium-containing solution. The release of less CPK and a lower water content were also observed in the hearts reperfused with calcium-containing solution. We concluded that calcium-containing cardioplegic solution with a high concentration of magnesium (10 mmol/L) was superior to calcium-free solution for myocardial protection.