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)

Calcitriol is effective in suppressing PTH levels in haemodialysis patients with hyperparathyroidism but has a low therapeutic index. There is a search for other vitamin D sterols that suppress PTH but cause less hypercalcaemia. We review evidence that 1 alpha-hydroxy-vitamin D2 (1 alpha-D2) may be an effective and safer alternative to calcitriol. In vitamin D-deficient rats, 1 alpha-D2 is equipotent to 1 alpha-D3, which is converted to calcitriol before it acts; but, in normal rats, 1 alpha-D2 is much less toxic at high doses. In osteopenia models, either steroid-induced or following ovariectomy, 1 alpha-D2 is equal to or more effective than 1 alpha-D3 in preventing bone loss but causes less hypercalciuria. Studies in osteoporotic women reveal minimal hypercalciuria with 1 alpha-D2 at doses up to 4 micrograms/day, data suggesting greater safety than reported with calcitriol or 1 alpha-D3. Preliminary data in haemodialysis patients with secondary hyperparathyroidism demonstrate the efficacy of 1 alpha-D2 in suppressing PTH levels with minimal untoward effects on serum Ca and no effects on serum P. Taken together, these observations suggest that 1 alpha-D2 deserves strong consideration as a therapeutic agent for secondary hyperparathyroidism associated with end-stage renal disease.
Nephrol Dial Transplant 1996
PMID:1 alpha-Hydroxy-vitamin D2: a new look at an 'old' compound. 884 Mar 32

Recently, several reports have suggested that there is a higher incidence of low turnover bone in the absence of aluminium exposure in peritoneal dialysis patients than in hemodialysis patients. Relative hypoparathyroidism with mild hypercalcemia, induced by a positive calcium balance, is considered to be one of the major causes of this disorder. Thus, we recruited 9 continuous ambulatory peritoneal dialysis (CAPD) patients with relative hypoparathyroidism and low bone turnover [intact parathyroid hormone (iPTH) < 50 pg/mL, intact osteocalcin < 10.0 ng/mL] who had been prescribed 1.75 mmol/L calcium (Ca) dialysate for 5.0 +/- 0.3 years. They were then treated by low Ca (1.25 mmol/L) dialysate for nine months without vitamin D and aluminum administration. Intact PTH and bone metabolic markers [intact osteocalcin, alkaline phosphatase (ALP)] were measured every three months. Intact PTH levels increased from 21.1 +/- 3.8 to 159.2 +/- 32.8 pg/mL after the first three months; thereafter, those levels were maintained at around 150 pg/mL. On the other hand, intact osteocalcin levels rose consecutively from 6.7 +/- 1.2 to reach 22.0 +/- 3.8 ng/mL after nine months. Interestingly, the pattern of time course changes between PTH and intact osteocalcin was different. ALP activity did not change during the nine-month period. Corrected serum calcium was significantly decreased (p < 0.001) to approximately 0.25 mmol/L within one month, and the level remained almost the same thereafter. The serum phosphate level did not change without adjusting the original dose of calcium carbonate as a phosphate binder. We concluded that low Ca dialysate (1.25 mmol/L) is effective for the treatment of CAPD-related hypoparathyroidism with low bone turnover.
Adv Perit Dial 1996
PMID:Low calcium (1.25 mmol/L) dialysate can normalize relative hypoparathyroidism in CAPD patients with low bone turnover. 886 14

The aim of this study was to evaluate the role of pulse oral calcitriol in the control of secondary hyperparathyroidism in peritoneal dialysis (PD) patients, addressing the effects after withdrawal. We studied 15 patients with intact parathyroid hormone (iPTH) plasma levels above 250 pg/mL. The initial calcitriol dose was 8 or 4 micrograms/week, administered in two doses, according to whether the iPTH plasma levels were above or below 400 pg/mL. This dose was modified during the follow-up according to the response. Serum iPTH levels decreased in all patients after the first month (559 +/- 243 to 212 +/- 94 pg/mL, p < 0.001). Serum calcium levels significantly increased during therapy, while serum phosphorus levels did not change. The mean duration of the treatment was 95 +/- 57 days. Nine patients reached the target iPTH levels without complications, and in 6 patients the treatment was interrupted because of hypercalcemia. One month after finishing pulse therapy, a significant decrease in serum calcium levels and an increase in iPTH levels were observed. These values were similar to baseline data and were significantly higher than those found during the pulse calcitriol period. Pulse oral calcitriol administration seems to be a short-term, efficient therapy for secondary hyper-parathyroidism in PD patients. However, after the end of pulse therapy, iPTH serum levels return to baseline values, suggesting long-term therapeutic failure.
Adv Perit Dial 1997
PMID:Frequent recurrence of secondary hyperparathyroidism after pulse oral calcitriol withdrawal in PD patients. 936 Jun 90

A quality assessment (QA) activity revealed that the percentage of parathyroid hormone (PTH) levels above 300 micrograms/dL was higher in the peritoneal dialysis (PD) unit than in the hemodialysis (HD) unit (44% vs 27%). To reduce the proportion of patients with a target PTH above 200 micrograms/dL, a protocol that emphasized control of the serum phosphate level, standard pulsed doses of calcitriol, and increased patient education was created for the management of renal osteodystrophy. Serum calcium, phosphate, and PTH levels were obtained according to the protocol from July 1994 through June 1996. The percentage of patients achieving a PTH level below 200 micrograms/dL increased from 40% in June 1994 to 57% in June 1996. Significant differences were found in PTH levels at baseline and at test times 1, 2, and 3. Hypercalcemia (Ca > 12) occurred in 4% of the 532 Ca levels drawn during the study period and were due to breaches of protocol. In conclusion, we have confirmed previous work indicating that pulsed calcitriol can control elevated PTH levels in PD patients. Furthermore, we have developed a protocol that can be used as a QA tool to reduce the prevalence of hyperparathyroidism in the outpatient PD setting without inducing excess hypercalcemia.
Adv Perit Dial 1997
PMID:Oral pulsed calcitriol protocol reduces the prevalence of hyperparathyroidism in a PD unit. 936 Jun 91

Calcitriol and alfacalcidol are useful in suppressing parathyroid hormone (PTH) in haemodialysis patients, but hypercalcaemia and hyperphosphataemia are frequent. The vitamin D analogue, 1alpha-hydroxyvitamin D2 (1alphaD2), has a higher therapeutic index in animal models. Previously, 1alphaD2, 4 microg/day or 4 microg/haemodialysis, lowered iPTH to the target range in 87.5% of 24 haemodialysis patients with moderate to severe secondary hyperparathyroidism (plasma iPTH, 359-1521 pg/ml). The incidences of hypercalcaemia (serum Ca>2.8 mM) or hyperphosphataemia (serum P>2.23 mM) were low. Later, 10 of these patients were re-treated with 1alphaD2, initial dose, 10 microg, thrice weekly with haemodialysis. The iPTH was suppressed as readily, and there was no greater incidence of hypercalcaemia and hyperphosphataemia. Based on these data, a large, multicentre study is ongoing in California and Tennessee/Mississippi, using 1alphaD2 in haemodialysis patients with iPTH >400 pg/ml. In this and the earlier studies, only calcium-based phosphate binders were used to control serum phosphorus. The initial dose, 10 microg thrice weekly with haemodialysis, is adjusted to maintain a target iPTH within the range of 150-300 microg/ml; the final dose range is 2.5-20 microg per haemodialysis. The protocol includes 8 weeks of wash-out with no vitamin D, 16 weeks of open label treatment period with 1alphaD2, and finally 8 weeks of randomized double blinded treatment with either continued 1alphaD2 or placebo. Forty two patients from California and 38 from Tennessee/Mississippi have completed 16 weeks of open label treatment. In California, iPTH declined from 832+/-95 pg/ml at baseline to 222+/-71 pg/ml at the nadir and to 477+/-117 pg/ml at week 16 of the treatment. In Tennessee/Mississippi, the iPTH declined from 977+/-65 pg/ml to 286+/-42 pg/ml at the lowest point and to 493+/-79 at the end of the treatment. Plasma iPTH reached or fell below the target range in 84% of the 80 patients completing open treatment. Asymptomatic hypercalcaemia (serum Ca>2.8 mM) increased from 0.3 episodes/100 weeks during wash-out to 3.6 episodes/100 treated weeks in California and from 0 to 3.7 episodes in Tennessee/Mississippi. In California and Tennessee, the episodes of hyperphosphataemia (serum P>2.2 mM) increased from 5.0 and 5.0 episodes per 100 patient/week during wash-out to 10.1 and 10.9 episodes/100 treatment weeks, respectively, with 1alphaD2 treatment. There were no adverse events in association with 1alphaD2 treatment. Thus, oral 1alphaD2 is safe and highly effective for the treatment of secondary hyperparathyroidism.
Nephrol Dial Transplant 1998
PMID:Intermittent oral 1alpha-hydroxyvitamin D2 is effective and safe for the suppression of secondary hyperparathyroidism in haemodialysis patients. 1alphaD2 Study Group. 956 25

Since dietary restrictions and phosphorus removal by haemodialysis (HD) are not sufficient to control serum phosphate (s-phosphate) levels in dialysis patients the use of oral phosphate binders is mandatory. Calcium ketoglutarate (CaKE) is an analogue of glutamic acid exerting phosphate binding properties. Therefore we compared this substance to calcium acetate (CaAC) in a 24-weeks open cross-over trial in 28 maintenance HD patients. Medications and HD prescriptions were kept unchanged during the trial. Following 2 weeks of withdrawal of phosphate binders, patients were randomly assigned to one of the calcium salts for 12 weeks; after a second withdrawal of 2 weeks, all patients were shifted to the other treatment for another 12 weeks. All patients received equimolar doses of CaKE and CaAC with respect to the amount of prescribed elemental calcium. Treatment with CaAC and CaKE significantly reduced s-phosphate levels after 4 weeks (CaAC 1.95+/-0.6 vs. 2.4+/-0.53 mmol/l, P = 0.004; CaKE 1.95+/-0.4 vs. 2.47+/-0.63 mmol/l, P = 0.0001) reaching a virtually stable plateau over the remaining observation time without significant differences between the groups. The incidence of hypercalcaemia defined as a serum calcium level > or =2.8 mmol/l was significantly higher in CaAC than in CaKE treated patients (n = 8 vs. n = 1, P = 0.03). There were no significant differences in serum intact parathyroid hormone (PTH) bicarbonate, albumin or calcitriol levels between the groups after 12 weeks treatment. We conclude that CaKE is as effective as CaAC for treatment of hyperphosphataemia in chronic HD patients and may be particularly helpful in patients who are prone to develop hypercalcaemia.
Nephrol Dial Transplant 1999 Jun
PMID:Calcium ketoglutarate versus calcium acetate for treatment of hyperphosphataemia in patients on maintenance haemodialysis: a cross-over study. 1038 11

The uremic milieu generates chronic stimulatory input to the parathyroid glands, which is mediated principally by low calcium, high phosphate and low calcitriol, and results in increased parathyroid hormone (PTH) synthesis and release and an increase in parathyroid mitotic activity with the development of monoclonal areas of nodular hyperplasia. Such glands do not fully express the machinery required to mediate the suppressive inputs to the parathyroids; the extracellular calcium receptor (CaR) and the vitamin D receptor (VDR) are both downregulated. In most of these patients ablation, by parathyroidectomy or ethanol injection, provides the only means of correcting the hyperparathyroidism; apoptosis in parathyroid cells is negligible and clinically irrelevant. In practice, surgery is often delayed by a doomed and ultimately futile attempt to effect control by medical means. Better predictors of the likely success or failure of optimal non surgical management are needed. Gland size exceeding 1 cm3 and elevated PTH despite hypercalcemia (implying loss of suppressibility by calcium), in the presence of good phosphate control and adequate calcitriol provision point strongly to eventual failure of medical treatment and the need for parathyroid ablation. Parathyroidectomy, usually subtotal, remains the standard management, with ultrasound guided injection of ethanol or calcitriol showing promise in some centers. The above scenario is unlikely to be changed greatly by the new emerging vitamin D metabolites, but calcimimetic agents may well increase the scope of non surgical management.
Semin Dial
PMID:Are parathyroidectomies still appropriate in chronic dialysis patients? 1101 87

Chronic renal failure is characterized by diminished synthesis of, and resistance to, the active vitamin D metabolite 1,25-dihydroxy-vitamin D3 (1,25(OH)2D3, calcitriol). Calcitriol results from the biotransformation of the precursor 25-hydroxy-vitamin D3 (25(OH)D3) to 1,25(OH)2D3. 25(OH)D3 is synthesized in the liver, and 1alpha-hydroxylase, the rate-limiting enzyme for its biotransformation into the most active metabolite, 1,25(OH)2D3, is located in the kidney. The regulation of 1alpha-hydroxylase in renal failure is not well known. Recent work indicates that, in contrast to previous opinion, 1alpha-hydroxylase is predominantly expressed not in the proximal tubule but in the distal tubule [1]. In vivo, the main stimulatory signal is presumably parathyroid hormone (PTH) and the main inhibitory signal hyperphosphataemia. Both signals are altered in renal failure. There is also evidence that the renal 1alpha-hydroxylase becomes substrate-dependent in patients with renal failure. This means that a higher concentration of the precursor 25(OH)2D3 will result in a higher rate of transformation into the active metabolite 1,25(OH)2D3 in renal patients. Calcitriol is not exclusively synthesized in the kidney, but may also be synthesized in extra-renal tissues, e.g. activated monocytes/macrophages [2], particularly in granuloma [3] as shown by anephric uraemic patients who develop hypercalcaemia and elevated calcitriol concentrations when sarcoidosis [4] or tuberculosis [5] supervenes. On the other hand, calcitriol is less effective in uraemia. This may be to some extent due to diminished expression of vitamin D receptors [6], particularly in parathyroid glands when they undergo nodular transformation [7], but there may also be resistance to calcitriol at the post-receptor level [8]. In a series of elegant experiments [9,10], calcitriol resistance has been related to disturbed genomic effects of active vitamin D because the interaction of the vitamin D receptor ligand complex with vitamin D-responsive elements (VDREs) upstream of vitamin D-regulated genes was disturbed by the action of low molecular weight substances in uraemia, which have not been completely characterized. The role of genetically determined polymorphisms of the vitamin D receptor in the genesis of disturbed calcium metabolism of renal failure is currently unclear.
Nephrol Dial Transplant 2000
PMID:Management of disturbed calcium metabolism in uraemic patients: 1. Use of vitamin D metabolites. 1107 70

Vitamin D plays a pivotal role in the pathogenesis and treatment of renal bone disease. Vitamin D levels decline in the early phase of renal failure, however, through a compensatory mechanism parathyroid hormone (PTH) stimulates the production of 1,25-dihydroxyvitamin D(3) (1,25(OH)(2)D(3), calcitriol) to return it to normal circulating concentrations. Nevertheless, resistance to calcitriol is observed and may be related to the decreased presence of the heterodimeric, DNA-binding partner for the vitamin D receptor protein. In end-stage kidney disease (ESKD) the circulating levels of calcitriol are invariably low. The indications of vitamin D therapy are the replacement of the missing hormone vs suppression of hyperparathyroidism (HPT) requiring daily low-dose oral vs intermittent 'pulse' or oral administration. However, this therapy must be accompanied by careful patient monitoring to avoid hypercalcaemia and low bone turnover. Low bone turnover is not merely a histologic entity, but a clinical condition associated with a high risk of extraosseous calcifications, in particular in the cardiovascular system, leading to increased morbidity. Thus, determination of bone turnover in patients with ESKD is essential. Bone biopsy is the gold standard to assess bone turnover, however, it is not always available and nephrologists rely on PTH levels. The intact PTH assay measures PTH(1-84) and large C-PTH fragments, which may antagonize the PTH(1-84) effects on bone. An assay that measures exclusively PTH(1-84) has recently become available and a calculated PTH(1-84)/C-PTH fragment ratio has been shown to be the best predictor of bone turnover in patients with ESKD not treated with vitamin D or with other medications known to affect bone metabolism. 1,25-dihydroxy-22-oxavitamin D(3) (22-oxacalcitriol, OCT) is a vitamin D analogue that could control serum PTH concentrations without deleterious effects on bone.
Nephrol Dial Transplant 2002
PMID:Use and indication of vitamin D and vitamin D analogues in patients with renal bone disease. 1238 63

Secondary hyperparathyroidism (2HPT), a common disorder in patients with chronic renal failure, develops in response to phosphate retention and low serum 1,25-dihydroxyvitamin D(3) (1,25(OH)(2)D(3), calcitriol). Replacement therapy with calcitriol or its precursor 1alpha-hydroxyvitamin D(3) (1alphaOHD(3), alfacalcidol) often produces hypercalcaemia, especially when combined with calcium-based phosphate binders. In addition, these vitamin D compounds can aggravate the hyperphosphataemia in these patients. Several vitamin D analogues have been developed that retain the direct suppressive action of 1,25(OH)(2)D(3) on the parathyroid glands but have less calcaemic activity, thereby offering a safer and more effective means of controlling 2HPT. 1,25-Dihydroxy-19-norvitamin D(2) (19-norD(2)) and 1alpha-hydroxyvitamin D(2) (1alphaOHD(2)) are available in the US and 1,25-dihydroxy-22-oxavitamin D(3) (22-oxacalcitriol, OCT) and 1,25-dihydroxy-26,26,26,27,27,27-hexafluorovitamin D(3) (1,25(OH)(2)26,27F6 D(3), falecalcitriol) have been approved for use in Japan. Animal studies have demonstrated that OCT and 19-norD(2) have a wider therapeutic window for suppression of parathyroid hormone (PTH) because of their lower calcaemic and phosphataemic activities. The low calcaemic activity of OCT has been attributed to its rapid clearance, which prevents sustained effects on intestinal calcium absorption and bone resorption, but still allows a prolonged suppression of PTH gene expression and parathyroid cell growth. The calcaemic activity of 19-norD(2) diminishes with the duration of treatment by as yet unknown mechanisms. The lower toxicity of 1alphaOHD(2), compared with 1alphaOHD(3), has also been noted with chronic, but not acute administration, perhaps due to differential metabolism. The unique actions of falecalcitriol may also result from an altered metabolism. A clear understanding of the molecular basis for the selectivity of vitamin D analogues on parathyroid function may allow the design of even more effective analogues.
Nephrol Dial Transplant 2002
PMID:Vitamin D analogues for secondary hyperparathyroidism. 1238 64

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