Intermittent calcitriol therapy in secondary hyperparathyroidism: a comparison between oral and intraperitoneal administration

BACKGROUND: Intermittent oral or intravenous doses of calcitriol given two or three times per week are commonly used to treat secondary hyperparathyroidism (secondary HPT). This study was undertaken to compare the biochemical and skeletal responses to thrice weekly intraperitoneal (i.p.) versus oral doses of calcitriol in children with secondary HPT undergoing peritoneal dialysis (CCPD). METHODS: Forty-six patients aged 12.5+/-4.8 years on CCPD for 22+/-25 months were randomly assigned to treatment with oral (p.o.) or i.p. calcitriol for 12 months; 17 subjects given p.o. calcitriol and 16 subjects given i.p. calcitriol completed the study. Bone biopsies were performed at the beginning and at the end of the study, while determinations of serum and total ionized calcium, phosphorus, alkaline phosphatase, parathyroid hormone (PTH) and calcitriol levels were done monthly. RESULTS: Serum total and ionized calcium levels were higher in subjects treated with i.p. calcitriol, P < 0.0001, whereas serum phosphorus levels were higher in those given p.o. calcitriol, P < 0.0001. For the i.p. group, serum PTH levels decreased from pre-treatment values of 648+/-125 pg/ml to a nadir of 169+/-57 pg/ml after nine months. In contrast, serum PTH levels did not change from baseline values of 670+/-97 pg/ml in subjects given p.o. calcitriol, P < 0.0001 by multiple regression analysis. Serum alkaline phosphatase levels were also lower in patients treated with i.p. calcitriol, P < 0.0001, but there was no difference between groups in the average dose of calcitriol given thrice weekly. The skeletal lesions of secondary HPT improved in both groups, 33% of patients developed adynamic bone lesion. CONCLUSION: Differences in the bioavailability of calcitriol and/or in phosphorus metabolism may account for the divergent biochemical response to p.o. and i.p. calcitriol.     

Safety and efficacy of pulse and daily calcitriol in patients on CAPD: a randomized trial

BACKGROUND: Calcitriol therapy is the mainstay of therapy for the treatment of secondary hyperparathyroidism. Oral administration of calcitriol is necessary in CAPD patients, but no studies have directly compared different routes of administration in this patient population. METHODS: To determine if the peak serum calcitriol level (pulse therapy) is more important than the total delivered dose, we randomized CAPD patients with mild to moderate secondary hyperparathyroidism to receive either pulse (3.0 microg twice a week, n = 10) or daily (0.75 microg a day, n = 8) oral calcitriol in comparable weekly doses. The main comparison was the rate of decline of serum intact parathyroid hormone (PTH) levels to reach the desired end-point of 100 pg/ml. The patients were dialysed with low-calcium dialysate and received only calcium-containing phosphate binders. RESULTS: Pharmacokinetic analysis after a single dose of 3.0 microg (pulse) vs 0.75 microg (daily) revealed 1,25(OH)2-vitamin D levels to be higher in the pulse group at 3 and 6 h, but equivalent by 12 h. The area under the curve for 1 week of daily and 1 week of pulse therapy was equal. The patients in the 2 arms had equivalent basal serum levels of PTH (pulse = 562 +/- 291 vs daily = 454 +/- 113 pg/ml), calcium (pulse = 2.32 +/- 0.20 vs daily = 2.32 +/- 0.12 mmol/l) and phosphorus (pulse = 1.32 +/- 0.52 vs daily = 1.35 +/- 0.26 mmol/l). The time required for the PTH to decrease to 100 pg/ml and the rate of decline in PTH were similar (time: pulse = 14.2 +/- 6.8 weeks, daily = 12.2 +/- 7 weeks; rate: pulse = 7.4 +/- 4.2 vs daily = 8.4 +/- 4.2% PTH/week; P = NS). The serum calcium increased similarly in both groups. Hypercalcaemia (> 2.9 mmol/l) was rare (pulse = 3, daily = 2 episodes). CONCLUSIONS: This study demonstrates that pulse and daily calcitriol are similarly effective and safe for the treatment of mild to moderate secondary hyperparathyroidism in CAPD patients despite higher peak levels of 1,25(OH)2-vitamin D with pulse therapy.     

Oral calcitriol pulse therapy in treatment of secondary hyperparathyroidism in patients with long term hemodialysis

Oral calcitriol pulse therapy slowly becomes a method of choice in the treatment of secondary hyperparathyroidism in hemodialysis patients. It appears to be equally effective and simultaneously significantly cheaper than an intravenous therapy. In last year we have applied such a treatment to 12 hemodialysis patients with severe secondary hyperparathyroidism (iPTH range: 447-1228 pg/ml). All of them were hemodialysed 3 times a week with dialysate Ca+2 level 1.25-1.75 mM/l. Calcium carbonate was administered to maintain serum Ca level between 9.0-11.0 mg/dl and phosphate below 6.0 mg/dl. The patients were given calcitriol at dose 0.1 microgram/kg once a week, but it was obligatory to take a drug at bedtime, at least two hours after the last meal, a day before hemodialysis. During the treatment we divided the patients into two groups: I-patients who responded to our treatment (7/12); II-treatment was unsuccessful (5/12). In this group we decided to increase the dose of calcitriol to 0.075 micrograms/kg twice a week after 6 months use of a previous one. We have achieved statistically significant decrease of parathormone (p < 0.001) and alkaline phosphatase (p < 0.02) in group I and after the increase the dose of calcitriol there occurred the decrease of parathormone (p < 0.05) and alkaline phosphatase (p < 0.002) in group II. Simultaneously we have observed a great clinical improvement. Our results confirm the fact that even severe secondary hyperparathyroidism can be successfully treated with oral calcitriol pulse therapy. Administering of high doses of calcitriol at bedtime increases safety of this procedure-we have not observed any case of hypercalcemia.     

Hypercalcemia during pulse vitamin D3 therapy in CAPD patients treated with low calcium dialysate: the role of the decreasing serum parathyroid hormone level

Oral pulse therapy with vitamin D is effective in suppressing parathyroid hormone (PTH) secretion in continuous ambulatory peritoneal dialysis patients with secondary hyperparathyroidism (2'hpt). However, this treatment often leads to hypercalcemia. The goals of the study were: (1) to examine whether the incidence of hypercalcemia decreases when dialysate calcium is reduced from 1.25 to 1.0 mmol/L; (2) to determine the relative role of the factors involved in the pathogenesis of hypercalcemia; and (3) to study the efficacy of a low oral pulse dose of alfacalcidol in preventing the recurrence of 2'hpt. Fourteen continuous ambulatory peritoneal dialysis patients with 2'hpt were treated with pulse oral alfacalcidol and calcium carbonate and dialyzed with a 1.0-mmol (n = 7) or a 1.25-mmol (n = 7) dialysate calcium. The response rate (87%) and the incidence (71%) and severity of hypercalcemia were similar in both groups. In the early response stage, PTH decreased by 70% in both groups, and serum ionized calcium (iCa) increased from 1.18 +/- 0.02 to 1.27 +/- 0.04 mmol/L (P < 0.005) in the 1.0 group and from 1.19 +/- 0.02 to 1.29 +/- 0.02 mmol/L in the 1.25 group (P < 0.005). Nine of the 12 responders had a further decrease in serum PTH, which was associated with an additional increase in iCa from 1.28 +/- 0.02 to 1.47 +/- 0.04 (P < 0.005). Multivariate analysis showed that the early increase in iCa was positively correlated with alfacalcidol dosage (r = 0.69). In contrast, the late increase in iCa was mostly accounted for by the decrease in serum PTH (r = -0.93). This occurred while calcium carbonate, alfacalcidol dosage, and serum 1,25 hydroxy D3 remained unchanged compared with the early response stage. Finally, an alfacalcidol dose of 1 microg twice weekly was unable to maintain serum PTH at an adequate level in the long term. These data show that a reduction in dialysate calcium from 1.25 to 1.0 mmol does not reduce the occurrence of hypercalcemia and suggest that lowering serum PTH reduces the ability of the bone to handle a calcium load within a few weeks, thus causing hypercalcemia.     

Usefulness of calcium acetate as a chelating of phosphorus in patients in hemodialysis with secondary hyperthyroidism

In this study, we prospectively evaluated the efficacy of calcium acetate in patients with chronic renal insufficiency on hemodialysis programme with secondary hyperparathyroidism and hyperphosphatemia, which are difficult to control by means of the usual finders (calcium carbonate and aluminium hydroxide) and who were treated with pulses of calcitriol. We studied 10 patients. The inclusion criteria were: a serum phosphorus higher than 6.5 mg/dl, a serum PTHi higher than 250 pg/ml and a serum calcium higher than 9.5. The former therapy was stopped at the time of the patient was included in the study. Calcium acetate was initially introduced with doses between 2.5-4 g/day according to previous calcium and phosphate values. Also, all patients were initially treated with intermittent subcutaneous bolus of Calcitriol were modified and adjusted according to serum concentrations of calcium, phosphorus and PTHi. The concentration of calcium in the dialyzed was of 1.25 mmol/l. Fortnightly total calcium, phosphate and alkaline phosphatase serum determinations and monthly aluminium and PTHi serum determinations were carried out. During the 6 months treatment, a decrease was observed in serum concentrations of phosphate (p < 0.01), aluminum (p < 0.02) and PTHi (p < 0.001) with no changes in the values of calcium (p = ns) nor alkaline phosphatase (p = ns). The incidence of hypercalcemia was low during the follow-up period (11% of all biochemical serum determinations) and was easily controlled. We can conclude that calcium acetate is a sure and effective finder of phosphorus with a very good tolerance. Administered together with pulses of calcitriol, and the use of a low calcium concentration in the dialysate, it does not increase the risk of hypercalcemia.     

Low-dose intravenous calcitriol treatment of secondary hyperparathyroidism in hemodialysis patients. Italian Group for the Study of Intravenous Calcitriol

Intravenous calcitriol is known to directly suppress PTH secretion and release. We evaluated the effect of four months of treatment with low-dose intravenous calcitriol on PTH levels in 83 hemodialysis patients. The criteria for including patients in the study were a serum PTH levels at least four times the normal limit, a serum total calcium less than 10 mg/dl and good control of the serum phosphorus level. All patients underwent standard bicarbonate or acetate dialysis; dialysate calcium level was maintained at the usual 3.5 mEq/liter concentration. Initial calcitriol dose was 0.87 +/- 0.02 (SEM) micrograms (0.015 micrograms/kg body wt) thrice weekly at the end of dialysis, and it was reduced in case of hypercalcemia or elevated calcium-phosphate product. Seven out of 83 patients dropped out during treatment. Among the 76 patients who completed the study, 58 (76%) showed a highly significant decrease of intact PTH levels (average reduction 48%) and of alkaline phosphatase levels after four months of therapy. Total serum calcium increased slightly but significantly in the responder group but remained unchanged in the non-responders. No significant changes in ionized calcium levels could be detected, even in responders. Treatment was well tolerated by patients, but 60% of them had transient episodes of hyperphosphatemia. Mean serum phosphate was 4.95 mg/dl at the beginning of the study. It increased significantly after four months of treatment in patients who showed a decrease of PTH levels, although it remained within acceptable limits, below 5.5 mg/dl. Twenty-eight of 76 patients (37%) reduced the dose of calcitriol because their calcium-phosphate products exceeded 60.(ABSTRACT TRUNCATED AT 250 WORDS)     

1.25(OH)2 cholecalciferol pulse therapy and the effects of different dialysis membranes on serum PTH levels of haemodialysis patients

Either oral, intravenous or subcutaneous 1.25(OH)2 cholecalciferol is used in the therapy of hyperparathyroidism, which is a serious complication in patients on haemodialysis. We studied a total of 30 patients (10 women and 20 men) and divided them into two groups depending on the different types of dialysis membranes used. In the polysulfone group, mean age was 43.7 +/- 0.97 years and the average dialysis period lasted 29.9 +/- 1.23 months. For the 15 cases in which we used cuprophane membrane the mean age was 40.2 +/- 1.31 years and the average dialysis period lasted 16.2 +/- 0.86 months. The calcium level of the dialysate in both groups was 1.5 mmol/l. According to the study protocol, the determined oral calcitriol dose was 0.07 mg/kg and it was administered intermittently. After one month on high dose calcitriol therapy, treatment was continued with a maintenance dose of 0.03 mg/kg for a further six months. As a phosphate binding agent, daily 3 g calcium carbonate was administered. Before starting this treatment protocol, patients went on a 1 mg/day calcitriol therapy, although the mean PTH level was 424.63 pg/ml and the mean serum alkaline phosphatase level was 290.2 U/l. During the pretreatment period, levels of PTH, alkaline phosphatase, ionized calcium, and total calcium remained significantly within normal limits as a result of the new therapy protocol applied. PTH and phosphorus clearance rates were compared in the patient groups in which different dialysis membranes had been used. PTH and phosphorus clearances were 15.2 +/- 3 ml/min and 239.1 +/- 19.2 ml/min, respectively, in the polysulfone membrane group, and 1.1 +/- 0.3 ml/min and 112.8 +/- 9.88 ml/min, respectively, in the cuprophane membrane group (p < 0.05).     

Are we mismanaging calcium and phosphate metabolism in renal failure?

Secondary hyperparathyroidism and renal osteodystrophy are the consequences of abnormal calcium, phosphate, and calcitriol metabolism ensuing from renal failure. Evidence suggests that calcium balance tends to become negative as we grow older than 35 years of age; however, the current dialysis modalities provide patients regardless of age with excessive calcium during dialysis. Administration of calcitriol in the management of hyperparathyroidism further increases the calcium and phosphate absorption. Furthermore, the current thrice-weekly renal replacement therapies fail to remove the daily absorbed phosphate, and we have to use calcium carbonate as a primary phosphate-binding agent to reduce intestinal phosphate absorption. The large calcium mass transfer and phosphate retention could lead to soft tissue calcification, especially in older end-stage renal disease (ESRD) patients. Consequently, only by maintaining a negative calcium balance during renal replacement therapy can we safely use calcitriol and calcium carbonate for the management of secondary hyperparathyroidism. Recent studies have indicated that phosphate restriction alone independent of plasma calcitriol or calcium can lower plasma parathyroid hormone (PTH) in renal failure and prevent hyperplasia of parathyroid glands. Therefore, phosphate control perhaps is the most important means to prevent secondary hyperparathyroidism. Previous studies have shown that ferric compounds are potent phosphate-binding agents; hence, these compounds warrant further trial in the management of phosphate metabolism in renal failure.     

Kinetics of serum 1,84 iPTH after high dose of calcitriol in uremic patients

The temporal relation between oral administration of calcitriol and the nadir of PTH concentration is important for selecting optimal schedules of administration of calcitriol in the treatment of secondary hyperparathyroidism. To further assess this issue we examined 9 patients with preterminal renal failure (3 females, 6 males; median age 58.0 years, range 47-64, median S-Crea 4.8 mg/dl, range 3.7-6.8) with elevated baseline concentrations of 1,84 iPTH (median 46.0 pmol/l, range 18-100). After ingestion of a single oral dose of 2.0 micrograms calcitriol a transient rise in 1,25(OH)2D3 levels was seen with a peak at 6 h (from 20 pg/ml; 14-52 to 43 pg/ml; 35-102). 1,84 iPTH levels did not significantly change in the first 24 h, but were decreased significantly (p 0.01) 48 h after a single oral dose of calcitriol, the time to reach nadir varying from 24 to 96 hours. The percent decrease wa highest in patients with the highest baseline concentrations of 1,84 iPTH. Median 1,84 iPTH levels continued to remain below baseline at 48 h (25.0 pmol/l), 72 h (24.0 pmol/l) and 96 h (24.0 pmol/l) after oral calcitriol. A modest increase of S-Ca was noted which was not statistically significant. We conclude that 1. a single dose of oral calcitriol causes a delayed but long-lasting decrease of 1,84 iPTH, 2. decreased 1,84 iPTH levels persist despite return of calcitriol concentrations to baseline levels and 3. 1,84 iPTH may remain below baseline for more than 96 h.     

Developing habits and knowing what habits to develop: a look at the role of virtue in ethics

In vitro studies of parathyroid glands removed from dialysis patients with secondary hyperparathyroidism and hypercalcemia have demonstrated the presence of an increased set point of parathyroid hormone (PTH) stimulation by calcium (set point [PTHstim]), suggesting an intrinsic abnormality of the hyperplastic parathyroid cell. However, clinical studies on dialysis patients have not observed a correlation between the set point (PTHstim) and the magnitude of hyperparathyroidism. In the present study, 58 hemodialysis patients with moderate to severe hyperparathyroidism (mean PTH 780 +/- 377 pg/ml) were evaluated both before and after calcitriol treatment to establish the relationship among PTH, serum calcium, and the set point (PTHstim) and to determine whether changes in the serum calcium, as induced by calcitriol treatment, modified these relationships. Calcitriol treatment decreased serum PTH levels and increased the serum calcium and the setpoint (PTHstim); however, the increase in serum calcium was greater than the increase in the setpoint (PTHstim). Before treatment with calcitriol, the correlation between the set point (PTHstim) and the serum calcium was r = 0.82, p < 0.001, and between the set point (PTHstim) and PTH was r = 0.39, p = 0.002. After treatment with calcitriol, the correlation between the set point (PTHstim) and the serum calcium remained significant (r = 0.70, p < 0.001), but the correlation between the set point (PTHstim) and PTH was no longer significant (r = 0.09); moreover, a significant correlation was present between the change in the set point (PTHstim) and the change in serum calcium that resulted from calcitriol treatment (r = 0.73, p < 0.001). The correlation between the residual values (deviation from the regression line) of the set point (PTHstim), derived from the correlation between PTH and the set point (PTHstim), and serum calcium was r = 0.77, p < 0.001 before calcitriol and r = 0.72, p < 0.001 after calcitriol. In conclusion, the set point (PTHstim) increased after a sustained increase in the serum calcium, suggesting an adaptation of the set point to the existing serum calcium; the increase in serum calcium resulting from calcitriol treatment was greater than the increase in the set point (PTHstim); the set point (PTHstim) was greater in hemodialysis patients with higher serum PTH levels; and the correlation between PTH and the set point (PTHstim) may be obscured because the serum calcium directly modifies the set point (PTHstim).     

Elevation of serum phosphate affects parathyroid hormone levels in only 50% of hemodialysis patients, which is unrelated to changes in serum calcium

Hyperphosphatemia is said to cause hyperparathyroidism either by depressing the plasma levels of ionized calcium and/or by affecting serum 1,25(OH)2 vitamin D3 levels. Direct evidence that hyperphosphatemia contributes to hyperparathyroidism in hemodialysis patients is unclear because previous published data are with older parathyroid hormone (PTH) assays. Phosphate was added to the dialysate of 15 patients for 12 wk whose predialysis serum phosphates were between 1.5 and 1.9 mM (4.7 to 5.9 mg/dL) in order to further increase their serum phosphate by 0.75 mM (2.4 mg/dL) without adjustments in other medications. No patient was on vitamin D therapy. In half of the patients, PTH levels remained unchanged (nonresponders; 214 +/- 64 versus 219 +/- 60 ng/L), whereas in the other patients, PTH rose from 204 +/- 53 to 338 +/- 60 ng/L (P < 0.05; responders). The degree of induced hyperphosphatemia was virtually identical in both groups, 1.7 mM increasing to 2.4 mM. Ionized calcium was unchanged in both groups after phosphate. Plasma 1,25(OH)2 vitamin D3 levels were low to start with and remained low throughout. Nonresponders had been on dialysis twice as long as responders and had consumed over seven times more aluminum salts. Nonresponders had higher postdeferoxamine increments in plasma aluminum (3,588 +/- 1,466 versus 603 +/- 390; P < 0.05), although neither these amounts nor plasma levels were in the toxic range.(ABSTRACT TRUNCATED AT 250 WORDS)     

Predictors of short-term changes in serum intact parathyroid hormone levels in hemodialysis patients: role of phosphorus, calcium, and gender

Several factors have been identified as important in the pathogenesis of secondary hyperparathyroidism in end-stage renal disease, including serum calcium, phosphorus, and calcitriol. To examine the independent effects of key factors, we prospectively studied 52 new hemodialysis patients with mild secondary hyperparathyroidism (PTH, 110-670 pg/mL) treated with a standardized regimen of calcium supplements, phosphorus binders, and no vitamin D derivatives. We used simple and multivariable linear regression analysis to examine the relationship between changes in PTH (deltaPTH) levels observed over a 4-week period and various biochemical and demographic variables. By simple linear regression we found that changes in serum phosphorus (r2 = 0.31; beta = 41.6; P = 0.0001), initial phosphorus concentration (r2 = 0.15; beta = 33.4; P = 0.005), initial PTH level (r2 = 0.29; beta = 0.58; P = 0.0001), changes in serum calcium (r2 = 0.12; beta = -74.0; P = 0.01), and gender (r2 = 0.07; beta = 76.1; P = 0.05) were significantly associated with deltaPTH. However, upon multivariable regression analysis, only the changes in phosphorus (partial r2 = 0.31; beta = 37.0; P = 0.0001), initial PTH level (partial r2 = 0.23; beta = 0.50; P = 0.0001), and gender (partial r2 = 0.05; beta = 63.1; P = 0.02) remained significantly associated with deltaPTH. Neither the serum concentration of 1,25-dihydroxyvitamin D3, bicarbonate, aluminum, or albumin nor changes in the serum bicarbonate concentration, the presence of diabetes, KT/V, or age were significantly associated with the deltaPTH. Our findings are consistent with independent effects of phosphorus and gender on parathyroid gland function in patients with dialysis-dependent renal failure through mechanisms that remain to be defined.     

Distinct gap junction protein phenotypes in cardiac tissues with disparate conduction properties

The aim of this study was to assess the effect of a long-term course of high-dose i.v. pulses of calcitriol (CLT) on hyperparathyroid bone disease (HBD) and functional mass of parathyroid glands of chronically hemodialyzed uremic (CHU) patients. We prospectively studied nine CHU patients treated with CLT, 30 ng/kg/body wt, i.v., thrice weekly over a period of eight months. Plasma concentrations of intact parathyroid hormone (iPTH), bone GLA protein (bGLA) and bone isoenzyme of alkaline phosphatase (biALP) were sampled throughout. Transiliac bone biopsies were made before and after the start of CLT therapy. Double scanning scintigraphy of the neck with 201Tl-99Tc was made before, during and eight months after the start of the treatment. All patients but one, who later responded to higher than planned CLT doses, had significant decreases of plasma iPTH (F = 76; P < 0.0001; ANOVA). The mean pretreatment value of PTH was 966 +/- 160 (mean +/- SE) pg/ml and it had decreased significantly by the first week (T = 2.4, P < 0.04), and had fallen an average of 80% by the 35th week. Ionized plasma calcium concentration was 1.19 +/- .01 mmol/liter which rose significantly (F = 13.5; P < 0.0001) by the 14th week to maximal peak levels, averaging 1.34 +/- .02 mmol/liter. Changes in biALP were parallel to those of iPTH, while bGLA tended to increase immediately after the start of the therapy and to significantly decrease thereafter (T = 3.2; P < 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)     

A randomized trial of sevelamer hydrochloride (RenaGel) with and without supplemental calcium. Strategies for the control of hyperphosphatemia and hyperparathyroidism in hemodialysis patients

OBJECTIVE: We have previously shown sevelamer hydrochloride (RenaGel) to be an effective and well-tolerated treatment for hyperphosphatemia in hemodialysis patients. PATIENTS AND METHODS: We performed a randomized clinical trial to compare the efficacy of RenaGel alone and RenaGel with calcium, using the serum phosphorus concentration and intact parathyroid hormone (PTH) as the principal outcomes of interest. Calcium (900 mg elemental) was provided as a once-nightly dose on an empty stomach. 71 patients were randomized and included in the intent-to-treat population; 55 completed the 16-week study period (2 weeks washout, 12 weeks treatment, 2 weeks washout). 49% of subjects were taking vitamin D metabolites. RESULTS: Serum phosphorus and PTH rose significantly when patients stopped their phosphate binders during both washout periods. RenaGel and RenaGel with calcium were equally effective at reducing serum phosphorus (mean change -2.4 mg/dL vs. -2.3 mg/dL). RenaGel with calcium was associated with a small increase in serum calcium (mean change 0.3 mg/dL vs. 0.0 mg/dL in RenaGel group, P = 0.09) that was not statistically significant. During the treatment phase, the reduction in PTH tended to be greater in the RenaGel with calcium group (median change -67.0 vs. -22.5 pg/mL in RenaGel group, P = 0.07). Non-users of vitamin D metabolites treated with RenaGel with calcium experienced a significant decrease in PTH (median change -114.5 vs. -22 pg/mL in RenaGel group, P = 0.006). Adverse events were seen with equal frequency in both groups, being generally mild in intensity, and rarely attributable to the drugs. CONCLUSION: We conclude that RenaGel and RenaGel with calcium are similarly effective in the treatment of ESRD-related hyperphosphatemia. Provision of supplemental calcium or metabolites of vitamin D with RenaGel may enhance control of hyperparathyroidism.     

Pregnancy after renal transplantation: 25 years experience in Spain

OBJECTIVES: To evaluate the kinetics of calcitriol (1,25(OH)2D3) administered subcutaneously. STUDY DESIGN: Calcitriol kinetics and efficacy after subcutaneous administration were studied in 13 CAPD patients with varying degrees of increased plasma levels of parathyroid hormone (i-PTH). A single dose of 2 micrograms of calcitriol was administered subcutaneously, and its serum levels at baseline and after 1, 2, 6, 12, and 24 hours were determined. Plasma ionized calcium and i-PTH were also determined at these periods. RESULTS: Serum calcitriol levels reached peak levels of 60 and 70 pg/mL at 1 and 2 hours after administration, respectively. These levels decreased thereafter, but remained above baseline values during 24 hours. The mean value of the area under the curve (AUC) was 809 +/- 226 pg/mL/hour. Plasma i-PTH levels showed a slight decrease after 1 and 2 hours, returning to baseline levels after this period. Plasma ionized calcium did not show significant changes during the study. A slight pain at the site of injection was mentioned by some patients. CONCLUSIONS: The subcutaneous route for calcitriol administration achieves theoretically adequate plasma levels in continuous ambulatory peritoneal dialysis (CAPD) patients. This is important when parenteral administration of calcitriol is considered in the treatment of secondary hyperparathyroidism.     

Evidence of absorptive hypercalciuria in tuberculosis patients

In patients with granulomatous diseases, disturbances in calcium metabolism have been described. The aim of the study was to evaluate alterations in calcium metabolism in patients with tuberculosis. Forty patients with tuberculosis (TB) were studied in a baseline state (calcium intake 1000 mg/day). Fourteen of these patients were also studied after restrictive calcium diet (400 mg/calcium/day) and after a load of oral calcium of 1000 mg. In all the studies, calcium and phosphorus were measured in serum and urine, and parathyroid hormone (PTH) in plasma. In addition, serum 25OHD and 1,25(OH)2D (calcitriol) levels were measured in the baseline state and after the restrictive diet. In the baseline state, 25OHD levels were lower and urinary calcium higher in TB patients than in the control group. No patients had hypercalcemia, but hypercalciuria was present in 10 patients (25%). The patients with tuberculosis were divided according to the presence or absence of hypercalciuria. In both groups, the 25OHD levels were lower than in controls. Hypercalciuric patients had lower plasma parathyroid hormone levels and higher serum calcitriol levels than the control group and the TB patients without hypercalciuria. Urinary calcium excretion after a calcium load was higher in TB patients with hypercalciuria than in controls. A positive correlation was found between the calcitriol levels and postcalcium load urinary calcium excretion in patients with calcium hyperabsorption. These data indicate that absorptive hypercalciuria is frequently observed in patients with TB and is possible due to inappropriately high serum calcitriol levels.     

Minor physical anomalies in schizophrenia and mood disorders

The purpose of the present study was to examine the effect of a two day and a five day administration of 22-oxa-calcitriol (OCT) on calcium metabolism in rats with advanced chronic renal failure and severe secondary hyperparathyroidism. A first series of 27 uremic rats received either placebo, OCT or calcitriol (0.3 microgram i.p./rat) 48 and 24 hours before sacrifice. A second series of 18 uremic rats received either placebo, OCT (0.3 microgram i.p./rat) or calcitriol (0.05 microgram i.p./rat) for five days. We found that after 48 hours (series 1) both calcitriol and OCT increased blood ionized calcium (Ca2+) as compared to vehicle (1.23 +/- 0.04 and 1.10 +/- 0.02 mM, P < 0.01 and P < 0.05, respectively vs. control, 1.02 +/- 0.03 mM). Duodenal Ca transport (S/M) using the everted gut sac technique was not stimulated by OCT, even though it increased from 2.8 +/- 0.4 to 7.0 +/- 0.6 (P < 0.01) with calcitriol. In contrast, duodenal calbindin-D9k mRNA expression and protein content increased to a similar extent with OCT and calcitriol. Calcitriol was more potent in reducing plasma iPTH1-34 levels than OCT: 344 +/- 75 pg/ml (calcitriol) versus 632 +/- 46 pg/ml (OCT) compared with 897 +/- 74 pg/ml (control), P < 0.01. In the second series of rats, the injection of OCT (0.3 microgram i.p./rat) over five days was less effective than the lower dose of calcitriol (0.05 microgram i.p./rat) in reducing circulating iPTH: 110 +/- 26 (calcitriol) and 281 +/- 64 (OCT) versus 624 +/- 135 pg/ml (control), P < 0.01.(ABSTRACT TRUNCATED AT 250 WORDS)     

Residual urine in 75-year-old men and women. A normative population study

To evaluate the therapeutic effects of high dose pulse oral calcitrol, 3.5 micrograms calcitrol three times a week and calcium carbonate were administered to 13 patients with end-stage renal disease on chronic hemodialysis with hyperparathyroidism refractory to conventional calcitrol therapy. Serum parathyroid hormone and osteocalcin were detected by radioimmunoassay. Serum parathyroid hormone level of the patients decreased from 1111 +/- 344 ng/L to 492 +/- 218 ng/L by 57.5 +/- 11.5 percent (P < 0.01) in 6 months after the beginning of treatment. Both serum alkaline phosphatase and osteocalcin levels declined markedly, and correlated positively with that of parathyroid hormone. Plasma calcium concentration was markedly elevated, but no obvious increase of plasma phosphate was found. High dose pulse oral calcitrol was effective on secondary hyperparathyroidism. During the course of treatment timely and individual adjustment of calcitrol dose and dialysate calcium concentration is essential.     

Fracture strength of type IV and type V die stone as a function of time

OBJECTIVE: To evaluate risk/benefit of various continuous ambulatory peritoneal dialysis (CAPD) dialysate calcium concentrations. DATA SOURCES: A review of the literature on the effects of various CAPD dialysate Ca concentrations on plasma Ca, plasma phosphate, plasma parathyroid hormone (PTH), doses of calcium carbonate, doses of vitamin D analogs, and requirements of aluminum-containing phosphate binders. STUDY SELECTION: Eleven studies of nonselected CAPD patients, and 13 studies of CAPD patients with hypercalcemia were reviewed. RESULTS:In nonselected CAPD patients, treatment with a reduced dialysate Ca concentration (1.00, 1.25, or 1.35 mmol/L) improved the tolerance to calcium carbonate and/or vitamin D metabolites and reduced the need for Al-containing phosphate binders. When using dialysate Ca 1.25 or 1.35 mmol/L, the initial decrease of plasma Ca and increase of PTH could easily be reversed with an immediate adjustment of the treatment. After 3 months, stable plasma Ca and PTH levels could be maintained using only monthly investigations. In patients with hypercalcemia and elevated PTH levels, treatment with dialysate Ca concentrations below 1.25 mmol/L implied a considerable risk for the progression of secondary hyperparathyroidism. When hypercalcemia was present in combination with suppressed PTH levels, a controlled increase of PTH could be obtained with a temporary discontinuation of vitamin D and/or a reduction of calcium carbonate treatment in combination with a dialysate Ca concentration of 1.25 or 1.35 mmol/L. CONCLUSION: Most CAPD patients can be treated effectively and safely with a reduced dialysate Ca concentration of 1.35 or 1.25 mmol/L. Treatment with dialysate Ca concentrations below 1.25 mmol/L should not be used. A small fraction of patients with persistent hypocalcemia need treatment with high dialysate Ca, such as 1.75 mmol/L.     

Secondary hyperparathyroidism: pathophysiology, histopathology, and medical and surgical management

It is generally accepted that morphological changes of the parathyroid glands appear early in renal failure. When diffuse hyperplasia develops into a nodular type, the cells grow monoclonally and proliferate aggressively, with abnormal suppression of parathyroid hormone (PTH) secretion under high extracellular calcium. Based on histopathological and pathophysiological findings, patients with nodular hyperplasia in renal hyperparathyroidism might be refractory to medical treatment, including calcitriol pulse therapy. Thus, parathyroid surgery is indicated for individuals developing hypercalcemia, elevated PTH levels, and/or bone disease, who cannot be effectively treated medically. The detection of enlarged parathyroid glands by image diagnosis is another criterion for surgery. In our experience, parathyroidectomy is an effective treatment; however, the timing of the operation is important, because skeletal deformity and vessel calcification cannot be expected to diminish even after successful surgery. Technically, it is important to identify all parathyroid glands and, in autotransplantation, to use an adequate amount of suitable tissue, namely, a diffuse type of hyperplastic tissue, to guarantee satisfactory postoperative function.