Calcium-regulated parathyroid hormone secretion in adynamic renal osteodystrophy

Lack of FGF23 response to acute changes in serum calcium and PTH in humans

CONTEXT

1,25-Dihydroxyvitamin D (1,25D) administration and long-term increases in phosphate, PTH, and calcium concentrations are associated with increases in circulating fibroblast growth factor 23 (FGF23); however, whether or not acute changes in serum calcium modulate short-term FGF23 release is unknown.

OBJECTIVE/DESIGN

To assess the direct effect of acute changes in calcium and PTH on circulating FGF23 levels.

SETTING

A university clinical and translational research center.

PATIENTS/PARTICIPANTS

Twelve healthy volunteers and 10 dialysis patients.

INTERVENTIONS

Calcium gluconate and sodium citrate were infused for 120 minutes on 2 consecutive days.

MAIN OUTCOME MEASURES

Serum levels of ionized calcium, phosphorus, PTH, 1,25D, and plasma C-terminal FGF23 levels were obtained at 0, 13, 30, 60, 90, and 120 minutes during the infusions.

RESULTS

During the calcium infusion, serum calcium concentrations increased from 1.33 ± 0.01 to 1.57 ± 0.04 mmol/L (P < .05 from baseline) and from 1.20 ± 0.05 to 1.50 ± 0.03 mmol/L (P < .05 from baseline) in healthy subjects and in dialysis patients, respectively, whereas serum calcium values decreased from 1.33 ± 0.01 to 1.03 ± 0.02 mmol/L (P < .05 from baseline) and from 1.26 ± 0.04 to 1.07 ± 0.03 mmol/L (P < .05 from baseline) in the two groups, respectively during the sodium citrate infusion. PTH levels decreased from 35 (29, 57) to 8 (2,10) pg/mL (healthy subjects) (P < .05 from baseline) and from 292 (109, 423) to 44 (28, 86) pg/mL (dialysis patients) (P < .05 from baseline) during the calcium infusion and rose from 31 (25, 56) to 122 (95, 157) pg/mL and from 281 (117, 607) to 468 (169, 928) pg/mL (P < .05 from baseline) during sodium citrate infusion. Serum 1,25D levels and plasma FGF23 values remained unchanged during both infusions in both groups.

CONCLUSIONS

Short-term changes in calcium and PTH levels do not affect FGF23 concentrations in either healthy volunteers or dialysis patients.

Measuring parathyroid hormone (PTH) in patients with oxidative stress--do we need a fourth generation parathyroid hormone assay?

Oxidation of PTH at methionine residues results in loss of biological activity. PTH may be oxidized in patients with renal disease. The aim of this study was to develop an assay considering oxidation of PTH. Oxidized hPTH was analyzed by high resolution nano-liquid chromatography coupled to ESI-FTT tandem mass spectrometry (nanoLC-ESI-FT-MS/MS) directly and after proteolytic cleavage. The oxidized hPTH(1–84) sample shows TIC-peaks at 18–20 min and several mass peaks due to mass shifts caused by oxidations. No significant signal for oxidized hPTH(1–84) species after removal of oxidized PTH molecules by a specific column with monoclonal antibodies (MAB) raised against the oxidized hPTH was detectable. By using this column in samples from 18 patients on dialysis we could demonstrate that measured PTH concentrations were substantially lower when considering oxidized forms of PTH. The relationship between PTH concentrations determined directly and those concentrations measured after removal of the oxidized PTH forms varies substantially. In some patients only 7% of traditionally measured PTH was free of oxidation, whereas in other patients 34% of the traditionally measured PTH was real intact PTH. In conclusion, a huge but not constant proportion of PTH molecules are oxidized in patients requiring dialysis. Since oxidized PTH is biologically inactive, the currently used methods to detect PTH in daily clinical practice may not adequately reflect PTH-related bone and cardiovascular abnormalities in patients on dialysis.

Can the combination of calcium and parathormone levels above K/DOQI guidelines be used as a marker of adynamic bone disease in African Americans?

BACKGROUND

Patients of African American descent are at risk for the development of adynamic bone disease at parathyroid hormone levels 50% above the K/DOQI guidelines. Since a low bone formation rate is associated with hypercalcemia, attempts to reach one K/DOQI guideline may result in serum calcium levels above another K/DOQI guideline. Calcium levels above K/DOQI guidelines therefore may signal a need to stop parathyroid suppression.

STUDY DESIGN

SETTING AND PARTICIPANTS

Bone biopsies were performed at the East Alabama Medical Center, in Opelika AL, USA on eight patients (four Caucasians, four African Americans) whose parathormone levels and serum calcium levels both exceeded K/DOQI guideline recommendations.

RESULTS

All patients had mild to severe hyperparathyroid bone disease. No variable studied was predictive of the finding.

LIMITATIONS

Small sample size and the unavailability of the original Nichols Diagnostic Institute radioimmunoassay for parathormone.

CONCLUSION

We did not find hypercalcemia predictive of adynamic bone in patients of African American descent at levels of parathormone where low bone formation rates have been documented to occur. Since no parameter predicted bone histology, perhaps bone biopsies will be necessary to distinguish hyperparathyroidism from adynamic bone disease in African Americans with ESRD, hypercalcemia, and moderately elevated levels of PTH. Further studies are needed to determine appropriate therapy.

Long-term outcome of chronic dialysis in children

As the prevalence of children on renal replacement therapy (RRT) increases world wide and such therapy comprises at least 2% of any national dialysis or transplant programme, it is essential that paediatric nephrologists are able to advise families on the possible outcome for their child on dialysis. Most children start dialysis with the expectation that successful renal transplantation is an achievable goal and will provide the best survival and quality of life. However, some will require long-term dialysis or may return intermittently to dialysis during the course of their chronic kidney disease (CKD). This article reviews the available outcome data for children on chronic dialysis as well as extrapolating data from the larger adult dialysis experience to inform our paediatric practice. The multiple factors that may influence outcome, and, particularly, those that can potentially be modified, are discussed.

Development and progression of secondary hyperparathyroidism in chronic kidney disease: lessons from molecular genetics

The identification of the calcium-sensing receptor (CaSR) and the clarification of its role as the major regulator of parathyroid gland function have important implications for understanding the pathogenesis and evolution of secondary hyperthyroidism in chronic kidney disease (CKD). Signaling through the CaSR has direct effects on three discrete components of parathyroid gland function, which include parathyroid hormone (PTH) secretion, PTH synthesis, and parathyroid gland hyperplasia. Disturbances in calcium and vitamin D metabolism that arise owing to CKD diminish the level of activation of the CaSR, leading to increases in PTH secretion, PTH synthesis, and parathyroid gland hyperplasia. Each represents a physiological adaptive response by the parathyroid glands to maintain plasma calcium homeostasis. Studies of genetically modified mice indicate that signal transduction via the CaSR is a key determinant of parathyroid cell proliferation and parathyroid gland hyperplasia. Because enlargement of the parathyroid glands has important implications for disease progression and disease severity, it is possible that clinical management strategies that maintain adequate calcium-dependent signaling through the CaSR will ultimately prove useful in diminishing parathyroid gland hyperplasia and in modifying disease progression.

Mineral metabolism and vascular damage in children on dialysis

Cardiovascular disease is increasingly recognized as a life-limiting problem in young patients with chronic kidney disease, but there are few studies in children that describe its determinants. We studied the association of intact parathyroid hormone (iPTH) levels and their management on vascular structure and function in 85 children, ages 5-18 years, who had received dialysis for > or =6 months. Compared to controls, dialysis patients had increased carotid intima-media thickness and pulse-wave velocity. All vascular measures positively correlated with serum phosphorus levels, while carotid intima-media thickness and cardiac calcification score also correlated with iPTH levels. Patients with mean time-integrated iPTH levels less than twice the upper limit of normal (n = 41) had vascular measures that were comparable to age-matched controls, but those with iPTH levels greater than twice the upper limit of normal (n = 44) had greater carotid intima-media thickness, stiffer vessels, and increased cardiac calcification than controls. Patients with increased carotid intima-media thickness had stiffer vessels and a greater prevalence of cardiac calcification. There was a strong dose-dependent correlation between vitamin D and all vascular measures, and calcium intake from phosphate binders weakly correlated with carotid intima-media thickness. In conclusion, both iPTH level and dosage of vitamin D are associated with vascular damage and calcification in children on dialysis.

PHOSPHORUS METABOLISM AND MANAGEMENT IN CHRONIC KIDNEY DISEASE: Renal Osteodystrophy, Phosphate Homeostasis, and Vascular Calcification

New advances in the pathogenesis of renal osteodystrophy (ROD) change the perspective from which many of its features and treatment are viewed. Calcium, phosphate, parathyroid hormone (PTH), and vitamin D have been shown to be important determinants of survival associated with kidney diseases. Now ROD dependent and independent of these factors is linked to survival more than just skeletal frailty. This review focuses on recent discoveries that renal injury impairs skeletal anabolism decreasing the osteoblast compartment of the skeleton and consequent bone formation. This discovery and the discovery that PTH regulates the hematopoietic stem cell niche alters our view of secondary hyperparathyroidism in chronic kidney disease (CKD) from that of a disease to that of a necessary adaptation to renal injury that goes awry. Furthermore, ROD is shown to be an underappreciated factor in the level of the serum phosphorus in CKD. The discovery and the elucidation of the mechanism of hyperphosphatemia as a cardiovascular risk in CKD change the view of ROD. It is now recognized as more than a skeletal disorder, it is an important component of the mortality of CKD that can be treated.

Calcium and phosphorus metabolism in patients who have chronic kidney disease

Disturbances in calcium and phosphorus metabolism are almost invariable consequences of chronic kidney disease (CKD). Because the capacity to regulate calcium and phosphorus metabolism becomes compromised progressively as kidney function declines, calcium and phosphorus homeostasis is disrupted and serum calcium or phosphorus levels are perturbed in many patients with CKD. The level of interest in, and concerns about, abnormalities in calcium and phosphorus metabolism among patients with CKD has increased substantially in recent years. Strategies for clinical management are being revised, and recent recommendations differ substantially from those used previously with a renewed emphasis on safety.

Parathormone secretion in peritoneal dialysis patients with adynamic bone disease

The prevalence of low-turnover lesions in patients undergoing peritoneal dialysis (PD) is high. Our aims are to evaluate the prevalence of adynamic bone disease (ABD) in PD patients, analyze risk factors, and define the association of serum parathyroid hormone (PTH) levels measured under different plasma calcium concentrations with this lesion. Fifty-seven patients were studied by bone biopsy (BB). ABD was found in 63.2%, and 36.8% showed high-turnover bone disease (HTBD). Patients with HTBD had a lower prevalence of diabetes, younger age, lower accumulated oral calcium salt intake, and greater calcitriol doses, serum osteocalcin level, and ultrafiltration than patients with ABD. Both mean baseline PTH levels from the previous year and PTH level at time of BB were greater in patients with HTBD than those with ABD (357 +/- 267 pg/mL versus 89 +/- 67 pg/mL; 390 +/- 337 pg/mL versus 88 +/- 78 pg/mL, respectively; P < 0.05). However, the magnitude of the increase from baseline serum PTH levels in response to hypocalcemia was greater in patients with ABD than in those with HTBD (166.4% +/- 134% versus 83.5% +/- 73.6%; P < 0.05). We found that PTH levels less than 150 pg/mL in patients with ABD showed a sensitivity of 91. 6%, specificity of 95.2%, and positive predictive value (PPV) of 97%. In the HTBD group, PTH levels greater than 450 pg/mL had a specificity and PPV of 100%. Our data confirm that ABD is the most prevalent lesion in PD patients, and PTH secretion capacity is maintained in these patients. The definitive diagnosis and management strategies for many patients requires a BB, especially when HTBD is unlikely.

Adynamic bone and chronic renal failure: an overview

Renal osteodystrophy may present with a wide spectrum of bone lesions, ranging from high bone turnover to low bone turnover. Decreased serum calcium and 1,25-dihydroxy vitamin D synthesis and retention of phosphate are involved in the pathogenesis of high bone turnover. However, several factors may influence the evolution of this disorder. The use of different therapeutic approaches (such as calcium supplements, phosphate binders, vitamin D metabolites, etc.), the type of treatment (either hemodialysis or continuous ambulatory peritoneal dialysis), and also the changes in the type of patients to whom we are offering dialysis (more diabetics and older patients are currently included in dialysis programs) may have introduced changes modifying the form of presentation of the bone metabolic disorders. As a result, recent studies reported a greater prevalence of adynamic forms of renal osteodystrophy. Patients with adynamic bone (with or without aluminum) would have more difficulties in handling and buffering calcium loads; consequently, they would have a higher risk of extraosseous calcifications.

Influence of Glomerular Filtration Rate on Non-(1-84) Parathyroid Hormone (PTH) Detected by Intact PTH Assays

Background: Commercial intact parathyroid hormone (I-PTH) assays detect molecular form(s) of human PTH, non-(1-84) PTH, different from the 84-amino acid native molecule. These molecular form(s) accumulate in hemodialyzed patients. We investigated the importance of non-(1-84) PTH in the interpretation of the increased I-PTH in progressive renal failure.

Methods: Five groups were studied: 26 healthy individuals, 12 hemodialyzed patients, and 31 patients with progressive renal failure subdivided according to their glomerular filtration rate (GFR) into 11 with a GFR between 60 and 100 mL · min−1 · 1.73 m−2, 12 with a GFR between 30 and 60 mL · min−1 · 1.73 m−2, and 8 with a GFR between 5 and 30 mL · min−1 · 1.73 m−2. We evaluated indicators of calcium and phosphorus metabolism and creatinine clearance (CrCl) in the progressive renal failure groups, and the HPLC profile of I-PTH and C-terminal PTH in all groups.

Results: Only patients with a GFR &lt;30 mL · min−1 · 1.73 m−2 and hemodialyzed patients had decreased Ca2+ and 1,25-dihydroxyvitamin D, and increased phosphate. In patients with progressive renal failure, I-PTH was related to Ca2+ (r = −0.66; P &lt;0.0001), CrCl (r = −0.61; P &lt;0.001), 1,25-dihydroxyvitamin D (r = −0.40; P &lt;0.05), and 25-hydroxyvitamin D (r = −0.49; P &lt;0.01) by simple linear regression. The importance of non-(1-84) PTH in the composition of I-PTH increased with each GFR decrease, being 21% in healthy individuals, 32% in progressive renal failure patients with a GFR &lt;30 mL · min−1 · 1.73 m−2, and 50% in hemodialyzed patients, with PTH(1-84) making up the difference.

Conclusions: As I-PTH increases progressively with GFR decrease, part of the increase is associated with the accumulation of non-(1-84) PTH, particularly when the GFR is &lt;30 mL · min−1 · 1.73 m−2. Concentrations of I-PTH 1.6-fold higher than in healthy individuals are necessary in hemodialyzed patients to achieve PTH(1-84) concentrations similar to those in the absence of renal failure.

Low bone turnover in patients with renal failure

Renal failure inevitably leads to metabolic bone disease. Low turnover disease or adynamic bone disease (ABD) is characterized by a low number of osteoblasts with normal or reduced numbers of osteoclasts. Mineralization proceeds at a normal rate, resulting in normal or decreased osteoid thickness. Recently, it became clear that the relative contribution of the various types of renal osteodystrophy (ROD) to the spectrum of the histologic picture in renal failure patients underwent profound changes during the last 25 years. At the moment, the exact physiopathological mechanisms behind ABD are not yet elucidated, and thus the reason(s) for its increasing prevalence remains poorly understood. A number of epidemiological and experimental data suggest a multifactorial pathophysiologic process, in which hypoparathyroidism and suppression of the osteoblast are the main actors. Compared to adynamic bone disease, osteomalacia has now become a much rarer disease (around 4%), at least in Western countries. On the other hand, recent studies indicate that this particular bone disease entity might still regularly occur in less developed countries. Osteomalacia originates from a direct effect on the mineralization process. With this type of renal bone disease, the effects of secondary hyperparathyroidism on bone are overridden by a number of metabolic abnormalities that finally result in a defective bone mineralization, as occurs, for instance, when the lag time between osteoid deposition and its mineralization is increased. The relationship between exogenous and endogenous vitamin D deficiency (mainly calcitriol) and the histologic finding of osteomalacia in uremic patients is well known. Recent data showed distinctly lowered 25-(OH) vitamin D3 levels in the presence of unaffected calcitriol concentrations in patients with osteomalacic lesions, as assessed radiologically by the presence of Looser's zones. Recently, we found that bone strontium levels were increased in patients with osteomalacia as compared to all other types of ROD. Strontium accumulation appeared to originate mainly from the use of strontium-contaminated dialysate, which resulted from the addition of strontium-containing acetate-based concentrates. Evidence for a causal role of the element in the development of a mineralization defect could be tested experimentally by adding strontium to drinking water in a chronic renal failure rat model.

Effect of rate of calcium reduction and a hypocalcemic clamp on parathyroid hormone secretion: a study in dogs

BACKGROUND

The parathyroid hormone (PTH) calcium curve is used to evaluate parathyroid function in clinical studies. However, unanswered questions remain about whether PTH secretion is affected by the rate of calcium reduction and how the maximal PTH response to hypocalcemia is best determined. We performed studies in normal dogs to determine whether (a) the rate of calcium reduction affected the PTH response to hypocalcemia and (b) the reduction in PTH values during a hypocalcemic clamp from the peak PTH value observed during the nadir of hypocalcemia was due to a depletion of stored PTH.

METHODS

Fast (30 min) and slow (120 min) ethylenediamine-tetraacetic acid (EDTA) infusions were used to induce similar reductions in ionized calcium. In the fast EDTA infusion group, serum calcium was maintained at the hypocalcemic 30-minute value for an additional 90 minutes (hypocalcemic clamp). To determine whether the reduction in PTH values during the hypocalcemic clamp represented depletion of PTH stores, three subgroups were studied. Serum calcium was rapidly reduced from established hypocalcemic levels in the fast-infusion group at 30 and 60 minutes (after 30 min of a hypocalcemic clamp) and in the slow-infusion group at 120 minutes.

RESULTS

At the end of the fast and slow EDTA infusions, serum ionized calcium values were not different (0.84 +/- 0.02 vs. 0.82 +/- 0.03 mM), but PTH values were greater in the fast-infusion group (246 +/- 19 vs. 194 +/- 13 pg/ml, P < 0.05). During the hypocalcemic clamp, PTH rapidly decreased (P < 0.05) to value of approximately 60% of the peak PTH value obtained at 30 minutes. A rapid reduction in serum calcium from established hypocalcemic levels at 30 minutes did not stimulate PTH further, but also PTH values did not decrease as they did when a hypocalcemic clamp was started at 30 minutes. At 60 minutes, the reduction in serum calcium increased (P < 0.05) PTH to peak values similar to those before the hypocalcemic clamp. The reduction in serum calcium at 120 minutes in the slow EDTA infusion group increased PTH values from 224 +/- 11 to 302 +/- 30 pg/ml (P < 0.05).

CONCLUSIONS

These results suggest that (a) the reduction in PTH values during the hypocalcemic clamp may not represent a depletion of PTH stores. (b) The use of PTH values from the hypocalcemic clamp as the maximal PTH may underestimate the maximal secretory capacity of the parathyroid glands and also would change the analysis of the PTH-calcium curve, and (c) the PTH response to similar reductions in serum calcium may be less for slow than fast reductions in serum calcium.

Bone mass and dynamic parathyroid function according to bone histology in nondialyzed uremic patients after long-term protein and phosphorus restriction

One year of a very low protein diet (VLPD) can reverse secondary hyperparathyroidism in uremic patients. We studied bone histology, bone mineral density (BMD), and dynamic parathyroid function (calcium/PTH curves) in 16 nondialyzed patients with advanced renal failure who had been receiving a VLPD for a mean of 5 yr (mean protein intake, 0.34 +/- 0.12 mg/kg x day; mean phosphorus intake, 8.2 +/- 2.1 mg/kg x day) and daily supplementation with essential amino acids and their ketoanalogs (1000 IU vitamin D2 and 1-2 g calcium carbonate). Three patients exhibited a high bone formation rate (BFR), 7 patients had normal bone remodeling, and 6 patients had a low BFR, including 2 with osteomalacia and 4 with adynamic bone disease without aluminum overload. A longer diet duration and lower caloric intake were associated with low BFR. More than half of the patients exhibited moderate or severe osteoporosis at the appendicular skeleton. The t score of femur BMD explained 65% of the BFR variance. Patients with a low BFR had a dynamic parathyroid function similar to that of patients with a normal BFR, except they had a lower capacity to buffer a calcium load, whereas patients with a high BFR had a higher basal PTH/maximum PTH and a steeper calcium/PTH curve slope; the calcium set-point was identical in the three groups.

A non-(1–84) circulating parathyroid hormone (PTH) fragment interferes significantly with intact PTH commercial assay measurements in uremic samples

We have previously shown that the Nichols assay for intact parathyroid hormone (I-PTH) reacts with a non-(1–84) molecular form of PTH. This form behaves as a carboxy-terminal fragment and accumulates in renal failure, accounting for 40–60% of the measured immunoreactivity. We wanted to see whether this was a common event with other commercial two-site I-PTH assays. We thus compared the ability of three commercial kits [Nichols (NL), Incstar (IT), and Diagnostic System Laboratories (DSL)] to measure I-PTH in 112 renal failure patients and to detect hPTH(1–84) and non-(1–84)PTH on HPLC profiles of serum pools from uremic patients with I-PTH concentrations of 10–100 pmol/L. The behavior of synthetic hPTH(7–84), a fragment possibly related to non-(1–84)PTH was also compared with hPTH(1–84) in the three assays. The I-PTH concentrations measured with the three assays in the 112 uremic samples were highly related (r2 ≥ 0.89, P &lt;0.0001), and the values measured with NL were, on average, 23% higher than IT. Values measured with DSL were 23% and 56% higher than IT for values less than and more than 40 pmol/L, respectively. The three assays detected two HPLC peaks on four different profiles corresponding to hPTH(1–84) and non-(1–84)PTH. This last peak represented 36 ± 8.4% of the immunoreactivity with NL, 24 ± 5.5% with IT, and 25 ± 2.8% with DSL (NL vs IT or DSL: P &lt;0.05). These differences were confirmed by a 50% lower immunoreactivity to hPTH(7–84) compared with hPTH(1–84) for IT and DSL but not for NL. These results suggest that most of the two-site I-PTH assays would cross-react with non-(1–84)PTH material, thus explaining about one-half of the 2–2.5 × higher I-PTH concentrations reported in uremic patients without bone involvement than in subjects without uremia.

Suppressive effect of calcium on parathyroid hormone release in adynamic renal osteodystrophy and secondary hyperparathyroidism

Serum parathyroid hormone (PTH) levels are markedly lower in patients with the adynamic lesion (AD) of renal osteodystrophy than in those with secondary hyperparathyroidism (2 degrees HPT), but serum PTH values are often moderately elevated in AD when compared to subjects with normal renal and parathyroid gland function (NL). To study the inhibitory effect of calcium on PTH release in AD and in 2 degrees HPT, the response to two-hour intravenous calcium infusions was examined in 6 patients with AD, in 31 patients with 2 degrees HPT and in 20 NL. Basal serum PTH levels were 88 +/- 51, 536 +/- 395, and 26 +/- 6 pg/ml, respectively, in AD, 2 degrees HPT and NL, whereas basal ionized calcium levels did not differ. When expressed as a percentage of pre-infusion values, PTH levels at the end of two-hour calcium infusions were higher both in AD (23.2 +/- 5.6%) and in 2 degrees HPT (27.8 +/- 12.3%) than in NL, (11.9 +/- 5.8%, P < 0.001). Both the amplitude of suppression (%) and the rate of decline (min-1) in serum PTH were less in AD and 2 degrees HPT than in NL, P < 0.05 for each parameter; corresponding values for each group, with 95% confidence intervals, were 77% (73 to 82) and 0.039 min-1 (0.030 to 0.048) in AD, 72% (68 to 76) and 0.031 min-1 (0.025 to 0.036) in 2 degrees HPT and 87% (84 to 89) and 0.070 min-1 (0.058 to 0.089) in NL. Neither variable differed between AD and 2 degrees HPT. Basal and nadir serum PTH levels were highly correlated: r = 0.95 and P < 0.05 in AD; r = 0.90 and P < 0.01 in 2 degrees HPT; r = 0.75 and P < 0.01 in NL. The slope of this relationship was less, however, both in AD and in 2 degrees HPT than in NL, P < 0.05 by analysis of co-variance. Thus, serum PTH levels fell below 20% of pre-infusion values in fewer subjects with AD (1 of 6) or 2 degrees HPT (9 of 31) than in NL (17 of 20) (chi 2 = 17.81, P < 0.005). The results indicate that the inhibitory effect of calcium on PTH release in vivo does not differ in AD and 2 degrees HPT despite marked differences in basal serum PTH levels. Variations in functional parathyroid gland mass rather than disturbances in calcium-sensing by the parathyroids probably account not only for the lower basal serum PTH levels in patients with AD compared to those with 2 degrees HPT, but also for the moderately elevated serum PTH values commonly seen in patients with AD.

Evidence for both abnormal set point of PTH stimulation by calcium and adaptation to serum calcium in hemodialysis patients with hyperparathyroidism

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).

In vivo assessments of calcium-regulated parathyroid hormone release in secondary hyperparathyroidism

In vivo dynamic tests of parathyroid gland function have provided useful information about the secretory behavior of parathyroids in various clinical disorders, but the limitations of this approach must be recognized when applied to studies of parathyroid gland physiology. Set point abnormalities have been documented in vivo both in primary hyperparathyroidism and in familial hypocalciuric hypercalcemia. Such findings are consistent with in vitro results obtained in studies of dispersed parathyroid cells from patients with primary hyperparathyroidism and with recently described alteration in calcium receptor expression in patients with FHH. The assessment of parathyroid gland function in patients with end-stage renal disease presents distinct methodological problems, however, because of marked variation in the degree of parathyroid gland enlargement. Neither the four parameter model originally used to describe set point abnormalities both in vitro and in vivo or alternative approaches to the assessment of PTH secretion in vivo adequately address this important issue. Results from recent in vivo studies of patients with chronic renal failure do not support the view that the set point for calcium-regulated PTH release is abnormal in secondary hyperparathyroidism or that treatment with calcitriol lowers the set point for calcium-regulated PTH release in patients with uremic secondary hyperparathyroidism. The concept of set point disturbances has strongly influenced discussions about the pathogenesis of secondary hyperparathyroidism, and it has served as a focal point for examining the therapeutic response to calcitriol in patients with this disorder. This matter requires careful reconsideration, however, in light of recent clinical findings and the development of techniques to directly assess the molecular mechanisms responsible for regulating calcium-mediated PTH release in renal failure and other disorders of mineral metabolism. Although knowledge in this area remains limited, the extent of parathyroid hyperplasia and the role of factors that influence the development of parathyroid gland enlargement may ultimately prove to be particularly important modifiers of parathyroid gland function in chronic renal failure.

Non-suppressible parathyroid hormone secretion is related to gland size in uremic secondary hyperparathyroidism

To determine the relative importance of parathyroid gland enlargement and alterations in calcium sensing (set-point changes) in the pathogenesis of uremic secondary hyperparathyroidism (2 degrees HPT), we investigated the relationship between estimates of parathyroid gland size and calcium-mediated parathyroid hormone (PTH) suppression in 19 normocalcemic 2 degrees HPT patients on chronic maintenance hemodialysis. We compared our results to calcium-mediated PTH suppression in 12 normal volunteers, 12 patients with familial benign hypocalciuric hypercalcemia (FBHH), a disorder of abnormal calcium sensing, and 9 subjects with primary hyperparathyroidism (1 degree HPT), which is characterized by both calcium set-point abnormalities and parathyroid gland enlargement. We found that the 2 degrees HPT group displayed a distinctive pattern of calcium-mediated PTH suppression characterized by a failure to normally suppress PTH at supraphysiologic ionized calcium concentrations, similar to 1 degree HPT, but without the rightward shift of the calcium-PTH suppression curve that characterizes calcium sensing abnormalities in FBHH and 1 degree HPT. In the patients with 2 degrees HPT, hypercalcemic suppression resulted in an ending PTH (as a percent of baseline) that was significantly higher (39.8 +/- 4.47%), and a slope of the calcium-PTH suppression curve that was significantly less negative (-4.8 +/- 0.53), compared to respective values of 19.4 +/- 1.81% (P = 0.0009) and -9.0 +/- 1.02 (P = 0.001) in normals and 19.1 +/- 2.49% (P = 0.001) and -9.6 +/- 1.11 (P = 0.0006) in FBHH. Values of ending PTH and slope in 2 degrees HPT patients, however, were similar to those found in 1 degree HPT (49.8 +/- 6.35%, P = 0.21 and -4.5 +/- 0.74, P = 0.72). The ionized calcium concentration required to attain half maximal PTH suppression (EC50) in 2 degrees HPT (1.20 +/- 0.02 mmol/liter) was not significantly different from normals (1.25 +/- 0.01 mmol/liter, P = 0.12) but was significantly less than in 1 degree HPT (1.52 +/- 0.02 mmol/liter, P < 0.0001) and in FBHH (1.44 +/- 0.02 mmol/liter, P < 0.0001). More importantly, we found a significant linear correlation between the natural logarithm of gland size and ending PTH suppression (r = 0.71, P < 0.001) and slope of the calcium-PTH curve (r = 0.67, P = 0.002) in 2 degrees HPT. Thus, calcium non-suppressible PTH secretion in 2 degrees HPT does not represent a simple set-point error, but rather correlates with the degree of parathyroid gland enlargement.

Hysteresis of the PTH-calcium curve during hypocalcemia in the dog: effect of the rate and linearity of calcium decrease and sequential episodes of hypocalcemia

Several studies have shown the presence of hysteresis of the parathyroid hormone (PTH)-calcium relationship in both normal humans and hemodialysis patients; for hypocalcemia, hysteresis is defined as a lower PTH level for the same serum calcium during the recovery from than the induction of hypocalcemia. However, some have questioned whether hysteresis is only a function of the rate and/or direction of change in calcium, and others have proposed that hysteresis is due to depletion of PTH stores. To address these issues, two groups of dogs were studied. To induce hypocalcemia, sodium EDTA (50 mg/kg) was infused either over 60 (termed slow) or 30 (termed fast) minutes; immediately after the cessation of the ethylenediamine tetracetate (EDTA) infusion, calcium chloride (0.75 mEq/kg) was infused over 60 or 30 minutes, respectively, to correct the hypocalcemia. The EDTA infusion produced a linear decrease in serum calcium by progressively increasing the infusion rate at regular intervals. A second cycle of hypocalcemia and recovery using the same protocol was started immediately after the completion of the first cycle. To determine whether a nonlinear decrease in the serum calcium affected the PTH response to hypocalcemia, a third group of dogs, termed superfast, was studied; in this group, EDTA was infused for 30 minutes at a constant rate of 50 mg/kg. The hysteretic loops of PTH produced by the two sequential slow and fast cycles and the superfast cycle during the induction of and recovery from hypocalcemia were similar. Moreover, the maximal PTH level for the two sequential slow and fast cycles and the superfast cycle was not different even though the rates of calcium decrease varied and the calcium decrease was nonlinear in the superfast cycle. In conclusion, (1) since hysteresis was reproducible and the maximal PTH was not different during two sequential cycles of hypocalcemia, hysteresis is not due to PTH depletion; (2) the PTH-calcium curve is not affected by the rate at which hypocalcemia is induced; and (3) the maximal PTH level is not influenced by either the rate or linearity of the reduction in serum calcium.

The renal bone diseases in children treated with dialysis

Renal osteodystrophy represents a spectrum from high- to low-turnover bone lesions. The specific pattern, however, may change during selected therapeutic interventions. As in the past, osteitis fibrosa remains the most frequent histologic lesion in pediatric patients on dialysis, although recently the prevalence of low-turnover bone lesions without aluminum toxicity has been increasing in the pediatric population. This may be a consequence of aggressive calcitriol and calcium therapy. The different factors involved in the development of secondary hyperparathyroidism include hyperphosphatemia, hypocalcemia, altered vitamin D synthesis, impairments in parathyroid hormone (PTH) secretion and metabolism, and, recently, possible downregulation of renal PTH/PTH-rP messenger RNA receptor. New developments in molecular biology have demonstrated the relationship between vitamin D and PTH. The use of high-dose pulse intravenous, intraperitoneal, and oral calcitriol therapy has significantly decreased serum PTH levels and retarded the progression of osteitis fibrosa. These therapeutic interventions, however, may have led to the development of adynamic bone lesions. The impact of adynamic bone lesions in the young and growing skeleton remains to be determined.