Calcemic response to parathyroid hormone in renal failure: role of calcitriol and the effect of parathyroidectomy

Silver jubilee: 25 years of the first demonstration of the direct effect of phosphate on the parathyroid cell

Although phosphorus is an essential element for life, it is not found in nature in its native state but rather combined in the form of inorganic phosphates (PO₄^3-), with tightly regulated plasma levels that are associated with deleterious effects and mortality when these are out of bounds. The growing interest in the accumulation of PO₄^3- in human pathophysiology originated in its attributed role in the pathogenesis of secondary hyperparathyroidism (SHPT) in chronic kidney disease. In this article, we review the mechanisms by which this effect was justified and we commemorate the important contribution of a Spanish group led by Dr. M. Rodríguez, just 25 years ago, when they first demonstrated the direct effect of PO₄^3- on the regulation of the synthesis and secretion of parathyroid hormone by maintaining the structural integrity of the parathyroid glands in their original experimental model. In addition to demonstrating the importance of arachidonic acid (AA) and the phospholipase A2-AA pathway as a mediator of parathyroid gland response, these findings were predecessors of the recent description of the important role of PO₄^3- on the activity of the calcium sensor-receptor, and also fueled various lines of research on the importance of PO₄^3- overload not only for the pathophysiology of SHPT but also in its systemic pathogenic role.

Hyporesponsiveness or resistance to the action of parathyroid hormone in chronic kidney disease

Secondary hyperparathyroidism (SHPT) is an integral component of the chronic kidney disease-mineral and bone disorder (CKD-MBD). Many factors have been associated with the development and progression of SHPT but the presence of skeletal or calcemic resistance to the action of PTH in CKD has often gone unnoticed. The term hyporesponsiveness to PTH is currently preferred and, in this chapter, we will not only review the scientific timeline but also some of the molecular mechanisms behind. Moreover, the presence of resistance to the biological action of PTH is not unique in CKD since resistance to other hormones has also been described ("uremia as a receptor disease"). This hyporesponsiveness carries out important clinical implications since it explains, at least partially, not only the progressive nature of the pathogenesis of CKD-related PTH hypersecretion and parathyroid hyperplasia but also the increasing prevalence of adynamic bone disease in the CKD population. Therefore, we underline the importance of PTH control in all CKD stages, but not aiming to completely normalize PTH levels since a certain degree of SHPT may represent an adaptive clinical response. Future studies at the molecular level, i.e. on uremia or the recent description of the calcium-sensing receptor as a phosphate sensor, may become of great value beyond their significance to explain just the hyporesponsiveness to PTH in CKD.

Hyporesponsiveness or resistance to the action of parathyroid hormone in chronic kidney disease

Secondary hyperparathyroidism (SHPT) is an integral component of the chronic kidney disease-mineral and bone disorder (CKD-MBD). Many factors have been associated with the development and progression of SHPT but the presence of skeletal or calcemic resistance to the action of PTH in CKD has often gone unnoticed. The term hyporesponsiveness to PTH is currently preferred and, in this chapter, we will not only review the scientific timeline but also some of the molecular mechanisms behind. Moreover, the presence of resistance to the biological action of PTH is not unique in CKD since resistance to other hormones has also been described ("uremia as a receptor disease"). This hyporesponsiveness carries out important clinical implications since it explains, at least partially, not only the progressive nature of the pathogenesis of CKD-related PTH hypersecretion and parathyroid hyperplasia but also the increasing prevalence of adynamic bone disease in the CKD population. Therefore, we underline the importance of PTH control in all CKD stages, but not aiming to completely normalize PTH levels since a certain degree of SHPT may represent an adaptive clinical response. Future studies at the molecular level, i.e. on uremia, or the recent description of the calcium-sensing receptor as a phosphate sensor, may become of great value beyond their significance to explain just the hyporesponsiveness to PTH in CKD.

Recent advances in understanding and managing secondary hyperparathyroidism in chronic kidney disease

Secondary hyperparathyroidism is a complex pathology that develops as chronic kidney disease progresses. The retention of phosphorus and the reductions in calcium and vitamin D levels stimulate the synthesis and secretion of parathyroid hormone as well as the proliferation rate of parathyroid cells. Parathyroid growth is initially diffuse but it becomes nodular as the disease progresses, making the gland less susceptible to be inhibited. Although the mechanisms underlying the pathophysiology of secondary hyperparathyroidism are well known, new evidence has shed light on unknown aspects of the deregulation of parathyroid function. Secondary hyperparathyroidism is an important feature of chronic kidney disease-mineral and bone disorder and plays an important role in the development of bone disease and vascular calcification. Thus, part of the management of chronic kidney disease relies on maintaining acceptable levels of mineral metabolism parameters in an attempt to slow down or prevent the development of secondary hyperparathyroidism. Here, we will also review the latest evidence regarding several aspects of the clinical and surgical management of secondary hyperparathyroidism.

Risk of carpal tunnel syndrome after parathyroidectomy in patients with end-stage renal disease: A population-based cohort study in Taiwan

Carpal tunnel syndrome (CTS) is the most common mononeuropathy in clinical practice. Some patients with end-stage renal disease (ESRD) often associate with tertiary hyperparathyroidism, and ultimately need parathyroidectomy (PTX). However, no studies have definitively demonstrated an effect of PTX on ESRD patients' quality of life. We selected 1686 patients who underwent PTX and 1686 patients who did not receive PTX between 2000 and 2010. These patients were propensity-matched with others by age, sex, and comorbidities at a ratio of 1:1. We used single and multivariable cox proportional hazard models to estimate hazard ratios (HRs) and corresponding 95% confidence intervals (CIs). In this study, 116 ESRD patients developed CTS, and the CTS incidences were 7.33 and 12.5 per 1000 person-years for the non-PTX and PTX group. The results reveal that the incidence curve for the PTX group was significantly higher than that for the non-PTX group (log-rank test, P = .004). After adjustments were made for sex, age, and baseline comorbidities, the PTX group had a 1.70-fold higher risk of CTS (hazard ratio (HR) = 1.70, 95% confidence intervals (CI) = 1.17-2.47) than the non-PTX group. The results also demonstrated that female patients (HR = 1.60, 95% CI = 1.06-2.42) and patients with one or more comorbidities (HR = 1.79, 95% CI = 1.23-2.60) might have an increased risk of CTS. The subhazard ratio for CTS risk was 1.62 (95% CI = 1.12-2.36) for the PTX group compared with the non-PTX group in the competing risk of death. In conclusion, we revealed that ESRD patients who had undergone PTX may have an increased risk of CTS.

Parathyroid Hormone Measurement in Chronic Kidney Disease: From Basics to Clinical Implications

Accurate measurement of parathyroid hormone (PTH) is crucial for therapeutic decision-making in patients with chronic kidney disease-mineral and bone disorder (CKD-MBD). The second-generation PTH assays, often referred to as "intact PTH" assays, are the current standard and most available assays in clinical practice. However, intact PTH assays measure both full-length biologically active PTH and heterogeneous PTH fragments in the circulation, providing the equivocal value of PTH measurement in patients with CKD-MBD. Due to the variability of PTH assays, preanalytical sample errors, and the phenomenon of end-organ PTH hyporesponsiveness, current CKD-MBD guidelines recommend a wide range for serum PTH targets (2-9 the upper normal limit of the intact PTH assay) in dialysis patients to diminish the risk of developing adynamic bone disease. Nevertheless, a sizeable proportion of CKD patients still experience renal osteodystrophy despite having serum PTH levels within the recommended range. The primary cause of this inconsistency is the analytical interference of various PTH fragments and oxidized PTH forms that considerably accumulate in CKD patients. Therefore, a new mass spectrometry-based assay, which is capable of specifically measuring the whole spectra of PTH fragments, can potentially improve diagnostic accuracy for renal osteodystrophy. However, the effects of different PTH fragments on bone metabolism, vascular calcification, and mortality in CKD patients warrant further research.

FGF23, Biomarker or Target?

Fibroblast growth factor 23 (FGF23) plays a key role in the complex network between the bones and other organs. Initially, it was thought that FGF23 exclusively regulated phosphate and vitamin D metabolism; however, recent research has demonstrated that an excess of FGF23 has other effects that may be detrimental in some cases. The understanding of the signaling pathways through which FGF23 acts in different organs is crucial to develop strategies aiming to prevent the negative effects associated with high FGF23 levels. FGF23 has been described to have effects on the heart, promoting left ventricular hypertrophy (LVH); the liver, leading to production of inflammatory cytokines; the bones, inhibiting mineralization; and the bone marrow, by reducing the production of erythropoietin (EPO). The identification of FGF23 receptors will play a remarkable role in future research since its selective blockade might reduce the adverse effects of FGF23. Patients with chronic kidney disease (CKD) have very high levels of FGF23 and may be the population suffering from the most adverse FGF23-related effects. The general population, as well as kidney transplant recipients, may also be affected by high FGF23. Whether the association between FGF23 and clinical events is causal or casual remains controversial. The hypothesis that FGF23 could be considered a therapeutic target is gaining relevance and may become a promising field of investigation in the future.

TGF-Beta Signaling in Bone with Chronic Kidney Disease

Transforming growth factor (TGF)-β signaling is not only important in skeletal development, but also essential in bone remodeling in adult bone. The bone remodeling process involves integrated cell activities induced by multiple stimuli to balance bone resorption and bone formation. TGF-β plays a role in bone remodeling by coordinating cell activities to maintain bone homeostasis. However, mineral metabolism disturbance in chronic kidney disease (CKD) results in abnormal bone remodeling, which leads to ectopic calcification in CKD. High circulating levels of humoral factors such as parathyroid hormone, fibroblast growth factor 23, and Wnt inhibitors modulate bone remodeling in CKD. Several reports have revealed that TGF-β is involved in the production and functions of these factors in bone. TGF-β may act as a factor that mediates abnormal bone remodeling in CKD.

Tradeoff-in-the-Nephron: A Theory to Explain the Primacy of Phosphate in the Pathogenesis of Secondary Hyperparathyroidism

Chronic kidney disease (CKD) causes secondary hyperparathyroidism (SHPT). The cardinal features of SHPT are persistence of normocalcemia as CKD progresses and dependence of the parathyroid hormone concentration ([PTH]) on phosphate influx (IP). The tradeoff-in-the-nephron hypothesis integrates these features. It states that as the glomerular filtration rate (GFR) falls, the phosphate concentration ([P]CDN) rises in the cortical distal nephron, the calcium concentration ([Ca]CDN) in that segment falls, and [PTH] rises to maintain normal calcium reabsorption per volume of filtrate (TRCa/GFR). In a clinical study, we set GFR equal to creatinine clearance (Ccr) and IP equal to the urinary excretion rate of phosphorus (EP). We employed EP/Ccr as a surrogate for [P]CDN. We showed that TRCa/Ccr was high in patients with primary hyperparathyroidism (PHPT) and normal in those with SHPT despite comparably increased [PTH] in each group. In subjects with SHPT, we examined regressions of [PTH] on EP/Ccr before and after treatment with sevelamer carbonate or a placebo. All regressions were significant, and ∆[PTH] correlated with ∆EP/Ccr in each treatment cohort. We concluded that [P]CDN determines [PTH] in CKD. This inference explains the cardinal features of SHPT, much of the evidence on which other pathogenic theories are based, and many ancillary observations.

Relationship between Fibroblast Growth Factor 23 and Biochemical and Bone Histomorphometric Alterations in a Chronic Kidney Disease Rat Model Undergoing Parathyroidectomy

Background

Phosphate burden in chronic kidney disease (CKD) leads to elevated serum fibroblast factor-23 (FGF-23) levels, secondary hyperparathyroidism and chronic kidney disease-mineral bone disorder (CKD-MBD). However dissociated hyperphosphatemia and low serum FGF-23 concentrations have been observed in experimentally parathyoridectomized rats. The relationships between serum mineral, hormone, and bone metabolism may be altered in the presence of CKD. The aim of our study was to investigate whether a consistent relationship existed between serum FGF-23 levels, specific serum biochemical markers, and histomorphometric parameters of bone metabolism in a parathyroidectomized CKD animal model.

Results

Sprague Dawley rats were divided into 3 groups: parathyroidectomy (PTX) and CKD (PTX+CKD, 9 rats), CKD without PTX (CKD, 9 rats), and neither PTX nor CKD (sham-operated control, 8 rats); CKD was induced by partial nephrectomy. At 8 weeks after partial nephrectomy, serum biomarkers were measured. Bone histomorphometries of the distal femoral metaphyseal bone were analyzed. The mean serum FGF-23 levels and mean bone formation rate were the highest in the CKD group and the lowest in the PTX+CKD group. Bone volume parameters increased significantly in the PTX+CKD group. Pearson’s correlation revealed that serum FGF-23 levels associated with those of intact parathyroid hormone, phosphate, collagen type I C-telopeptide, and calcium. Univariate linear regression showed that serum FGF-23 values correlated with bone formation rate, bone volume, and osteoid parameters. Stepwise multivariate regression analysis revealed that circulating FGF-23 values were independently associated with bone volume and thickness (β = -0.737; p < 0.001 and β = -0.526; p = 0.006, respectively). Serum parathyroid hormone levels independently correlated with bone formation rate (β = 0.714; p < 0.001) while collagen type I C-telopeptide levels correlated with osteoid parameter.

Conclusion

Serum FGF-23 levels independently correlated with bone volume parameters in rats with experimentally induced CKD.

Safety and tolerability of paricalcitol in patients with chronic kidney disease

INTRODUCTION

Secondary hyperparathyroidism (SHPT) is a complication of chronic kidney disease (CKD). Beyond skeletal complications, uncontrolled SHPT is associated with cardiovascular mortality. Vitamin D receptor activators (VDRAs) are a mainstay of therapy for SHPT; however, use is limited by hypercalcemia, though less so with calcitriol analogs such as paricalcitol and there is emerging experience with oral formulations for non-SHPT indications. The role of VDRAs in the treatment of SHPT becomes a complex question as alternative strategies have developed.

AREAS COVERED

This review summarizes trials that established the safety and efficacy of paricalcitol for SHPT. Comparative experience with paricalcitol as against other VDRAs will be reviewed as will the experience with paricalcitol in non-dialysis CKD and comparative experience with non-VDRA-based therapy.

EXPERT OPINION

VDRA therapy is considered first-line therapy for treatment of SHPT. Paricalcitol has demonstrated superiority to calcitriol with respect to parathyroid hormone suppression and calcium-phosphorus balance. Oral formulations of paricalcitol appear to be similarly effective for SHPT. While there is evidence to suggest adjunctive antiproteinuria benefit with the use of VDRAs, efficacy of these agents to slow the progression of CKD or to reduce cardiovascular risk has not yet been demonstrated.

Long-term treatment with lanthanum carbonate reduces mineral and bone abnormalities in rats with chronic renal failure

Background. Lanthanum carbonate (FOSRENOL^®, Shire Pharmaceuticals) is an effective non-calcium, non-resin phosphate binder for the treatment of hyperphosphataemia in patients with chronic kidney disease (CKD). In this study, we used a rat model of chronic renal failure (CRF) to examine the long-term effects of controlling serum phosphorus with lanthanum carbonate treatment on the biochemical and bone abnormalities associated with CKD–mineral and bone disorder (CKD–MBD).

Methods. Rats were fed a normal diet (normal renal function, NRF), or a diet containing 0.75% adenine for 3 weeks to induce CRF. NRF rats continued to receive normal diet plus vehicle or normal diet supplemented with 2% (w/w) lanthanum carbonate for 22 weeks. CRF rats received a diet containing 0.1% adenine, with or without 2% (w/w) lanthanum carbonate. Blood and urine biochemistry were assessed, and bone histomorphometry was performed at study completion.

Results. Treatment with 0.75% adenine induced severe CRF, as demonstrated by elevated serum creatinine. Hyperphosphataemia, hypocalcaemia, elevated calcium × phosphorus product and secondary hyperparathyroidism were evident in CRF + vehicle animals. Treatment with lanthanum carbonate reduced hyperphosphataemia and secondary hyperparathyroidism in CRF animals (P < 0.05), and had little effect in NRF animals. Bone histomorphometry revealed a severe form of bone disease with fibrosis in CRF + vehicle animals; lanthanum carbonate treatment reduced the severity of the bone abnormalities observed, particularly woven bone formation and fibrosis.

Conclusions. Long-term treatment with lanthanum carbonate reduced the biochemical and bone abnormalities of CKD–MBD in a rat model of CRF.

Bone disease in elderly individuals with CKD

Bone disease can lead to significant morbidity and mortality for those who are afflicted by it, irrespective of etiology. Two very prevalent causes of bone disease that contribute to this are osteoporosis and chronic kidney disease (CKD). The modern era has seen important advances in the understanding and management of these processes, but in elderly patients with CKD it remains a complex issue that has yet to be clearly defined. Changes in mineral metabolism that accompany the loss of renal function result in a spectrum of bone disease that occurs concomitantly with bone loss secondary to aging. As such, the traditional paradigms used to manage bone disease may not be appropriate for these patients. With the aging dialysis population, a better understanding of these 2 processes and their interplay deserves more attention.

The journey from vitamin D-resistant rickets to the regulation of renal phosphate transport

In 1937, Fuller Albright first described two rare genetic disorders: Vitamin D resistant rickets and polyostotic fibrous dysplasia, now respectively known as X-linked hypophosphatemic rickets (XLH) and the McCune-Albright syndrome. Albright carefully characterized and meticulously analyzed one patient, W.M., with vitamin D-resistant rickets. Albright subsequently reported additional carefully performed balance studies on W.M. In this review, which evaluates the journey from the initial description of vitamin D-resistant rickets (XLH) to the regulation of renal phosphate transport, we (1) trace the timeline of important discoveries in unraveling the pathophysiology of XLH, (2) cite the recognized abnormalities in mineral metabolism in XLH, (3) evaluate factors that may affect parathyroid hormone values in XLH, (4) assess the potential interactions between the phosphate-regulating gene with homology to endopeptidase on the X chromosome and fibroblast growth factor 23 (FGF23) and their resultant effects on renal phosphate transport and vitamin D metabolism, (5) analyze the complex interplay between FGF23 and the factors that regulate FGF23, and (6) discuss the genetic and acquired disorders of hypophosphatemia and hyperphosphatemia in which FGF23 plays a role. Although Albright could not measure parathyroid hormone, he concluded on the basis of his studies that showed calcemic resistance to parathyroid extract in W.M. that hyperparathyroidism was present. Using a conceptual approach, we suggest that a defect in the skeletal response to parathyroid hormone contributes to hyperparathyroidism in XLH. Finally, at the end of the review, abnormalities in renal phosphate transport that are sometimes found in patients with polyostotic fibrous dysplasia are discussed.

Effect of kidney transplantation on bone

A broad range of different factors aggravates renal osteodystrophy, which is present in virtually all patients with chronic kidney disease and after successful kidney transplantation. Altered hormonal status, including sex hormones and parathyroid hormone (PTH), a deficit of 1,25(OH)(2) vitamin D(3) (calcitriol), immunosuppressive therapy and post-operative immobilization contribute to a progressive loss of bone density and structure. The decrease of bone mass is particularly prominent during the first 6 months after kidney transplantation and is associated with an increased number of fractures, both compared with the normal population as well as with dialysis patients. At particular risk are patients with a history of diabetes, long duration of haemodialysis and post-menopausal women. To prevent post-transplant bone loss prescription of steroids should be minimized and withdrawn as early as possible. Additional intake of alpha-calcidol [25(OH) vitamin D(3)] or calcitriol, despite normal serum levels, reduces persistent hyperparathyroidism after kidney transplantation, improves intestinal calcium absorption and activates osteoblasts. Inhibition of osteoclasts by biphosphonate therapy seems to effectively reverse bone loss during the early and late course of kidney transplantation. However, as the majority of transplant recipients have a low-turnover bone disease, inhibition of osteoclasts, through which bone turnover is impaired, might further reduce osteoblast activity and promote osteoid synthesis. Most investigations were small-scale studies with 10-100 participants and a follow up of only 12 months. This makes conclusions on the effect of any intervention on the fracture rate impossible. Larger, randomized multicentre studies investigating bone-sparing therapy on hard end points are therefore advocated.

Secondary hyperparathyroidism: Review of the disease and its treatment

BACKGROUND

Most patients with chronic kidney disease (CKD) stage 5 develop secondary hyperparathyroidism (SHPT). SHPT is an adaptive response to CKD and its associated disruptions in the homeostatic control of serum phosphorus, calcium, and vitamin D. The poor control of mineral and parathyroid hormone (PTH) levels characteristic of SHPT is associated with serious clinical consequences.

OBJECTIVE

This review discusses the pathophysiology and consequences of SHPT, as well as the efficacy and limitations of current treatment modalities.

METHODS

Literature searches were conducted using the MEDLINE, EMBASE, and BIOSIS databases. Additional information was obtained from Internet web sites, textbooks, and nephrology congress abstracts.

RESULTS

Patients with uncontrolled SHPT are at higher risk for cardiovascular morbidity and mortality, hospitalization, bone disease, vascular and soft-tissue calcification, and vascular access failure than patients whose mineral and PTH levels are well managed. New National Kidney Foundation Kidney Disease Outcomes Quality Initiative (K/DOQI) targets for calcium, phosphorus, calcium-phosphorus product, and PTH control have recently been published with the aim of improving the management of mineral metabolism in CKD patients. Data from observational studies suggest that the majority of patients currently have PTH and mineral levels outside these target ranges.

CONCLUSIONS

Given the inadequacies of current therapies, novel agents are being developed that may help improve the management of SHPT.

The calcium-sensing receptor: a key factor in the pathogenesis of secondary hyperparathyroidism

Serum calcium levels are regulated by the action of parathyroid hormone (PTH). Major drivers of PTH hypersecretion and parathyroid cell proliferation are the hypocalcemia and hyperphosphatemia that develop in chronic kidney disease patients with secondary hyperparathyroidism (SHPT) as a result of low calcitriol levels and decreased kidney function. Increased PTH production in response to systemic hypocalcemia is mediated by the calcium-sensing receptor (CaR). Furthermore, as SHPT progresses, reduced expression of CaRs and vitamin D receptors (VDRs) in hyperplastic parathyroid glands may limit the ability of calcium and calcitriol to regulate PTH secretion. Current treatment for SHPT includes the administration of vitamin D sterols and phosphate binders. Treatment with vitamin D is initially effective, but efficacy often wanes with further disease progression. The actions of vitamin D sterols are undermined by reduced expression of VDRs in the parathyroid gland. Furthermore, the calcemic and phosphatemic actions of vitamin D mean that it has the potential to exacerbate abnormal mineral metabolism, resulting in the formation of vascular calcifications. Effective new treatments for SHPT that have a positive impact on mineral metabolism are clearly needed. Recent research shows that drugs that selectively target the CaR, calcimimetics, have the potential to meet these requirements.

Regulation of PTH1 receptor expression by uremic ultrafiltrate in UMR 106-01 osteoblast-like cells

BACKGROUND

Homologous down-regulation/desensitization of the parathyroid hormone receptor (PTH1R)/adenylate cyclase system has been demonstrated in uremia, and may contribute to parathyroid hormone (PTH) resistance; however, additional studies have shown that parathyroidectomy fails to normalize the down-regulation of the PTH1R. The present studies were designed to test directly, in vitro, the hypothesis that factors circulating in the uremic environment, other than PTH, decrease the response of osteoblastic cells to PTH.

METHODS

Studies were conducted in confluent cultures of UMR 106-01 osteoblast-like cells. Uremic ultrafiltrate (UUF) was obtained from patients on hemodialysis. Cells were exposed to media containing 50% uremic ultrafiltrate for periods of up to 72 hours. Control cultures were exposed to a buffered salt solution containing a comparable ionic composition to that of the UUF. PTH-stimulated cyclic adenosine monophosphate (cAMP) generation was determined by radioimmunoassay (RIA), PTH binding and PTH1R mRNA levels were determined by radioligand binding and Northern analysis, respectively.

RESULTS

PTH-stimulated cAMP generation from cultures treated with uremic ultrafiltrate for 48 hours was 1385.8 +/- 183.2 pmol/culture/5 minutes, whereas control cultures generated 2389.5 +/- 271 pmol cAMP/culture/5 minutes (P < 0.05). PTH binding was decreased by 30% in cultures incubated with UUF as compared to controls. The decrease in binding induced by UUF was accompanied by a decrease in PTH1R mRNA levels.

CONCLUSION

These findings demonstrate that factors present in UUF decrease PTH-stimulated cAMP generation by a mechanism that involves a decrease in the levels of PTH1R mRNA levels. Thus, the skeletal resistance to PTH in the setting of chronic kidney disease, may be explained, at least in part, by circulating factors other than PTH.

Effect of 2′-phosphophloretin on renal function in chronic renal failure rats

Hyperhosphatemia and secondary hyperparathyroidism are common and severe complications of chronic renal failure. Therapies to reduce serum phosphate have been shown to reduce serum parathyroid hormone (PTH) and slow the progression of renal failure. The effect of the inhibitor of intestinal phosphate absorption, 2′-phosphophloretin (2′-PP), on serum and urine chemistry, renal histology, and cardiac structure in the uremic rat model of renal failure, 5/6 nephrectomy (5/6 NX), was examined. The effect of 2′-PP on serum phosphate, serum PTH, serum total Ca2+, and ionized Ca2+, Ca2+ × Pi product, urine protein, urine osmolality, and creatinine clearance in 5/6 NX rats was examined. Uremic rats in chronic renal failure were gavaged daily with 25 μM 2′-PP. Over the course of a 5-wk experiment, serum chemistry in untreated uremic rats, 2′-PP-treated uremic rats, and age-matched control rats with normal renal function was determined twice a week. Urine creatinine, urine osmolality, urine phosphate, and urine protein were determined once a week from 24-h collections. 2′-PP reduced serum phosphate 40 ± 3% compared with a 17% increase in untreated uremic control rats. 2′-PP did not alter total serum Ca2+. During 5-wk experiments, serum PTH increased 65 ± 25% in untreated uremic rats and decreased 70 ± 7% in uremic rats treated with 25 μM 2′-PP. Creatinine clearance decreased 20% in untreated uremic rats compared with a 100% increase in 2′-PP-treated uremic rats. Urine protein decreased and urine osmolality increased in uremic rats treated with 2′-PP. The mechanism of the effect of 2′-PP on serum phosphate was inhibition of intestinal phosphate absorption. 2-PP inhibited intestinal phosphate absorption 50% without altering dietary protein absorption or intestinal Ca2+ absorption. Over the course of the 5-wk treatment with 2′-PP, uremic animals treated with 2′-PP had a 2–4% weight gain/wk, similar to the weight gain seen in age-matched control rats with normal renal function.

Comparison of peripheral bone and body axis skeleton in a rat model of mild-to-moderate renal failure in the presence of physiological serum levels of calcitropic hormones

The skeleton is characterized by anatomic heterogeneity of metabolic turnover. Site-dependent differences in hormonal effects seem likely. Hyporesponsiveness of osteoclasts to parathyroid hormone (PTH) and probably calcitriol was recently demonstrated in the fifth lumbar vertebra of a rat model with moderate renal failure. We compared histomorphometric findings of the tibial head to these data. Histomorphometric measurements were carried out in sections of the right tibial head of pair-fed male Sprague-Dawley rats. Subtotally nephrectomized (SNx), parathyroidectomized (PTx), rats, which received either solvent or rat PTH(1-34) (100 ng/kg per hour) + calcitriol (5 pmol/kg per hour) via osmotic minipumps were compared with sham-operated controls. Results were compared with data from the fifth lumbar vertebra reported recently. Osteoclast numerical density and osteoclast surface density were lower in the tibial head and the lumbar vertebra of solvent-treated SNxPTx rats than in sham-operated controls (p < 0.05), and could not be returned to normal by the substitution of PTH + calcitriol (p < 0.05). On the other hand, there were differences between interventional effects on the tibial head and on the lumbar vertebra concerning parameters describing osteoblasts and trabecular bone volume. In the tibial head, osteoblast surface density was nearly unchanged in both interventions. Nevertheless, bone volume increased after SNxPTx without substitution of PTH + calcitriol (p < 0.05), and no further changes occurred after hormonal replacement. In contrast, osteoblast surface density in the lumbar vertebra was decreased slightly compared with values in sham-operated rats; a clear but nonsignificant increase occurred after the administration of calcitropic hormones. This was accompanied by unchanged trabecular bone volume after SNxPTx. Hormonal replacement, however, caused an increase in trabecular bone volume (p < 0.05), which represents an anabolic effect, which contrasts with findings from the tibial head. The different interventional effects on the lumbar spine and on peripheral bone, regarding the parameters reflecting the condition of osteoblasts, may be intrinsic to the uremic syndrome itself as well as to dissimilar growth manner, function, and mechanical requirements. The findings substantiate the site dependence of bone surface cell metabolism in renal failure and should be the subject of further study. Corresponding results with regard to bone resorption argue for a bone-site-independent, diminished response of osteoclasts to calcitropic hormones.

Comparison of serum parathyroid hormone and ionized calcium and magnesium concentrations and fractional urinary clearance of calcium and phosphorus in healthy horses and horses with enterocolitis

OBJECTIVE

To evaluate calcium balance and parathyroid gland function in healthy horses and horses with enterocolitis and compare results of an immunochemiluminometric assay (ICMA) with those of an immunoradiometric assay (IRMA) for determination of serum intact parathyroid hormone (PTH) concentrations in horses.

ANIMALS

64 horses with enterocolitis and 62 healthy horses.

PROCEDURES

Blood and urine samples were collected for determination of serum total calcium, ionized calcium (Ca2+) and magnesium (Mg2+), phosphorus, BUN, total protein, creatinine, albumin, and PTH concentrations, venous blood gases, and fractional urinary clearance of calcium (FCa) and phosphorus (FP). Serum concentrations of PTH were measured in 40 horses by use of both the IRMA and ICMA.

RESULTS

Most (48/64; 75%) horses with enterocolitis had decreased serum total calcium, Ca2+, and Mg2+ concentrations and increased phosphorus concentrations, compared with healthy horses. Serum PTH concentration was increased in most (36/51; 70.6%) horses with hypocalcemia. In addition, FCa was significantly decreased and FP significantly increased in horses with enterocolitis, compared with healthy horses. Results of ICMA were in agreement with results of IRMA.

CONCLUSIONS AND CLINICAL RELEVANCE

Enterocolitis in horses is often associated with hypocalcemia; 79.7% of affected horses had ionized hypocalcemia. Because FCa was low, it is unlikely that renal calcium loss was the cause of hypocalcemia. Serum PTH concentrations varied in horses with enterocolitis and concomitant hypocalcemia. However, we believe low PTH concentration in some hypocalcemic horses may be the result of impaired parathyroid gland function.

Down-regulation of human osteoblast PTH/PTHrP receptor mRNA in end-stage renal failure

BACKGROUND

Resistance to the action of parathyroid hormone (PTH) has been demonstrated in end-stage renal failure and is considered to be important in the pathogenesis of secondary hyperparathyroidism. The mechanism of resistance is unknown. However, altered regulation of cellular PTH/PTH-related protein (PTH/PTHrP) receptor (PTH1R) has been assumed to be important.

METHODS

We have used in situ hybridization to examine PTH1R mRNA expression by osteoblasts in human bone and have compared the expression in high- and low-turnover renal bone disease, high-turnover nonrenal bone disease (healing fracture callus and Pagetic bone), and normal bone. Bone biopsies were formalin fixed, ethylenediaminetetraacetic acid decalcified, and paraffin wax embedded. A 1.8 kb PTH1R cDNA probe, labeled with 35S, was used, and the hybridization signal was revealed by autoradiography. The density of signal over osteoblasts was quantitated using a semiautomated Leica image analysis software package.

RESULTS

The mean density of PTH1R mRNA signal over osteoblasts in renal high-turnover bone was only 36% of that found in nonrenal high-turnover bone (P < 0.05) and 51% of that found in normal bone (P < 0.05). Osteoblast PTH1R mRNA signal in adynamic bone from individuals with diabetes mellitus was 28% of normal bone (P < 0.05) and 54% of that found in renal high-turnover bone (P < 0.05).

CONCLUSIONS

These results demonstrate a down-regulation of osteoblast PTH1R mRNA in end-stage renal failure in comparison to normal and high-turnover bone from otherwise healthy individuals, and provide an insight into the mechanisms of "skeletal resistance" to the actions of PTH.

Daily intermittent decreases in serum levels of parathyroid hormone have an anabolic-like action on the bones of uremic rats with low-turnover bone and osteomalacia

The calcium receptor agonist (calcimimetic) compound NPS R-568 causes rapid decreases in circulating levels of parathyroid hormone (PTH) in rats and humans. We hypothesized that daily intermittent decreases in serum PTH levels may have different effects on bone than do chronically sustained decreases. To test this hypothesis, we compared two NPS R-568 dosing regimens in rats with chronic renal insufficiency induced by two intravenous injections of adriamycin. Fourteen weeks after the second adriamycin injection, creatinine clearance was reduced by 52%, PTH levels were elevated approximately 2.5-fold, and serum 25(OH)D3 and 1,25(OH)2D3 levels were reduced substantially. Treatment by daily per os gavage, which decreased PTH levels intermittently, or continuous subcutaneous infusion, which resulted in a sustained suppression of serum PTH levels, then began for 8 weeks. Despite the hyperparathyroidism, the adriamycin-injected rats developed a low-turnover bone lesion with osteomalacia (fourfold increase in osteoid volume in the proximal tibial metaphysis) and osteopenia (67% decrease in cancellous bone volume and an 18% reduction in bone mineral density at the distal femur). Daily administered (but not infused) NPS R-568 significantly increased cancellous bone volume solely by normalizing trabecular thickness, and increased femoral bone mineral density by 14%. These results indicate that daily intermittent, but not sustained, decreases in PTH levels have an "anabolic-like" effect on bones with a low-turnover lesion in this animal model of chronic renal insufficiency.

Cellular mechanisms of renal osteodystrophy

Renal osteodystrophy affects all patients with end-stage renal failure, resulting in significant skeletal and extra-skeletal morbidity. The patterns of disease seen in bone are the result of changes in calcium, phosphate, parathyroid hormone (PTH), and vitamin D metabolism, as well as the effects of uremia. Standard histological techniques, however, give little insight into the altered biological activity or mechanisms of disease at the cellular level. In order to examine the cellular abnormalities in renal bone disease we have performed a series of in situ hybridization studies to examine renal bone cell expression of genes for PTH receptor (PTHR1), transforming growth factor beta (TGF-beta) and insulin growth factor 1 (IGF-I). PTHR1 mRNA was expressed predominantly by osteoblasts, but also by resorbing osteoclasts, suggesting that these cells may be stimulated directly by PTH. Semi-quantitative analysis of gene expression showed down-regulation of PTHR1 mRNA by osteoblasts in renal bone compared with normal, fracture and Pagetic bone. This may be important in the pathogenesis of skeletal resistance seen in end-stage renal failure, altering the "threshold" at which PTH has its effects on bone cells. TGF-beta and IGF-I mRNA expression was also decreased, suggesting that synthesis of these factors, postulated to be mediators of PTH, is also downregulated.

Effect of phosphate on parathyroid hormone secretion in vivo

Alterations in phosphate homeostasis play an important role in the development of secondary hyperparathyroidism in renal failure. Until recently, it was accepted that phosphate retention only increased parathyroid hormone (PTH) secretion through indirect mechanisms affecting calcium regulation and calcitriol synthesis. However, recent in vitro studies have suggested that phosphate may directly affect PTH secretion. Our goal was to determine whether in vivo an intravenous phosphate infusion stimulated PTH secretion in the absence of changes in serum calcium. Three different doses of phosphate were infused intravenously during 120 minutes to increase the serum phosphate concentration in dogs. Sulfate was also infused intravenously as a separate experimental control. A simultaneous calcium clamp was performed to maintain a normal ionized calcium concentration throughout all studies. At the lowest dose of infused phosphate (1.2 mmol/kg), serum phosphate values increased to approximately 3 mM, but PTH values did not increase. At higher doses of infused phosphate (1.6 mmol/kg and 2.4 mmol/kg), the increase in serum phosphate to values of approximately 4 mM and 5 mM, respectively, was associated with increases in PTH, even though the ionized calcium concentration did not change. Increases in PTH were not observed until 30-60 minutes into the study. These increases were not sustained, since by 120 minutes PTH values were not different from baseline or controls despite the maintenance of marked hyperphosphatemia. During the sulfate infusion, serum sulfate values increased by approximately 3-fold, but no change in PTH values were observed. In conclusion, an acute elevation in serum phosphate stimulated PTH secretion in the intact animal, but the magnitude of hyperphosphatemia exceeded the physiologic range. Future studies are needed to determine whether PTH stimulation is more sensitive to phosphate loading in states of chronic phosphate retention. Moreover, the mechanisms responsible for the delay in PTH stimulation and the failure to sustain the increased PTH secretion need further evaluation.

Dynamics of skeletal resistance to parathyroid hormone in the rat: effect of renal failure and dietary phosphorus

Secondary hyperparathyroidism develops in renal failure and is generally ascribed to factors directly affecting parathyroid hormone (PTH) production and/or secretion. These include hypocalcemia, phosphorus retention, and a calcitriol deficiency. However, not often emphasized is that skeletal resistance to PTH is an important factor. Our study evaluated: (1) the relative effects of uremia and dietary phosphorus on the skeletal resistance to PTH; and (2) how, during a PTH infusion, the dynamics of skeletal resistance to PTH were affected by renal failure. Renal failure was surgically induced and, based on serum creatinine, rats were divided into normal, moderate renal failure, and advanced renal failure. In each group, three diets with the same calcium (0.6%) but different phosphorus contents were used: high (1.2%, HPD); moderate (0.6%, MPD); and low (0.2%, LPD) phosphorus. The study diet was given for 14-16 days followed by a 48 h infusion of rat PTH(1-34) (0.11 microg/100 g per hour), a dose five times greater than the normal replacement dose. During the PTH infusion, rats received a calcium-free, low phosphorus (0.2%) diet. In both moderate and advanced renal failure, the PTH level was greatest in the HPD group (p < 0.05) and, despite normal serum calcium values, PTH was greater in the MPD than the LPD group (p < 0.05). Despite phosphorus restriction and normal serum calcium and calcitriol levels in the azotemic LPD groups, the PTH level was greater (p < 0.05) in the LPD group with advanced rather than moderate renal failure. During PTH infusion, the increase in serum calcium was progressively less (p < 0.05) in all groups as renal function declined. Furthermore, despite normal and similar serum phosphorus values at the end of PTH infusion, the serum calcium concentration was less (p < 0.05) in the HPD group than the other two groups and similar in the LPD and MPD groups.

IN CONCLUSION

(1) uremia and phosphorus each had separate and major effects on skeletal resistance to PTH; (2) skeletal resistance to PTH was an important cause of secondary hyperparathyroidism, even in moderate renal failure; (3) during PTH infusion, the dynamics of skeletal resistance to PTH changed because all groups received a low phosphorus diet, and the adaptation to a new steady state was delayed by the degree of renal failure and the previous dietary phosphorus burden; and (4) normal serum phosphorus may not be indicative of body phosphorus stores during states of disequilibrium.

Phosphate depletion in the rat: effect of bisphosphonates and the calcemic response to PTH

BACKGROUND

The removal of phosphate from the diet of the growing rat rapidly produces hypercalcemia, hypophosphatemia, hypercalciuria, and hypophosphaturia. Increased calcium efflux from bone has been shown to be the important cause of the hypercalcemia and hypercalciuria. It has been proposed that the increased calcium efflux from bone is osteoclast mediated. Because bisphosphonates have been shown to inhibit osteoclast-mediated bone resorption, this study was performed to determine whether bisphosphonate-induced inhibition of osteoclast function changed the biochemical and bone effects induced by phosphate depletion.

METHODS

Four groups of pair-fed rats were studied: (a) low-phosphate diet (LPD; phosphate less than 0.05%), (b) LPD plus the administration of the bisphosphonate Pamidronate (APD; LPD + APD), (c) normal diet (ND, 0.6% phosphate), and (d) ND + APD. All diets contained 0.6% calcium. A high dose of APD was administered subcutaneously (0.8 mg/kg) two days before the start of the study diet and on days 2, 6, and 9 during the 11 days of the study diet. On day 10, a 24-hour urine was collected, and on day 11, rats were either sacrificed or received an additional APD dose before a 48-hour parathyroid hormone (PTH) infusion (0.066 microgram/100 g/hr) via a subcutaneously implanted miniosmotic pump.

RESULTS

Serum and urinary calcium were greater in the LPD and LPD + APD groups than in the ND and ND + APD groups [serum, 11.12 +/- 0.34 and 11.57 +/- 0.45 vs. 9.49 +/- 0.17 and 9.48 +/- 0.15 mg/dl (mean +/- SE), P < 0.05; and urine, 8.78 +/- 2.74 and 16.30 +/- 4.68 vs. 0.32 +/- 0.09 and 0.67 +/- 0.28 mg/24 hr, P < 0.05]. Serum PTH and serum and urinary phosphorus were less in the LPD and LPD + APD than in the ND and ND + APD groups (P < 0.05). The calcemic response to PTH was less (P < 0.05) in the LPD and LPD + APD groups than in the ND group and was less (P = 0.05) in the LPD + APD than in the ND + APD group. Bone histology showed that phosphate depletion increased the osteoblast and osteoclast surface, and treatment with APD reduced the osteoblast surface (LPD vs. LPD + APD, 38 +/- 4 vs. 4 +/- 2%, P < 0.05, and ND vs. ND + APD, 20 +/- 2 vs. 5 +/- 2%, P < 0.05) and markedly altered osteoclast morphology by inducing cytoplasmic vacuoles.

CONCLUSIONS

(a) Phosphate depletion induced hypercalcemia and hypercalciuria that were not reduced by APD administration. (b) The calcemic response to PTH was reduced in phosphate-depleted rats and was unaffected by APD administration in normal and phosphate-depleted rats, and (c) APD administration markedly changed bone histology without affecting the biochemical changes induced by phosphate depletion.

Abnormal skeletal response to parathyroid hormone and the expression of its receptor in chronic uremia

Chronic renal failure is characterized by a resistance to the hypercalcemic action of parathyroid hormone (PTH). This resistance probably involves several mechanisms, including a disturbance of vitamin D metabolism, a desensitization of the skeleton by high PTH levels, hyperphosphatemia, uremic toxins, and acidosis. We have explored the possibility that a downregulation of the recently cloned PTH/PTHrp receptor might also be involved. We found a marked decrease in the expression of the receptor mRNA in the kidney and the bone of uremic rats; other authors have found a decrease in the heart and the liver. The reduced expression in the kidney was accompanied by a diminished stimulability of renal adenylate cyclase activity, suggestive of a functional depression of the hormonal response in this target tissue. It is probable that the downregulation of the PTH/PTHrp receptor plays an important role in the skeletal resistance to the calcemic effect of PTII in chronic renal failure.

Secondary hyperparathyroidism in renal failure: the trade-off hypothesis revisited

Our understanding of the mechanism responsible for secondary hyperparathyroidism (HPTH) has advanced significantly since the "trade-off" hypothesis was formulated. It appears that in early renal failure a deficit of calcitriol synthesis is an important factor. However, additional factors, such as a defect of the vitamin D receptor or the newly cloned calcium sensor receptor (BoPCaR1), may be present in the parathyroid cells. As renal failure progresses, the lack of calcitriol becomes more pronounced, inducing HPTH. With advanced chronic renal failure, hyperphosphatemia is an additional important factor in worsening HPTH. In addition, resistance of the parathyroids to calcitriol due to a reduced density of calcitriol receptors also may contribute to HPTH. Finally, uremia per se not only may cause a receptor abnormality in the parathyroid but at the level of the bone it may aggravate the impaired calcemic response to PTH. In conclusion, after reviewing the "trade-off" hypothesis, although some of the original concepts may have been simplistic, most of the factors postulated 30 years ago are still operative in the pathogenesis of secondary HPTH in renal failure.

Neuropsychiatric consequences of renal failure

Renal failure is associated with many subtle, and several distinct, alterations in neuropsychiatric function. This review describes the clinical findings, the treatments, and the known pathophysiology of the neuropsychiatric effects of renal failure.

Direct in vivo assessment of parathyroid hormone-calcium relationship curve in renal patients

Secondary hyperparathyroidism (SHP) is a well documented finding even in the early stages of chronic renal failure (CRF). A sigmoidal relationship, fitting a four parameter model, links PTH secretion rate and calcium concentration changes. To our knowledge, PTH secretory parameters have only been studied in uremic patients who are in dialysis treatment. As a result of these studies, a possible role for derangement in setpoint values (that is, the serum calcium concentration corresponding to the mid-range value on the sigmoidal curve) has been suggested in the pathogenesis of SHP in CRF. Our study was undertaken to gain insight into the calcium-PTH relationship curve in the first course of CRF and to assess whether a change in any of the secretory parameters is related to the beginning of SHP. We studied 27 male renal patients with a variable degree of renal function (creatinine clearance 12 to 164 ml/min) and 9 control subjects. In all patients and controls the following parameters were evaluated: (1) basal 1,25(OH)2 vitamin D, 25(OH)vitamin D, calcitonin (CT), intact PTH; (2) GFR by Cr51EDTA clearance; (3) the sigmoidal PTH-ionized calcium relation curve, by means of a hypocalcemic stimulating test (Na2-EDTA 37 mg/kg body weight/2 hr) and a hypercalcemic test (Ca gluconate giving 8 mg/kg of body weight/2 hr of Ca element), performed on two consecutive days.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparison of two parathyroid hormone assays for the rat: the new immunoradiometric and the older competitive binding assay

A competitive binding assay for parathyroid hormone (PTH INS) has been used since 1986 to measure PTH in rats. During the past year an immunoradiometric assay for the measurement of PTH (PTH IRMA) in the rat was developed. The purpose of the present study was to compare results obtained with the PTH INS and IRMA and to provide a framework for comparison for investigators who have used the PTH INS in previous studies. A total of 99 rats were studied; 27 rats had normal renal function, and 72 rats had surgically induced renal failure. In the azotemic rats, the magnitude of hyperparathyroidism was varied by changing the calcium and phosphorus composition of the diet. The correlation between the two PTH assays in the 99 rats was r = 0.98, p < 0.001. For the 27 rats with normal renal function, the correlation even within the narrow range of normal PTH values was significant, r = 0.71, p < 0.001. In the 72 azotemic rats, in which the highest INS PTH value was approximately 17 times normal, the correlation between the two PTH assays was r = 0.98, p < 0.001. The PTH IRMA provides distinct advantages, such as extended standard range, shortened incubation time, increased sensitivity, and technical simplicity, but our results indicate that the PTH INS provided an accurate measurement of PTH. Furthermore, our results should provide investigators who have used the PTH INS in previous studies with a framework for comparison with studies in which the PTH IRMA was used.

The calcemic response to PTH in the rat: effect of elevated PTH levels and uremia

Secondary hyperparathyroidism (2 degrees HPT) is a consistent finding in renal failure. A decreased calcemic response (CR) to parathyroid hormone (PTH) contributes to the development of 2 degrees HPT. Since parathyroidectomy (PTX) corrects the decreased CR to PTH in azotemic animals, down-regulation of PTH receptors induced by an elevation of PTH has been advanced as an important factor in the development of 2 degrees HPT. The goal of the study was to determine in azotemic rats whether a progressive reduction of PTH improves the CR to PTH and whether the maintenance of normal PTH levels corrects the CR to PTH. Seven groups of pair-fed rats were studied. Three groups of rats had normal renal function (NRF groups) and received either a high phosphorus (HPD-NRF), a moderate phosphorus (MPD-NRF), or a low phosphorus (LPD-NRF) diet. Three azotemic (NX) groups received similar diets (HPD-NX, MPD-NX and LPD-NX groups) in order to vary the magnitude of 2 degrees HPT. A PTX was performed in a fourth azotemic group (PTX-NX) to induce the complete absence of PTH. After 14 to 16 days on the maintenance diets, the CR to PTH was determined with a 48 hour infusion of 1-34 rat PTH.(ABSTRACT TRUNCATED AT 250 WORDS)

Factors in the development of secondary hyperparathyroidism during graded renal failure in the rat

Secondary hyperparathyroidism (2 degree HPT) develops as a result of renal failure. Hypocalcemia, phosphorus retention, calcitriol deficiency and skeletal resistance to the calcemic action of parathyroid hormone (PTH) are closely interrelated pathogenic factors important for the development of 2 degrees HPT in renal failure. Since previous studies have mainly focused on advanced renal failure, only limited data are available in early renal failure. The goal of the present study was to evaluate how alterations in the dietary calcium and phosphorus composition affect the factors known to contribute to the genesis of 2 degrees HPT in early and more advanced renal failure. To achieve this goal, graded differences in renal function were surgically induced in 453 rats while the dietary content of calcium and phosphorus was varied. Three different diets were used: (1) a high phosphorus diet (HPD), to induce phosphorus retention and stimulate 2 degrees HPT; (2) a high calcium diet (HCaD), to inhibit calcitriol synthesis; and (3) a moderate calcium-moderate phosphorus diet (MCaPD), to separate the effects of high dietary phosphorus and calcium. Based on the serum creatinine (SCr) concentration rats were assigned to one of four different groups: (1) normal renal function (SCr < or = 0.3 mg/dl); (2) mild renal failure (SCr 0.4 to 0.6 mg/dl); (3) moderate renal failure (SCr 0.7 to 0.8 mg/dl); or (4) advanced renal failure (SCr > or = 0.9 mg/dl). As the severity of renal failure increased, progressive 2 degrees HPT developed in each of the dietary groups.(ABSTRACT TRUNCATED AT 250 WORDS)

Parathyroid gland function in chronic renal failure

The concept that the PTH-calcium curve is representative of parathyroid function has been discussed. Comparisons of parathyroid function have been made between normal humans and hemodialysis patients and also between hemodialysis patients with different forms of renal osteodystrophy. From these comparisons, it is apparent that the magnitude of HPT is much greater in patients with renal failure than in normal humans, and as represented by the ratio of basal to maximal PTH, the parathyroid gland appears to be stimulated at basal serum calcium levels in hemodialysis patients. Similarly, based on an analysis of the PTH-calcium curve, we were able to determine that several differences in parathyroid function were present in hemodialysis patients with different forms of renal osteodystrophy. As compared to hemodialysis patients with LTAABD and aplastic bone disease, patients with osteitis fibrosa have a greater magnitude of hyperparathyroidism, a greater sensitivity of the parathyroid cell (slope), a higher set point of calcium, and greater PTH stimulation at basal serum calcium (ratio of basal to maximal PTH). Calcitriol treatment of hemodialysis patients with osteitis fibrosa resulted in a significant decrease in PTH throughout the PTH-calcium curve and also reduced the sensitivity (slope) of the PTH-calcium curve. The concept of hysteresis has been discussed as well as the role that the ambient basal serum calcium concentration may have on the determination of the PTH-calcium curve. Finally, the effect that successful renal transplantation has on HPT has been examined. In conclusion, we believe that the PTH-calcium curve provides a reliable assessment of parathyroid function, and as such, has considerable application for the study of parathyroid disorders in the clinical setting.

A model of reversible uremia employing isogenic kidney transplantation in the rat. Reversibility of secondary hyperparathyroidism

Kidney transplanted patients with normalized kidney function may still exhibit a variety of problems such as bone problems, vascularly problems, and hormonal dysfunctions. A part of the symptoms may be persisting uremic symptoms, secondary to the pretransplanted period of chronic uremia. An experimental rat model, designed to the study of the reversibility of the chronic uremic implications is therefore described. A stable, severe chronic uremia was induced by 5/6 nephrectomy to inbred Lewis rats. Ten weeks later uremia was reverted by a successful isogenic rat kidney transplantation. During the period of chronic uremia the p-urea was elevated to an average of 21.8 +/- 0.9 mmol/l and p-creatinine to 105.7 +/- 5.7 microM/l. The isogenic kidney transplantation resulted in reestablishment of normal kidney function with an average level of p-urea of 7.6 +/- 0.2 mmol/l and p-creatinine 42.5 +/- 1.9 microM/l perfectly corresponding to the sham-operated rats, i.e. one-kidney rats. Reversibility of the secondary hyperparathyroidism due to chronic uremia was investigated in the model. In rats with chronic renal failure PTH increased from 52 +/- 4.9 pg/ml to 152 +/- 12.2 pg/ml and was normalized after transplantation. It is therefore concluded that the present described technique of introducing long term uremia followed up by a successful kidney transplantation in the rat may be a useful model to study the reversibility of different uremic manifestations.

Interrelationship between parathyroid hormone and insulin: effects on DNA synthesis in UMR-106-01 cells

UMR-106-01 osteoblast-like cells respond to high concentrations of parathyroid hormone (PTH) in vitro by decreasing thymidine incorporation, a marker of DNA synthesis and cell proliferation. This response is different from in vivo conditions, such as primary and secondary hyperparathyroidism, in which high PTH levels are associated with an increased number of osteoblasts. When the response of UMR-106-01 cells to PTH is evaluated in vitro, however, these cells are exposed to only a single hormone. The present study was designed to evaluate the combined effects of two hormones, PTH and insulin, on the DNA synthesis of UMR-106-01 cells. PTH is known to decrease and insulin to increase thymidine incorporation by UMR-106-01 cells. To examine the interaction of these hormones, acute studies, defined as a 24 h exposure to hormone, and chronic studies, defined as a 7 day exposure to hormone, were performed. Both acute and chronic exposure to 10(-9) M PTH decreased thymidine incorporation by UMR-106-01 cells, with suppression ranging from 27 to 81% (P < 0.05). Both acute and chronic exposure to 10(-8) M insulin (INS) increased thymidine incorporation by UMR-106-01 cells; this ranged from 26 to 58% (P < 0.05). However, chronic exposure to 10(-9) M PTH followed by an acute exposure to 10(-8) M INS resulted in a 710% increase in thymidine incorporation (P < 0.01). Reversing the sequence by chronically exposing UMR-106-01 cells to 10(-8) M INS followed by acute exposure to 10(-9) M PTH resulted in a 53% decrease in thymidine incorporation (P < 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)

Phosphate homeostasis, 1,25-dihydroxyvitamm D(3), and hyperparathyroidism in early chronic renal failure

In early chronic renal failure, low plasma levels of calcitriol (1,25[OH](2)D(3)) do not seem to be merely the consequence of a reduced mass of functional nephrons. Indeed, this alteration can be considered as a compensatory mechanism, as analyzed according to a new concept of inorganic phosphate (P(i)) homeostasis that integrates both 1,25(OH)(2)D(3) production and renal P(i) reabsorption as essential regulating elements. Accordingly, the observed reduction in the renal production of 1,25(OH)(2)D(3) that occurs concomitantly with a decrease in tubular P(i) reabsorptive capacity (TmP(i)/GFR) may well represent a secondary adaptive response to a primary alteration in P(i) homeostasis. This crucial alteration in P(i) homeostasis would consist of an overload of a putative regulated intracellular P(i) pool, the localization of which remains to be determined. The observed hypophosphatemia, hypocalcemia, and PTH hypersecretion would represent alterations secondary to a low TmP(i)/GFR and to reduced 1,25(OH)(2)D(3) production. According to this pathophysiologic sequence, 1,25(OH)(2)D(3), rather than PTH as proposed in a former theory, would be "traded off" to preserve P(i) homeostasis in early chronic renal failure. Both theories predict that dietary P(i) restriction represents a logical preventive therapy at least until the nature of the primary defect in P(i) homeostasis is understood. However, assuming that low 1,25(OH)(2)D(3) levels in early chronic renal failure represent a compensatory phenomenon, this new theory suggests that calcitriol should be only administered at a later stage of the disease, when the production of 1,25(OH)(2)D(3) becomes inappropriately low to maintain mineral homeostasis.