Pathogenesis Of Renal Osteodystrophy Research Articles

#911 A mice model of SHPT with bone abnormalities in CKD and potential functional role of sphingolipid in renal osteodystrophy

Abstract Background and Aims Renal osteodystrophy (ROD) is the skeletal disease of chronic kidney disease associated mineral and bone disorder (CKD-MBD). ROD is characterized by abnormal bone mineralization and impaired bone remodeling, leading to increased risk of fractures and mortality in patients with CKD. To date, the pathology of ROD remains poorly understood due to the lack of a suitable animal model. Hence, we successfully established a stable mouse model of ROD using an optimized adenine diet and explored the possible signaling based on RNA-seq expression analyses. Method Blood biochemical analysis, micro-computed tomography (micro-CT) and bone histomorphometry were performed to analyze the skeletal characteristics. RNA sequencing (RNA-seq) was used to investigate the mechanisms involved in ROD. The functions of differentially expressed genes (DEGs) were evaluated by Gene Ontology (GO) analyses, Kyoto Encyclopedia of Genes and Genomes (KEGG) analyses and Gene Set Enrichment Analyses (GSEA). DEGs were validated by quantitative real-time quantitative reverse transcription polymerase chain reaction (qRT-PCR). Results The mice with ROD induced by optimized adenine diet showed severe abnormalities in serum creatinine (Scr) and blood urea nitrogen (BUN) along with marked hyperparathyroidism and hyperphosphatemia. The bone mineral density (BMD) of femurs was significantly lower in the ROD mice than that in the control (CTL) mice. The trabecular and cortical bone parameters of femurs significantly showed bone loss and severe cortical porosity. ROD mice showed high bone turnover with increased osteoid, eroded, osteoblast, and osteoclast perimeters as well as increased bone formation rate and mineral apposition rate. Transcriptomic profiling identified 1286 genes were upregulated in the femurs of ROD mice compared to the CTL mice and 333 genes that were downregulated. GO, KEGG and GSEA pathway analyses indicated that these genes were highly enriched in functions related to lipid metabolism pathway, sphingolipid signaling pathway, among others. The differential expression of alkaline ceramidase 1(Acer1), ceramide synthase 4 (Cers4) sphingomyelin phosphodiesterase 3 (Smpd3), sphingosine-1-phosphate phosphatase 2 (Sgpp2) in skeletal tissue and serum of CKD patients were validated by qRT-PCR. Since sphingolipid pathways have been recently implicated in bone metabolism, these genes are potential target genes in the settings of ROD. Conclusion In conclusion, our findings demonstrated that the CKD mice with bone abnormalities induced by optimized adenine diet may serve as a useful model for skeletal analysis in ROD. Based on the RNA-seq, we identified that sphingolipid might play a crucial role in the pathogenesis of ROD and provided new therapeutic targets for future study.

Gut microbiome, parathyroid hormone, and bone.

Microorganisms in the gut (the 'microbiome') and the metabolites they produce (the 'metabolome') regulate bone mass through interactions between parathyroid hormone (PTH), the immune system, and bone. This review summarizes these data and details how this physiology may relate to CKD-mediated bone disease. The actions of PTH on bone require microbial metabolite activation of immune cells. Butyrate is necessary for CD4+ T-cell differentiation, T-reg cell expansion and CD8+ T-cell secretion of the bone-forming factor Wnt10b ligand. By contrast, mice colonized with segmented filamentous bacteria exhibit an expansion of gut Th17 cells and continuous PTH infusion increases the migration of Th17 cells to the bone marrow, contributing to bone resorption. In the context of CKD, a modified diet, frequent antibiotic therapy, altered intestinal mobility, and exposure to multiple medications together contribute to dysbiosis; the implications for an altered microbiome and metabolome on the pathogenesis of renal osteodystrophy and its treatment have not been explored. As dysregulated interactions between PTH and bone ('skeletal resistance') characterize CKD, the time is ripe for detailed, mechanistic studies into the role that gut metabolites may play in the pathogenesis of CKD-mediated bone disease.

Transcriptomics: a Solution for Renal Osteodystrophy?

The molecular mechanisms of the bone disease associated with chronic kidney disease (CKD), called renal osteodystrophy (ROD), are poorly understood. New transcriptomics technologies may provide clinically relevant insights into the pathogenesis of ROD. This review summarizes current progress and limitations in the study and treatment of ROD, and in transcriptomics analyses of skeletal tissues. ROD is characterized by poor bone quality and strength leading to increased risk of fracture. Recent studies indicate permanent alterations in bone cell populations during ROD. Single-cell transcriptomics analyses, successful at identifying specialized cell subpopulations in bone, have not yet been performed in ROD. ROD is a widespread poorly understood bone disease with limited treatment options. Transcriptomics analyses of bone are needed to identify the bone cell subtypes and their role in the pathogenesis of ROD, and to develop adequate diagnosis and treatment strategies.

Impaired osteocyte maturation in the pathogenesis of renal osteodystrophy

Pediatric renal osteodystrophy is characterized by skeletal mineralization defects, but the role of osteoblast and osteocyte maturation in the pathogenesis of these defects is unknown. We evaluated markers of osteocyte maturation and programmed cell death in iliac crest biopsy samples from pediatric dialysis patients and healthy controls. We evaluated the relationship between numbers of fibroblast growth factor 23 (FGF23)-expressing osteocytes and histomorphometric parameters of skeletal mineralization. We confirmed that chronic kidney disease (CKD) causes intrinsic changes in bone cell maturation using an invitro model of primary osteoblasts from patients with CKD and healthy controls. FGF23 co-localized with the early osteocyte marker E11/gp38, suggesting that FGF23 is a marker of early osteocyte maturation. Increased numbers of early osteocytes and decreased osteocyte apoptosis characterized CKD bone. Numbers of FGF23-expressing osteocytes were highest in patients with preserved skeletal mineralization indices, and packets of matrix surrounding FGF23-expressing osteocytes appeared to have entered secondary mineralization. Primary osteoblasts from patients with CKD retained impaired maturation and mineralization characteristics invitro. Addition of FGF23 did not affect primary osteoblast mineralization. Thus, CKD is associated with intrinsic changes in osteoblast and osteocyte maturation, and FGF23 appears to mark a relatively early stage in osteocyte maturation. Improved control of renal osteodystrophy and FGF23 excess will require further investigation into the pathogenesis of CKD-mediated osteoblast and osteocyte maturation failure.

Osteocyte dysfunction and renal osteodystrophy: not just calcium and phosphorus anymore

In an important new cross-sectional analysis in this issue, Graciolli and colleagues present bone data from 148 adult patients across the spectrum of chronic kidney disease that confirm that disrupted osteocyte function and abnormal bone histology characterize all stages of chronic kidney disease and suggest that osteocytic Wnt signaling and osteocyte maturation may play a role in the pathogenesis of renal osteodystrophy. These concepts may alter how the skeletal, cardiovascular, and infectious complications of chronic kidney disease are managed.

Bone biopsy in renal osteodystrophy

The pathogenesis and optimal therapy of renal bone disease remains poorly understood in chronic kidney disease (CKD) and dialysis patients. Bone biopsy is thus far the only window into cellular and molecular events in bone. This review will focus on recent insights into the pathophysiology of renal bone disease, as highlighted by bone biopsy, and discuss implications for treatment. Abnormalities in bone physiology start very early in children and adults with CKD, when most clinically measurable mineral metabolism parameters are normal. In addition, racial differences, known to exist in serum markers such as parathyroid hormone, also appear prominent in the bone, suggesting that clinical treatment guidelines may not address the needs of all patient populations. The effects of treatments for secondary hyperparathyroidism on bone may be unexpected. With the help of bone biopsy studies, molecular insights into the pathogenesis of renal osteodystrophy are beginning to emerge. Current therapies may have unexpected effects on bone physiology.

Repression of osteocyte Wnt/β-catenin signaling is an early event in the progression of renal osteodystrophy

Chronic kidney disease-mineral bone disorder (CKD-MBD) is defined by abnormalities in mineral and hormone metabolism, bone histomorphometric changes, and/or the presence of soft-tissue calcification. Emerging evidence suggests that features of CKD-MBD may occur early in disease progression and are associated with changes in osteocyte function. To identify early changes in bone, we utilized the jck mouse, a genetic model of polycystic kidney disease that exhibits progressive renal disease. At 6 weeks of age, jck mice have normal renal function and no evidence of bone disease but exhibit continual decline in renal function and death by 20 weeks of age, when approximately 40% to 60% of them have vascular calcification. Temporal changes in serum parameters were identified in jck relative to wild-type mice from 6 through 18 weeks of age and were subsequently shown to largely mirror serum changes commonly associated with clinical CKD-MBD. Bone histomorphometry revealed progressive changes associated with increased osteoclast activity and elevated bone formation relative to wild-type mice. To capture the early molecular and cellular events in the progression of CKD-MBD we examined cell-specific pathways associated with bone remodeling at the protein and/or gene expression level. Importantly, a steady increase in the number of cells expressing phosphor-Ser33/37-β-catenin was observed both in mouse and human bones. Overall repression of Wnt/β-catenin signaling within osteocytes occurred in conjunction with increased expression of Wnt antagonists (SOST and sFRP4) and genes associated with osteoclast activity, including receptor activator of NF-κB ligand (RANKL). The resulting increase in the RANKL/osteoprotegerin (OPG) ratio correlated with increased osteoclast activity. In late-stage disease, an apparent repression of genes associated with osteoblast function was observed. These data confirm that jck mice develop progressive biochemical changes in CKD-MBD and suggest that repression of the Wnt/β-catenin pathway is involved in the pathogenesis of renal osteodystrophy.

Fibroblast growth factor 23 and bone metabolism in children with chronic kidney disease

Fibroblast growth factor 23 (FGF23) is a circulating protein that regulates the renal reabsorption of phosphate and also inhibits 1-alpha-hydroxylase production. In adults FGF23 is increased in chronic kidney disease (CKD) and is an important prognostic factor for cardiovascular morbidity. In order to gain insight into the role of FGF23 and other biochemical variables of bone metabolism in children we studied 69 patients at different stages of CKD. FGF23 was found to be significantly elevated in stage 3 compared with stages 1 and 2 of CKD, preceding significant hyperphosphatemia in stage 4 disease. The highest levels of FGF23 were found in stage 5 compared with stages 1 and 2 CKD. The levels of FGF23 positively correlated with parathyroid hormone and phosphate concentrations and negatively with 1,25-dihydroxyvitamin D, the estimated glomerular filtration rate, and tubular phosphate reabsorption. Using multivariate analysis, hyperphosphatemia and low estimated glomerular filtration rate remained the most significant factors. Thus we found that FGF23 likely has an important role in pediatric calcium and phosphate homeostasis, and in vitamin D metabolism, even at an early stage of CKD. Further studies are needed to clarify the role of FGF23 on the pathogenesis of renal osteodystrophy and its impact on cardiovascular morbidity in pediatric patients with CKD.

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

AbstractNew 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.

New discoveries in the pathogenesis of renal osteodystrophy

New discoveries in the pathogenesis of renal osteodystrophy

Minimizing Bone Abnormalities in Children with Renal Failure

Renal osteodystrophy (ROD), a metabolic bone disease accompanying chronic renal failure (CRF), is a major clinical problem in pediatric nephrology. Growing and rapidly remodeling skeletal systems are particularly susceptible to the metabolic and endocrine disturbances in CRF. The pathogenesis of ROD is complex and multifactorial. Hypocalcemia, phosphate retention, and low levels of 1,25 dihydroxyvitamin D(3) related to CRF result in disturbances of bone metabolism and ROD. Delayed diagnosis and treatment of bone lesions might result in severe disability. Based on microscopic findings, renal bone disease is classified into two main categories: high- and low-turnover bone disease. High-turnover bone disease is associated with moderate and severe hyperparathyroidism. Low-turnover bone disease includes osteomalacia and adynamic bone disease. The treatment of ROD involves controlling serum calcium and phosphate levels, and preventing parathyroid gland hyperplasia and extraskeletal calcifications. Serum calcium and phosphorus levels should be kept within the normal range. The calcium-phosphorus product has to be <5 mmol(2)/L(2) (60 mg(2)/dL(2)). Parathyroid hormone (PTH) levels in children with CRF should be within the normal range, but in children with end-stage renal disease PTH levels should be two to three times the upper limit of the normal range. Drug treatment includes intestinal phosphate binding agents and active vitamin D metabolites. Phosphate binders should be administered with each meal. Calcium carbonate is the most widely used intestinal phosphate binder. In children with hypercalcemic episodes, sevelamer, a synthetic phosphate binder, should be introduced. In children with CRF, ergocalciferol (vitamin D(2)), colecalciferol (vitamin D(3)), and calcifediol (25-hydroxyvitamin D(3)) should be used as vitamin D analogs. In children undergoing dialysis, active vitamin D metabolites alfacalcidol (1alpha-hydroxy-vitamin D(3)) and calcitriol (1,25 dihydroxyvitamin D(3)) are applied. In recent years, a number of new drugs have emerged that hold promise for a more effective treatment of bone lesions in CRF. This review describes the current approach to the diagnosis and treament of ROD.

Diagnosis, assessment, and treatment of bone turnover abnormalities in renal osteodystrophy

HE ABNORMALITIES of the skeleton in chronic kidney disease (CKD), collectively known as renal osteodystrophy, are an important cause of morbidity and decreased quality of life. In the management of patients with kidney disease, it is necessary to have a rational approach to the diagnosis and assessment of renal osteodystrophy in order to devise a treatment plan that hopefully will lead to an improved outcome. In the past, the term renal osteodystrophy was mainly equated only with abnormalities of bone turnover, but as described in the article by Cunningham and Sprague 1 in this same issue, renal osteodystrophy is a complex disorder of compromised bone strength in CKD patients. While osteoporosis is a term used to describe fragile bones prone to fracture in the general population and is most often assessed by dual x-ray absorptiometry (DEXA), renal osteodystrophy should be the principal term to describe fragile bones prone to fracture and other morbidities in CKD. Renal osteodystrophy is a function of bone turnover (assessed by bone biopsy), bone density (assessed by DEXA or quantitative CT [qCT]), and bone architecture, but the principal determinant of bone fragility in CKD is abnormal bone turnover. However, diagnosing and treating bone turnover abnormalities remains challenging. Our discussion group met to assess the current state of knowledge, understand the basis of our current therapy, and identify the information that needs to be gathered to improve the therapy of bone turnover and thereby improve the disorder of renal osteodystrophy. A number of important questions, listed in Table 1, were considered.

Special aspects of renal osteodystrophy in children

Renal osteodystrophy represents a spectrum of skeletal lesions that range from high-turnover to low-turnover bone disease. Similar factors are involved in the pathogenesis of renal osteodystrophy in adult and pediatric patients with chronic kidney disease (CKD). However, growth retardation and the development of bone deformities are specific complications that occurred in pediatric patients with CKD. Metabolic acidosis, renal osteodystrophy, malnutrition, and disturbances in the insulin growth factor (IGF)/growth hormone (GH) are among the main factors involved and they are discussed briefly in this article. In addition to disturbances in bone remodeling, longitudinal bone growth occurs at the growth plate cartilage by endochondral ossification. Although young rats with experimental CKD have growth retardation, the characteristics of the growth plate are markedly different between animals with severe secondary hyperparathyroidism and those with calcium-induced adynamic osteodystrophy. These disturbances may suggest potential molecular mechanisms by which endochondral bone formation may be altered in renal failure, consequently leading to growth retardation.

Serum osteoprotegerin and renal osteodystrophy.

Numerous growth factors and cytokines are known to modulate bone turnover. An important, recently discovered complex involved in osteoclastogenesis is the osteoprotegerin/osteoprotegerin-ligand (OPG/OPGL) cytokine complex, which is produced by osteoblasts. Many factors, including parathyroid hormone (PTH), appear to affect bone turnover through this pathway. In this disorder, the role of the OPG/OPGL system in the pathogenesis of renal osteodystrophy, a disease with either low or high bone turnover, has not been investigated so far. Thirty-nine chronic haemodialysis patients had bone biopsies, including histomorphometric and histodynamic examinations. In addition, the following serum biochemistry parameters were measured: serum OPG, intact PTH, PTH 1-84, total PTH, osteocalcin, total and bone alkaline phosphatases, 25-hydroxycholecalciferol and 1,25-dihydroxycholecalciferol. On average, serum OPG levels were above the normal range. They were lower in adynamic bone disease (ABD) patients, than in patients with predominant hyperparathyroidism (HP) or mixed osteodystrophy (MO). Significant negative correlations were found between serum OPG and PTH levels, and between serum OPG and parameters of bone resorption (ES/BS) and bone formation (ObS/BS and BFR/BS) in HP and MO patients with PTH values < or =1000 pg/ml. For intact PTH levels < or =300 pg/ml, serum OPG was significantly lower in the group with ABD than in those with HP or MO (P<0.05). In renal osteodystrophy the OPG/OPGL system is involved in the regulation of bone turnover induced by PTH. The determination of serum OPG levels could be of use in the diagnosis of low turnover bone disease, at least in association with PTH levels < or =300 pg/ml.

Molecular mechanisms of secondary hyperparathyroidism.

Secondary hyperparathyroidism is a frequent complication of chronic renal failure (CRF) and a major factor in the pathogenesis of renal osteodystrophy. A high serum phosphate, decreased levels of serum 1,25(OH) 2 D 3 and the subsequently low serum calcium are the major metabolic abnormalities in CRF, which lead to the secondary hyperparathyroidism. At the level of parathyroid hormone (PTH) secretion there is insensi- tivity to the ambient serum calcium. PTH mRNA levels are increased by a post-transcriptional mechanism that involves the binding of PT cytosolic proteins to the PTH mRNA 3'-untranslated region (UTR). In a dietary model of secondary hyperparathyroidism due to hypocalcemia there is increased binding of parathyroid proteins to the 3'-UTR and decreased degradation as determined by an in vitro degradation assay. Changes in serum phosphate also dramatically regulate PTH mRNA stability. There is also regulation at the level of PT cell proliferation. PT cell proliferation is increased by experimental hypocal- cemia or hyperphosphatemia and decreased by hypo- phosphatemia and administered 1,25(OH) 2 D 3 . The un- derstanding of the molecular mechanisms involved in the genesis of secondary hyperparathyroidism will allow the design of new effective strategies in the management of this troubling condition.

Molecular mechanisms of secondary hyperparathyroidism.

Secondary hyperparathyroidism is a frequent complication of chronic renal failure (CRF) and a major factor in the pathogenesis of renal osteodystrophy. A high serum phosphate, decreased levels of serum 1,25(OH)2D3 and the subsequently low serum calcium are the major metabolic abnormalities in CRF, which lead to the secondary hyperparathyroidism. At the level of parathyroid hormone (PTH) secretion there is insensitivity to the ambient serum calcium. PTH mRNA levels are increased by a post-transcriptional mechanism that involves the binding of PT cytosolic proteins to the PTH mRNA 3'-untranslated region (UTR). In a dietary model of secondary hyperparathyroidism due to hypocalcemia there is increased binding of parathyroid proteins to the 3'-UTR and decreased degradation as determined by an in vitro degradation assay. Changes in serum phosphate also dramatically regulate PTH mRNA stability. There is also regulation at the level of PT cell proliferation. PT cell proliferation is increased by experimental hypocalcemia or hyperphosphatemia and decreased by hypophosphatemia and administered 1,25(OH)2D3. The understanding of the molecular mechanisms involved in the genesis of secondary hyperparathyroidism will allow the design of new effective strategies in the management of this troubling condition.

Renal osteodystrophy.

Secondary hyperparathyroidism develops in most patients with chronic renal failure, and is associated with the histologic finding of osteitis fibrosa cystica. The disease is characterized by growth failure and severe bone deformities in children, especially the very young. The pathogenesis of renal osteodystrophy is related to phosphate retention, and its effect on calcium and calcitriol metabolism, in addition to roles played by metabolic acidosis, cytokines, and degradation of parathyroid hormone. Treatment includes restriction of dietary phosphorous intake, phosphate binders, and use of active metabolites of vitamin D.

Metabolism of Transforming Growth Factor-β in Patients Receiving Hemodialysis Especially Those with Renal Osteodystrophy

We evaluated the intraplatelet and plasma levels of transforming growth factor β (TGF-β) in patients with or without renal osteodystrophy (ROD) who were undergoing hemodialysis (HD). Intraplatelet and plasma levels of TGF-β were examined before and after HD, and compared with those from healthy controls. Patients undergoing HD had significantly higher mean intraplatelet levels of TGF-β before and after HD than did the healthy subjects (22.7 ±7.8 and 29.5 ±15.8 vs. 18.7 ±7.9 ng/105 platelets; p <.05). The mean intraplatelet and plasma levels of TGF-β in patients after HD were significantly increased than those before HD and in healthy subjects (p <.05). Moreover, patients with ROD showed a significantly higher mean intra-platelet and plasma levels of TGF-β than that without ROD (p <.05). To investigate the effects of TGF-β on ROD in HD patients, we evaluated such parameters as parathyroid hormone (PTH) and alkaline phosphatase (ALP), which reflect the lesions of ROD. The mean intraplatelet level of TGF-β was not correlated with either parameter. Meanwhile, no correlation was observed between the intraplatelet level of TGF-β and the hematocrit (Hct). Similarly, no correlation was observed between the intraplatelet levels of TGF-β and the dose of erythropoietin (EPO)administered. These findings indicate that metabolism of TGF-β occurs during HD and overproduction of TGF-β may play an important role in the pathogenesis of ROD.

The role of metabolic acidosis in the pathogenesis of renal osteodystrophy.

Renal osteodystrophy is thought to be the result of abnormalities in the serum levels of parathyroid hormone, vitamin D, calcium, and phosphorus, and excess exposure to certain substances such as aluminum and iron. However, a significant amount of data suggest that the metabolic acidosis that develops in the course of chronic renal failure may also play a contributory role. Metabolic acidosis may effect changes in bone by directly inducing dissolution of bone, stimulating osteoclast-mediated bone resorption, inhibiting osteoblast-mediated bone formation, and altering the serum concentrations or the biological actions of parathyroid hormone and vitamin D. As a consequence, in some patients with normal renal function, osteoporosis and osteomalacia have been reported that are linked in part to metabolic acidosis. Also, in patients with chronic renal failure before and after initiation of dialysis, the severity of the metabolic acidosis appears to have a bearing on the presence and degree of hyperparathyroidism, osteitis fibrosa, and osteomalacia. Taken as a whole, these data suggest that correction of the metabolic acidosis of chronic renal failure may have a beneficial effect on the bone disease observed in these patients. This article reviews (1) the data indicating the mechanisms by which metabolic acidosis causes alterations in bone; (2) the types of bone lesions observed in animals and humans with metabolic acidosis in the presence of normal and abnormal renal function; (3) the impact of correction of the acidosis on the bone lesions; and (4) specific recommendations for treatment in patients with chronic renal failure both before and after initiation of maintenance dialysis.

Calcium acetate versus calcium carbonate as phosphate-binding agents in chronic haemodialysis

Hyperphosphataemia plays a key role in the pathogenesis of renal osteodystrophy, and phosphate-binding agents are required in many chronic dialysis patients. Aluminium hydroxide and calcium carbonate are well-established phosphate binders, but their use is associated with toxicity or poor efficacy. Calcium acetate is known to be a potent phosphate binder, and has recently been used successfully in chronic dialysis patients. In this randomized cross-over trial in 31 chronic haemodialysis patients, equimolar doses of calcium acetate and calcium carbonate were administered for 6 weeks each. Compliance was estimated from tablet counts, and biochemical parameters were measured at the end of each treatment period. Of the 31 patients 23 completed both treatment arms; of the remainder, three withdrew due to adverse symptoms, hypercalcaemia necessitated treatment withdrawal in two, and three died. Non-compliance was significantly higher with acetate (18.3% tablets not taken) than with carbonate (8.7%). Serum phosphate was significantly lower after treatment with acetate (1.51 mmol/l) than with carbonate (1.80), as was the Ca x PO4 product (3.59 vs 4.18 respectively) and PTH (17.8 vs 25.4 pmol/l respectively). Serum calcium was significantly higher after acetate therapy (2.40 vs 2.32 mmol/l). No significant difference was found for sodium, potassium, bicarbonate, urea, creatinine, and haemoglobin. This study confirms that the treatment of hyperphosphataemia is more effective with calcium acetate than with calcium carbonate. For the first time an associated beneficial effect on secondary hyperparathyroidism has also been demonstrated. Patient tolerability of calcium acetate was considerably poorer, probably due in part to tablet formulation and bulkiness, as well as possible direct gastrointestinal effects of the acetate salt.