[Hyperphosphatemic pseudotumoral calcinosis due to FGF23 mutation with secondary amyloidosis].

A 44 years old man was admitted for nephrotic syndrome and rapidly progressive renal failure. Two firm, tumour-like masses were localized around the left shoulder and the right hip joint. Since the age of 8 years old, the patient had a history of metastatic calcification of the soft tissues suggesting hyperphosphatemic pseudotumoral calcinosis. Despite treatment for a long time with phosphate binders the metastatic calcinosis had to be removed with several surgeries. The patient had also a history of recurrent fever associated with pain localized toward the two masses and underwent multiple antibiotic courses. Laboratory findings at admission confirmed nephrotic syndrome. S-creatinine was 2.8 mg/dl. Calcium was 8.4 mg/dl, Phosphorus 8.2 mg/dl, PTH 80 pg/ml, 25 (OH)VitD 8 ng/ml. Serum amyloid A was slightly increased. We performed renal biopsy and we found AA amyloid deposits involving the mesangium and the tubules. The bone marrow biopsy revealed the presence of AA amyloid in the vascular walls. During the next two months renal failure rapidly progressed and the patient started hemodialysis treatment. We performed genetic analysis that confirmed homozygous mutation of the FGF23 gene. After 14 months on hemodialysis, the patient's lesions are remarkably and significantly reduced in dimension. The current phosphate binder therapy is based on sevelamer and lanthanum carbonate. Serum amyloid A is persistently slightly increased as well as C reactive protein. Proteinuria is in the nephrotic range without nephrotic syndrome.

PEAR1 is not a human hypertension-susceptibility gene.

OBJECTIVE: Platelet endothelial aggregation receptor 1 (PEAR1) is a membrane protein involved in platelet contact-induced activation and sustained platelet aggregation. Experimental studies identified PEAR1, as a candidate gene that may be linked to the blood-pressure driven kidney injury in salt-sensitive Dahl rats. AIM: In a family-based European population study (mean age 39.7 years; 52.2% women), we searched for association of changes in blood pressure or incidence of hypertension with genetic variation in PEAR1. METHODS: Among 1973 randomly recruited people, genotyped for PEAR1, we measured blood pressure at baseline and follow-up. RESULTS: Median follow-up was 10.0 years. While accounting for family clusters and blood pressure at baseline and with adjustments applied for sex, age, body mass index, smoking and drinking, total cholesterol, and antihypertensive drug treatment, all associations of systolic and diastolic blood pressure changes with nine single nucleotide polymorphisms (SNPs) in PEAR1 were all non-significant (p ≥ 0.059). With similar adjustments, the incidence of hypertension (397 cases among 1532 participants were normotensive at baseline [25.9%]) was not related to the SNPs in PEAR1 (hazard ratios ≤ 1.09; p ≥ 0.09). CONCLUSION: Our study suggests that PEAR1 is not a hypertension susceptibility gene in humans.

The urinary proteome as correlate and predictor of renal function in a population study.

BACKGROUND: We investigate whether the urinary proteome refines the diagnosis of renal dysfunction, which affects over 10% of the adult population. METHODS: We measured serum creatinine, estimated glomerular filtration rate (eGFR) and 24-h albuminuria in 797 people randomly recruited from a population. We applied capillary electrophoresis coupled with mass spectrometry to measure multi-dimensional urinary proteomic classifiers developed for renal dysfunction (CKD273) or left ventricular dysfunction (HF1 and HF2). Renal function was followed up in 621 participants and the incidence of cardiovascular events in the whole study population. RESULTS: In multivariable-adjusted cross-sectional analyses, higher biomarker levels analysed separately or combined by principal component analysis into a single factor (SF), correlated (P ≤ 0.010) with worse renal function. Over 4.8 years, higher HF1 and SF predicted (P ≤ 0.014) lowering of eGFR; higher HF2 predicted (P ≤ 0.049) increase in serum creatinine and decrease eGFR. HF1, HF2 and SF predicted progression from CKD Stages 2 or ≤2 to Stage ≥3, with risk estimates for a 1-SD increment in the urinary biomarkers ranging from 38 to 71% (P ≤ 0.039). HF1, HF2 and SF yielded a net reclassification improvement of 31-51% (P ≤ 0.029). Over 6.1 years, 47 cardiovascular events occurred. HF2 and SF, independent of baseline eGFR, 24-h albuminuria and other covariables were significant predictors of cardiovascular complications with risk estimates for 1-SD increases ranging from 32 to 41% (P ≤ 0.047). CONCLUSIONS: The urinary proteome refines the diagnosis of existing or progressing renal dysfunction and predicts cardiovascular complications.

[Renal effects of combined anti-hypertensive treatments]. / Effetti sulla funzione renale dei trattamenti antipertensivi associati.

ACE inhibitors and angiotensin receptor blockers confer renal protection in proteinuric nephropaties, but recently worsening of renal outcomes has been reported in non-proteinuric patients treated with a combination of ramipril and telmisartan, compared to ramipril only. In view of these apparently contradictory data, the review wants to shed light on treatment modalities of patients with hypertension and chronic kidney disease.

Management of secondary hyperparathyroidism in the elderly patient with chronic kidney disease.

Patients with chronic kidney disease (CKD) are generally affected by secondary hyperparathyroidism (SHPT). High phosphate, low calcium and vitamin D deficiency represent the classical 'triad' involved into the pathogenesis of SHPT in renal insufficiency, in which downregulation of the parathyroid vitamin D receptor and calcium-sensing receptor represents a critical step. Recently, new studies indicate that fibroblast growth factor 23 may play a central role in the regulation of phosphate-vitamin D metabolism in patients with CKD. These new insights into the pathogenesis of SHPT will possibly improve the treatment of this condition in patients with CKD. The 'modern' treatment of SHPT in CKD patients consists of free-calcium and aluminium phosphate binders, vitamin D receptor activators and calcimimetics. However, calcium- and aluminium-based phosphate binders and calcitriol are therapeutic tools that are not without complications, including increasing the risk of cardiovascular calcification in patients with CKD. This review summarizes the current understanding and evidence supporting strategies for SHPT treatment in CKD patients, with particular focus on the elderly, although specific guidelines for control of this disorder in this age group are lacking.

Importance of vitamin D receptor activation in clinical practice.

Continuously emerging evidence indicates that defi ciencies in 25-hydroxyvitamin D and consequently vitamin D receptor (VDR) activation play crucial roles in adversely affecting cardiovascular (CV) health in the general population and those at high risk of CV disease, as well as in patients with chronic kidney disease (CKD). In CKD patients, a lack of VDR activation is one of the main pathophysiological factors contributing to secondary hyperparathyroidism (SHPT). However, this lack of VDR activation has numerous additional implications on CV and renal function, with SHPT being only one symptom of a much more extensive disorder. VDRs are widely expressed throughout the body with manifold activities that involve feedback loops within the CV, immune, and renal systems. Modulation of VDR activator levels results in correlative regulatory effects on mineral homeostasis, hypertension, vascular disease, and vascular calcifi cation, as well as a number of other endpoints in cardiac and renal pathology. Among compounds available for the treatment of SHPT, paricalcitol is a selective VDR activator. The term 'selective' refers to paricalcitol being more selective in affecting VDR pathways in the PTH gland compared with bone and intestine. As such, paricalcitol's selectivity allows for a wider therapeutic window with effects beyond PTH control and mineral management, and may explain, in part, the increased survival advantage with paricalcitol treatment.

New acquisitions in therapy of secondary hyperparathyroidism in chronic kidney disease and peritoneal dialysis patients: role of vitamin D receptor activators.

Secondary hyperparathyroidism is a serious complication of chronic renal disease when function decline and is characterized by abnormalities in serum calcium and phosphate profile, along with a decline in calcitriol synthesis. A reduced density of specific receptors for vitamin D and calcium in several tissues and organs are also present, thus contributing to parathyroid hyperplasia and abnormal parathyroid hormone synthesis and secretion. This metabolic derangement is observable early in the course of chronic renal failure (stages 3 and 4) and on this basis it should also be treated early in order to avoid important clinical consequences. To afford secondary hyperparathyroidism, several strategies should be considered: phosphate oral intake control (diet and phosphate binders), adequate calcium oral intake, vitamin D receptor activation. More specifically, the concept of selective vitamin D receptor activation will be considered as well as its biological effects, the use of paricalcitol (a selective vitamin D receptor activator) given orally to patients on peritoneal dialysis, and stages 3 and 4 of chronic renal failure. Finally, we will consider a series of nonclassical interesting potential mechanisms of selective vitamin D receptor activation leading to reduced cardiovascular and all-cause mortality.

Pathogenesis of secondary hyperparathyroidism.

Chronic renal failure is the primary cause of secondary hyperparathyroidism (SHPT). Patients with mineral metabolism disorders commonly present with low serum calcium levels, hyperphosphatemia, and calcitriol deficiency. In normal renal function subjects, parathyroid cells have a low turnover and rarely undergo mitoses. In uremic conditions, however, parathyroid glands become hyperplasic and leave quiescence. During the last ten years, new molecular mechanisms have been investigated to better understand the pathogenesis of SHPT: the emerging role of the Calcium Sensing Receptor (CaSR); the importance of the parathyroid expression of the Vitamin D receptor (VDR); the growing evidence on the central role of the Fibroblast Growth Factor 23 (FGF-23). In contrast, the discovery of a parathyroid phosphate sensor or receptor has yet to be made.

Vitamin D: physiology and pathophysiology.

Although vitamin D was initially considered a nutrient, it has been recognized that the molecules derived from vitamin D metabolism are best considered as a complex endocrine system. In this review article we summarize the basic concepts regarding vitamin D metabolism, transport, and genomic activity through the vitamin D receptor, facilitating activation or suppression of target genes. We also examine non-genomic actions, biological responses to vitamin D in classic target organs (intestine, bone, kidneys, and parathyroid glands), and in organs and tissues not related to mineral homeostasis.

Pathophysiology of calcium and phosphate metabolism impairment in chronic kidney disease.

Secondary hyperparathyroidism (SHPT) is a classical feature of chronic kidney disease (CKD). Commonly, hypocalcemia, hyperphosphatemia, and vitamin D deficiency are involved into the pathogenesis of SHPT. Parathyroid (PT) glands are characterized by a low turnover and rarely undergo mitoses. However, in the presence of low calcium, high phosphorus, vitamin D deficiency, and uremia, PT cells leave quiescence. In the last decade, both new molecular and cellular mechanisms have been investigated in the pathophysiology of SHPT, between them the emerging role of the PT vitamin D receptor and calcium-sensing receptor. Furthermore, recent studies indicate that the fibroblast growth factor-23 may play a central role in the regulation of phosphate-vitamin D metabolism in CKD. Certainly, in the next future, these new insights into the pathogenesis of SHPT will give the possibility to improve the treatment of this condition in the CKD population.