Steven C. Verberckmoes

Ultrastructural Analysis of Vascular Calcifications in Uremia

Accelerated intimal and medial calcification and sclerosis accompany the increased cardiovascular mortality of dialysis patients, but the pathomechanisms initiating microcalcifications of the media are largely unknown. In this study, we systematically investigated the ultrastructural properties of medial calcifications from patients with uremia. We collected iliac artery segments from 30 dialysis patients before kidney transplantation and studied them by radiography, microcomputed tomography, light microscopy, and transmission electron microscopy including electron energy loss spectrometry, energy dispersive spectroscopy, and electron diffraction. In addition, we performed synchrotron x-ray analyses and immunogold labeling to detect inhibitors of calcification. Von Kossa staining revealed calcification of 53% of the arteries. The diameter of these microcalcifications ranged from 20 to 500 nm, with a core-shell structure consisting of up to three layers (subshells). Many of the calcifications consisted of 2- to 10-nm nanocrystals and showed a hydroxyapatite and whitlockite crystalline structure and mineral phase. Immunogold labeling of calcification foci revealed the calcification inhibitors fetuin-A, osteopontin, and matrix gla protein. These observations suggest that uremic microcalcifications originate from nanocrystals, are chemically diverse, and intimately associate with proteinaceous inhibitors of calcification. Furthermore, considering the core-shell structure of the calcifications, apoptotic bodies or matrix vesicles may serve as a calcification nidus.

Lanthanum carbonate: a new phosphate binder

Purpose of reviewHyperphosphatemia remains an important aspect in the management of end-stage renal disease patients. Consequently, there is a need for new, efficient and well-tolerated phosphate binders. In this review, a new phosphate-binding drug, lanthanum carbonate, with an attractive preclinical efficacy profile compared with existing binders, is discussed. Although the available human efficacy and safety data over 3 years are encouraging, the consequences of low-level tissue deposition continue to be evaluated in longer-term clinical studies. Recent findingsLanthanum carbonate has been shown in clinical studies of up to 3 years to be an effective, well-tolerated phosphate binder. Reported adverse effects are mainly gastrointestinal, and do not differ from those of calcium carbonate. The gastrointestinal absorption of lanthanum is very low. Whereas the element is mainly excreted by the liver, renal excretion of the absorbed fraction is less than 2%. Bone lanthanum levels seen after long-term treatment (up to 4 years) seem not to affect the physicochemical process of mineralization, or osteoblast number/function. Preliminary data on the localization of lanthanum in bone have shown the element to be present at both active and quiescent sites of bone mineralization, independent of the type of renal osteodystrophy, a profile distinct from aluminum, as well as diffusely distributed throughout the mineralized bone matrix especially in rats/humans with an increased bone turnover. A randomized, comparator-controlled, parallel group, open-label study comparing lanthanum carbonate with calcium carbonate in dialysis patients showed no evolution towards low bone turnover in the lanthanum group, and no aluminum-like effect on bone. SummaryLanthanum carbonate seems to be a potent phosphate-binding drug, minimally absorbed from the gut, with an encouraging safety profile, and no deleterious effects on bone.

1,25-Dihydroxyvitamin D3-induced aortic calcifications in experimental uremia: up-regulation of osteoblast markers, calcium-transporting proteins and osterix.

Background and objective Whether treatment with vitamin D receptor activators contributes to cardiovascular disease in patients with chronic kidney disease is a matter of debate. We studied mechanisms involved in vitamin D-related vascular calcifications in vivo and in vitro. Methods Aortic calcifications were induced in subtotally nephrectomized (SNX) rats by treatment with a high dose (0.25 μg/kg per day) of 1,25-dihydroxyvitamin D3 (calcitriol) given for 6 weeks. Likewise, primary rat vascular smooth muscle cells (VSMCs) were incubated with calcitriol at concentrations ranging from 10−11 to 10−7 mol/l. Immunohistochemistry revealed that the aortic expression of osteopontin, osteocalcin and bone sialoprotein was significantly increased in calcitriol-treated SNX rats compared to untreated SNX controls. In addition, aortic expression of the transient receptor potential vanilloid calcium channel 6 (TRPV6) and calbindin D9k was significantly up-regulated by treatment with calcitriol. Furthermore, calcitriol significantly increased expression of the osteogenic transcription factor osterix. In-vitro studies showed similar results, confirming that these effects could be attributed to treatment with calcitriol. Conclusions High-dose calcitriol treatment induces an osteoblastic phenotype in VSMC both in SNX rats and in vitro, associated with up-regulation of proteins regulating mineralization and calcium transport, and of the osteogenic transcription factor osterix.

Hepatocellular transport and gastrointestinal absorption of lanthanum in chronic renal failure

Lanthanum carbonate is a new phosphate binder that is poorly absorbed from the gastrointestinal tract and eliminated largely by the liver. After oral treatment, we and others had noticed 2-3 fold higher lanthanum levels in the livers of rats with chronic renal failure compared to rats with normal renal function. Here we studied the kinetics and tissue distribution, absorption, and subcellular localization of lanthanum in the liver using transmission electron microscopy, electron energy loss spectrometry, and X-ray fluorescence. We found that in the liver lanthanum was located in lysosomes and in the biliary canal but not in any other cellular organelles. This suggests that lanthanum is transported and eliminated by the liver via a transcellular, endosomal-lysosomal-biliary canicular transport route. Feeding rats with chronic renal failure orally with lanthanum resulted in a doubling of the liver levels compared to rats with normal renal function, but the serum levels were similar in both animal groups. These levels plateaued after 6 weeks at a concentration below 3 microg/g in both groups. When lanthanum was administered intravenously, thereby bypassing the gastrointestinal tract-portal vein pathway, no difference in liver levels was found between rats with and without renal failure. This suggests that there is an increased gastrointestinal permeability or absorption of oral lanthanum in uremia. Lanthanum levels in the brain and heart fluctuated near its detection limit with long-term treatment (20 weeks) having no effect on organ weight, liver enzyme activities, or liver histology. We suggest that the kinetics of lanthanum in the liver are consistent with a transcellular transport pathway, with higher levels in the liver of uremic rats due to higher intestinal absorption.