Uremia-related vascular calcification: More than apatite deposition

Verberckmoes, Steven; Persy, Veerle P.; Behets, Geert J.; Neven, Ellen; Hufkens, A.; Zebger-Gong, Hong; Müller, Dominik; Haffner, Dieter; Querfeld, Uwe; Bohic, Sylvain; Broe, Marc E. De; D’Haese, Patrick C.

doi:10.1038/sj.ki.5002028

Cited by 79 publications

(64 citation statements)

References 33 publications

(42 reference statements)

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“…With synchrotron radiation analysis, however, because of the combination of micrometer resolution and short acquisition times (a few seconds), a more systematic scanning of the sample covering a larger area can be obtained, which is a major advantage of this technique-albeit at the cost of a lower resolution when compared with high-resolution TEM techniques. To the best of our knowledge, only Verberckmoes et al 10 applied synchrotron radiation analysis to examine vascular calcifications in rats with uremia, in which they also identified whitlockite as an important component of the mineral phase, particularly in vitamin D-treated animals. No studies using synchrotron radiation for diffraction analysis of human vascular calcification have been reported so far.…”

Section: Discussionmentioning

confidence: 99%

“…These previous studies used different tissues and yielded different results: Hydroxyapatite [Ca 10 (PO 4 ) 6 OH 2 ]-as seen in the skeleton-was described as the sole mineral phase of uremic arterial calcifications in two studies, 7,8 whereas another study found both brushite and hydroxyapatite in calcifications of stenotic arteriovenous fistulas. 9 In a rodent study of uremic calcification, whitlockite, a magnesium-containing crystal [(Ca,Mg) 3 (PO 4 ) 2 ], was detected in addition to hydroxyapatite.…”

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confidence: 99%

“…9 In a rodent study of uremic calcification, whitlockite, a magnesium-containing crystal [(Ca,Mg) 3 (PO 4 ) 2 ], was detected in addition to hydroxyapatite. 10 Different mineral phases arising during uremic medial calcification may potentially be the result of different pathomechanisms ultimately affecting dissolution of the calcifications and the choice of therapy. We therefore performed a systematic ultrastructural analysis of uremic media calcifications in patients with ESRD.…”

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confidence: 99%

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Ultrastructural Analysis of Vascular Calcifications in Uremia

Schlieper¹,

Aretz²,

Verberckmoes³

et al. 2010

Journal of the American Society of Nephrology

150

134

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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.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Ultrastructural Analysis of Vascular Calcifications in Uremia

Schlieper¹,

Aretz²,

Verberckmoes³

et al. 2010

Journal of the American Society of Nephrology

150

134

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“…In addition, the accompanying The increase in phosphate levels predisposes to the precipitation of calcium phosphate crystals in the media of the walls of the vessels. (18,19) In an elegant study on the rat model, Verberckmoes et al found calcium phosphate and whitlockite crystals in the aortas of uraemic animals.…”

Section: Bone-mineral Disorder (Bmd)mentioning

confidence: 99%

Chronic kidney disease is a risk factor for cardiovascular disease

Swanepoel¹

2017

SAHJ

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Chronic kidney disease (CKD) is common, harmful and treatable. There are no accurate statistics on the prevalence of kidney disease in South Africa but the world prevalence is estimated at approximately 10%. Patients with CKD have cardiovascular (CV) mortality rates as high as 50%. In addition to traditional risk factors, these patients are exposed to other non-traditional CV risk factors. It is important to stress that with the development of early CKD in the form of increasing albuminuria, even from within the normal range (a marker of endothelial dysfunction), the patient is at increased risk of coronary heart disease. "Reverse epidemiology" is the paradox where a high body mass index predicts a better long-term survival in patients with CKD on haemodialysis. Curiously these patients have increased infl ammatory markers and atherosclerosis. "Confounding by disease" or "reverse causality" is used to explain why the traditional relationship of increased cholesterol, increased LDL cholesterol and CV risk is not present (except in nephrotics) in CKD. The high phosphate level predisposes to calcium phosphate crystal deposition in the vessels and heart valves. The resultant arteriosclerosis produces the increased pulse wave velocity and systolic hypertension. Rapid valvular calcifi cation, aortic stenosis being a particular diffi culty, and early onset coronary artery calcifi cation occur. Arrhythmias are common and the long QT interval syndrome is particularly pertinent. The risk of acquired LQTS is increased by the administration of drugs. Cardiac troponin T is elevated in approximately 25% of asymptomatic patients with CKD. The use of angiotensin converting enzyme inhibitors and angiotensin receptor blockers have been shown to reduce proteinuria and to slow the progressive loss of renal function seen in CKD. These agents also improve cardiac outcomes and reduce the incidence of stroke. Most trials on the management of coronary artery disease have excluded patients with renal disease, and it remains unclear whether the results obtained from these trails can be extrapolated to patients with CKD.

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“…16 However, we did not observe significant reversal of calcification after aortic transplantation in an animal model of this disorder. 17 Vascular calcifications are composed primarily of apatitic mineral with varying amounts of whitlockite, 18,19 both of which are highly insoluble under physiological conditions 20 and thus are not expected to disappear spontaneously. Apatite appears not to form spontaneously from calcium and phosphate ions, whereas initially brushite (CaHPO 4 2H 2 O) and/or other intermediates (including amorphous calcium phosphate) that are more soluble may be present in variable amounts in calcified vessels.…”

mentioning

confidence: 99%

Persistence of Vascular Calcification after Reversal of Uremia

Lomashvili

Manning

Weitzmann

et al. 2017

The American Journal of Pathology

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The extent to which vascular calcification is reversible and the possible mechanisms are unclear. To address this, calcified aortas from uremic mice were transplanted orthotopically into normal mice, and the calcium content, histology, and minerals of the allografts were compared with the nontransplanted donor aorta. Calcium content decreased immediately after transplantation but remained constant thereafter, with 68% AE 12% remaining after 34 weeks. X-ray diffraction showed the presence of apatite in both donor aortas and allografts. Osteoclasts were absent in the allografts and there was no expression of the macrophage marker CD11b, the osteoclast marker tartrate-resistant acid phosphatase, or carbonic anhydrase II. The initial loss of calcium was less in heavily calcified aortas and was associated with an increase in the Ca/P ratio from 1.49 to 1.63, consistent with a loss of nonapatitic calcium. The results indicate that vascular calcification persists after reversal of uremia, because of a lack of active resorption of apatite. This failure to resorb established calcifications may contribute to the severity of vascular calcification and suggests that therapy should be aimed at prevention.

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Uremia-related vascular calcification: More than apatite deposition

Cited by 79 publications

References 33 publications

Ultrastructural Analysis of Vascular Calcifications in Uremia

Ultrastructural Analysis of Vascular Calcifications in Uremia

Chronic kidney disease is a risk factor for cardiovascular disease

Persistence of Vascular Calcification after Reversal of Uremia

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