doi: 10.1161/hq1001.097102
© 2001 American Heart Association, Inc.
Vascular Biology |
Osteoprotegerin Inhibits Artery Calcification Induced by Warfarin and by Vitamin D
From the Division of Biology, University of California, San Diego, La Jolla.
Correspondence to Dr Paul A. Price, Department of Biology, 0368, University of California, San Diego, La Jolla, CA 92093-0368. E-mail pprice{at}ucsd.edu
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Abstract |
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Abstract—— The present experiments were carried out to test the hypothesis that arterial calcification is linked to bone resorption by determining whether the selective inhibition of bone resorption with osteoprotegerin will inhibit arterial calcification. In the first test, arterial calcification was induced by treating 22-day-old male rats with warfarin, a procedure that inhibits the
-carboxylation of matrix Gla protein and causes extensive calcification of the arterial media. Compared with rats treated for 1 week with warfarin alone, rats treated with warfarin plus osteoprotegerin at a dose of 1 mg/kg per day had dramatically reduced alizarin red staining for calcification in the aorta and in the carotid, hepatic, mesenteric, renal, and femoral arteries, and they had 90% lower levels of calcium and phosphate in the abdominal aorta (P<0.001) and in tracheal ring cartilage (P<0.01). More rapid arterial calcification was induced by treating 49-day-old male rats with toxic doses of vitamin D. Treatment for 96 hours with vitamin D caused widespread alizarin red staining for calcification in the aorta and the femoral, mesenteric, hepatic, renal, and carotid arteries, and osteoprotegerin completely prevented calcification in each of these arteries and reduced the levels of calcium and phosphate in the abdominal aorta to control levels (P<0.001). Treatment with vitamin D also caused extensive calcification in the lungs, trachea, kidneys, stomach, and small intestine, and treatment with osteoprotegerin reduced or prevented calcification in each of these sites. Measurement of serum levels of cross-linked N-teleopeptides showed that osteoprotegerin dramatically reduced bone resorption activity in each of these experiments (P<0.001). Therefore, we conclude that doses of osteoprotegerin that inhibit bone resorption are able to potently inhibit the calcification of arteries that is induced by warfarin treatment and by vitamin D treatment. These results support the hypothesis that arterial calcification is linked to bone resorption.
Key Words: osteoprotegerin • artery calcification • vitamin D • bone resorption • matrix Gla protein
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Introduction |
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We have recently proposed the hypothesis that arterial calcification is linked to bone resorption1,2 to explain the association between the increased bone resorption and increased arterial calcification that has been seen in the vitamin D-treated rat,1 in the osteoprotegerin-deficient mouse,3 and in patients with postmenopausal osteoporosis.4–12 One prediction of the hypothesis that arterial calcification is linked to bone resorption is that inhibitors of bone resorption should inhibit arterial calcification.2 In previous studies, we have shown that arterial calcification induced by treatment with warfarin and by treatment with high doses of vitamin D is indeed inhibited by 2 potent inhibitors of bone resorption, the amino bisphosphonates alendronate and ibandronate, at doses of these drugs known to inhibit bone resorption in the rat.2,13 In the present investigations, we have determined the effect of another potent inhibitor of bone resorption, osteoprotegerin, on arterial calcification by using subcutaneous doses of this protein that have been shown to inhibit bone resorption in the rat.
Osteoprotegerin is a secreted protein of the tumor necrosis factor family, which regulates bone mass by inhibiting osteoclast differentiation and activation.14,15 In mice, targeted deletion of the osteoprotegerin gene results in an overall decrease in total bone density and a high incidence of fractures,3,16 as well as the calcification of the aorta and renal arteries. The early-onset osteoporosis observed in these mice is a result of increased bone resorption associated with increased numbers and activity of osteoclasts. In contrast, overexpression of osteoprotegerin in transgenic mice results in severe osteopetrosis associated with a decrease in osteoclasts in metaphyseal trabecular bone.14 Osteoprotegerin exerts its inhibitory effects on the osteoclast by binding to osteoprotegerin ligand (OPGL) and thereby inhibiting the interaction between receptor activator of nuclear factor 
B (RANK) and OPGL on osteoclasts and their precursors.17,18 Therefore, osteoprotegerin is a secreted inhibitor of the RANK signaling pathway in the osteoclast.
Two animal models have been used to test the efficacy of osteoprotegerin as an inhibitor of arterial calcification in the present study. In the first animal model, arterial calcification was induced by treatment with the vitamin K antagonist warfarin.1,19 This treatment causes arterial calcification by inhibiting the vitamin K-dependent carboxylation of the matrix Gla protein (MGP) and thereby inactivating the calcification inhibitory activity of the protein and does not elevate bone resorption or serum calcium levels. The arterial calcification induced by warfarin treatment is initially associated with the elastic lamellae of the arterial media, a pattern of arterial calcification also seen in the MGP gene knockout mouse.20 MGP deficiency also causes abnormal calcification of cartilage in warfarin-treated rats,19 in the MGP knockout mouse,20 and in patients with a defect in the MGP gene.21,22
In the second animal model, arterial calcification was induced by treatment with toxic doses of vitamin D,1,13 a treatment that has been known for >60 years to cause calcification of the elastic lamellae in the arterial media of humans, rats, and other species.23–25 Although the mechanism by which vitamin D intoxication induces arterial calcification is poorly understood, these vitamin D doses potently stimulate bone resorption and elevate serum calcium by >30%.
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The Methods section can be accessed online at http://atvb.ahajournals.org.
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Results |
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Effect of Osteoprotegerin on Soft Tissue Calcification Induced by Warfarin Treatment
The initial osteoprotegerin test was carried out by use of a warfarin treatment procedure that has been previously shown to induce rapid calcification of arteries and cartilage in the rat1,19 and an osteoprotegerin dose that has been previously shown to inhibit bone resorption.14,26,27 As seen in Figure 1, treatment for 1 week with warfarin caused widespread alizarin red staining for calcification in the lower abdominal aorta and the femoral, mesenteric, hepatic, and renal arteries and scattered foci of calcification in the carotid arteries and the thoracic aorta; treatment with osteoprotegerin at a dose of 1 mg/kg per day dramatically reduced the extent of warfarin-induced arterial calcification at each of these locations. Microscopic examination of von Kossa-stained sections revealed calcification of the elastic lamellae in the media of arteries from the warfarin-treated animals and an absence of staining in the arteries from animals treated with warfarin plus osteoprotegerin (figure not shown). Warfarin treatment also caused extensive alizarin red staining for calcification in tracheal ring cartilage, and osteoprotegerin treatment inhibited this calcification (figure not shown).
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A repeat experiment was carried out to obtain a quantitative measure of the effects of treatment with warfarin alone and with warfarin plus osteoprotegerin on the accumulation of calcium phosphate mineral in arteries and cartilage. As shown in Table 1, treatment with warfarin alone increased tissue levels of calcium in the abdominal aorta by 105-fold and increased tissue levels of phosphate by 430-fold. Osteoprotegerin treatment markedly reduced abdominal aortic calcification in the warfarin-treated animals, with a 90% reduction in calcium and phosphate levels, but the levels of calcium and phosphate remained significantly above control levels. Similar results were obtained on analysis of calcium and phosphate levels in tracheal ring cartilage, with a 15-fold increase in calcium and a 24-fold increase in phosphate in the animals treated with warfarin alone. Osteoprotegerin treatment again markedly reduced tracheal ring cartilage calcification in the warfarin-treated animals, with a 50% reduction in calcium and a 65% reduction in phosphate, but the levels of calcium and phosphate remained significantly above control levels. There was no significant difference in serum calcium and phosphate levels measured on blood obtained at the end of this experiment for the animals treated with warfarin alone, the animals treated with warfarin plus osteoprotegerin, and the age-matched control animals.
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Effect of Osteoprotegerin on Soft Tissue Calcification Induced by Vitamin D Treatment
The effect of osteoprotegerin was also tested in rats treated with 500 000 IU vitamin D per kilogram for 3 days, a procedure that has been shown previously to induce extensive calcification of arteries and cartilage as well as kidneys, lungs, stomach, and small intestine. Figure 2 shows a typical example of the level of alizarin red staining for calcification seen in the arteries from the 4 rats treated with vitamin D alone and an example of the absence of alizarin red staining seen in the arteries from the 4 rats treated with vitamin D plus osteoprotegerin at a dose of 1 mg/kg per day. Note that calcification in the vitamin D-treated animals is most pronounced in the smaller branch arteries, such as the mesenteric, hepatic, and renal arteries. Microscopic examination of von Kossa-stained sections revealed massive calcification of the elastic lamellae in the media of arteries from the vitamin D-treated animals and absence of staining in the arteries from animals treated with vitamin D plus osteoprotegerin (figure not shown).
Figure 3 shows the typical alizarin red staining seen in the lungs of rats treated for 4 days with vitamin D alone and an example of the absence of alizarin red staining seen in lungs from the 4 rats treated with vitamin D plus osteoprotegerin at a dose of 1 mg/kg per day. Microscopic examination of von Kossa-stained sections showed that calcification is associated with the alveolar wall and pulmonary arteries (figure not shown). As can also be seen in Figure 3, vitamin D treatment caused increased calcification of tracheal ring cartilage, and osteoprotegerin treatment prevented this increase.
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A repeat experiment was carried out to obtain a quantitative measure of the effects of treatment with vitamin D alone and with vitamin D plus osteoprotegerin on the accumulation of calcium phosphate mineral in arteries and other soft tissues. As shown in Table 2, treatment with vitamin D plus osteoprotegerin significantly (P<0.001) decreased tissue levels of calcium and phosphate in the abdominal aorta, kidney, lung, small intestine, stomach, and trachea compared with the levels seen in animals treated with vitamin D alone. In 4 of these tissues, the levels of calcium and phosphate in the animals treated with vitamin D plus osteoprotegerin were the same as those seen in age-matched control animals (Table 2), whereas in the stomach and trachea, the levels of calcium and phosphate found in the animals treated with vitamin D plus osteoprotegerin remained above control levels. Calcium levels measured on serum obtained 96 hours after the first vitamin D injection were as follows: 14.6±0.5 mg/dL for rats treated with vitamin D only (n=8), 14.9±0.8 mg/dL for rats treated with vitamin D plus osteoprotegerin (n=8), and 10.9±0.3 mg/dL for untreated control rats (n=4).
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Sections of arteries, kidneys, lungs, small intestine, and the stomach were also stained by hematoxylin and eosin and examined. There was no evidence of cell necrosis or degeneration in any tissue from the animals treated with vitamin D plus osteoprotegerin, and the microscopic appearance of these tissues was indistinguishable from the appearance of corresponding tissues from age-matched untreated control animals.
Effect of Osteoprotegerin on Bone Resorption Activity
To confirm that osteoprotegerin did in fact inhibit bone resorption in the above experiments, serum samples obtained at death were analyzed to determine the level of cross-linked N-teleopeptides, a specific marker for bone resorption activity that is released during the osteoclast-mediated breakdown of bone matrix collagen. As seen in Table 3, the level of cross-linked N-teleopeptides was not affected by treatment with warfarin alone but was reduced by 40% in rats treated with warfarin plus osteoprotegerin. This result supports the hypothesis that warfarin induces arterial calcification by inactivating the calcification inhibitory activity of MGP rather than by accelerating bone resorption and shows that the doses of osteoprotegerin used in the present study do significantly reduce bone resorption activity in the warfarin-treated rat. As also shown in Table 3, the level of cross-linked N-teleopeptides was elevated by 160% in rats treated with vitamin D alone and was reduced to control levels in rats treated with vitamin D plus osteoprotegerin. This result supports the hypothesis that vitamin D treatment induces arterial calcification by accelerating bone resorption and shows that osteoprotegerin treatment reduces bone resorption activity to control levels in the vitamin D-treated rat.
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Although osteoprotegerin reduced the level of bone resorption activity in the vitamin D-treated rats to normal levels, it is intriguing to note that serum calcium levels remained 37% above normal. This observation shows that the elevation in serum calcium seen in rats treated with toxic doses of vitamin D is not due to accelerated bone resorption.
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Discussion |
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The principle conclusion of the present study is that an osteoprotegerin dose that is known to inhibit bone resorption in the rat is able to potently inhibit the calcification of arteries induced by treatment with warfarin alone and the calcification of arteries induced by treatment with toxic doses of vitamin D alone. Osteoprotegerin also inhibited the calcification of cartilage induced by warfarin and by vitamin D, and osteoprotegerin potently inhibited the calcification of kidneys, lungs, small intestine, and the stomach of animals treated with vitamin D. Previous studies have also shown that the osteoprotegerin transgene will prevent arterial calcification that is induced in mice by the targeted deletion of the osteoprotegerin gene.28
One mechanism by which osteoprotegerin could inhibit arterial calcification is by inhibiting bone resorption. We have recently proposed the hypothesis that arterial calcification is linked to bone resorption to explain the association between increased bone resorption and increased arterial calcification that has been seen in the vitamin D-treated rat, in the osteoprotegerin-deficient mouse, and in patients with postmenopausal osteoporosis.1,2 One prediction of this hypothesis is that inhibitors of bone resorption should also inhibit arterial calcification. In previous studies, we have shown that arterial calcification induced by treatment with warfarin and by treatment with high doses of vitamin D is indeed inhibited by 2 potent inhibitors of bone resorption, the amino bisphosphonates alendronate and ibandronate, at doses of these drugs comparable to those that inhibit bone resorption in the rat.2 The fact that a dose of osteoprotegerin that inhibits bone resorption (Table 3) will also inhibit arterial calcification is therefore further evidence in support of the hypothesis that arterial calcification is indeed linked to bone resorption.
Another mechanism by which osteoprotegerin could inhibit arterial calcification is by acting directly on cells in the artery to promote the expression of calcification inhibitors such as MGP. This possibility is supported by the observation that osteoprotegerin is expressed in the media of arteries in the mouse.14 However, OPGL and RANK are not expressed in the normal adult mouse aorta28; therefore, it is presently unclear whether there are cells in the artery before the onset of calcification that can be affected by osteoprotegerin via the RANK signaling pathway. Because osteoprotegerin is also a receptor for the cytotoxic ligand TNF-related apoptosis-indwelling ligand (TRAIL),29 which is found in the aorta and pulmonary artery of the mouse,30 one possibility could be that osteoprotegerin influences arterial calcification by inhibiting TRAIL-induced apoptosis of vascular cells. However, there is presently no evidence indicating that apoptosis of vascular cells is induced by treatment with warfarin. It is also worth noting in this regard that if osteoprotegerin inhibits arterial calcification by acting directly on cells in the artery rather than by inhibiting bone resorption, then it follows that bisphosphonates would also inhibit arterial calcification by acting on cells in the artery rather than by inhibiting bone resorption. Because bisphosphonates are now known to inhibit the osteoclast by inhibiting farnesyl diphosphate synthase, an enzyme found in many cell types, the hypothesis that bisphosphonates might act on cells in the arterial wall would appear to be plausible. However, there is no evidence to indicate that doses of bisphosphonates that inhibit bone resorption in animals have any effect on the activity of farnesyl diphosphate synthase in cells other than the osteoclast.31 Indeed, because the mechanism by which bisphosphonates gain access to the osteoclast involves their ability to concentrate on bone mineral surfaces under the osteoclast32,33 and be taken up by the osteoclast during bone resorption, there is in fact little reason to suppose that cells in a normal rat artery could be equivalently sensitive to bisphosphonates. Because the only presently known physiological action of amino bisphosphonates and of osteoprotegerin in vivo is the inhibition of bone resorption, it seems more reasonable to suggest that the proven ability of these drugs to inhibit bone resorption accounts for their effectiveness as inhibitors of arterial calcification than to postulate the existence of novel and as-yet-undocumented actions of both drugs on cells in the arterial wall.
The nature of the biochemical mechanism that is responsible for the putative linkage between bone resorption and arterial calcification is presently unclear. One possibility is that soft tissue calcification could be an entirely passive physicochemical process that is driven by serum levels of calcium and phosphate and that inhibitors of bone resorption exert their effects on soft tissue calcification by reducing the level of calcium and phosphate in serum. However, this hypothesis is not supported by the observation that doses of osteoprotegerin and of bisphosphonates that inhibit arterial calcification do not lower serum levels of calcium or phosphate in the warfarin-treated rat and do not normalize serum calcium levels in the vitamin D-treated rat. Another possibility is that soft tissue calcification is promoted by crystal nuclei generated at sites of bone resorption that travel in blood and occasionally lodge in soft tissue structures. This hypothesis is supported by the observation that under some circumstances, a complex of a calcium phosphate mineral phase and matrix Gla protein is released from bone and can be detected in blood and by the observation that the release of this complex from bone is inhibited by inhibitors of bone resorption (authors’ unpublished data, 2001).
There are clinical implications of the present findings that should be noted. Because the present studies show that doses of bisphosphonates and osteoprotegerin that inhibit bone resorption are effective inhibitors of arterial calcification in 2 entirely different animal models, it seems likely that inhibitors of bone resorption will also inhibit arterial calcification in some human patients. However, it is important to note that these animal studies show that inhibitors of bone resorption prevent the initiation of arterial calcification, not the progression of arterial calcification once it has been initiated. An important goal of future studies will be to determine whether bone resorption inhibitors such as osteoprotegerin can arrest the progression of arterial calcification once it has been established. It is also important to note that the arterial calcification induced by warfarin treatment, by vitamin D treatment, and by osteoprotegerin deficiency is primarily associated with elastic lamellae in the arterial media, a type of calcification seen in the Mönckeberg’s sclerosis in human subjects. The grossly hardened regions of the atherosclerotic plaque in human patients are primarily located in the intimal region of the artery, not the media, and another important goal of future studies will be to examine intimal calcification in the rodent model and to determine the effect of bone resorption inhibitors on this calcification.
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Acknowledgments |
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This work was supported in part by grant HL58090 from the National Heart, Lung, and Blood Institute of the National Institutes of Health.
Received July 6, 2001; accepted July 25, 2001.
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R. C. Shroff, V. Shah, M. P. Hiorns, M. Schoppet, L. C. Hofbauer, G. Hawa, L. J. Schurgers, A. Singhal, I. Merryweather, P. Brogan, et al. The circulating calcification inhibitors, fetuin-A and osteoprotegerin, but not Matrix Gla protein, are associated with vascular stiffness and calcification in children on dialysis Nephrol. Dial. Transplant., October 1, 2008; 23(10): 3263 - 3271. [Abstract] [Full Text] [PDF]
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H. F Escobar-Morreale, J. I Botella-Carretero, M. A. Martinez-Garcia, M. Luque-Ramirez, F. Alvarez-Blasco, and J. L S. Millan Serum osteoprotegerin concentrations are decreased in women with the polycystic ovary syndrome Eur. J. Endocrinol., September 1, 2008; 159(3): 225 - 232. [Abstract] [Full Text] [PDF]
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D. A. Mandelbrot, P. W. Santos, R. K. Burt, Y. Oyama, G. A. Block, S. N. Ahya, R. M. Rosa, and A. E. Traynor Resolution of SLE-related soft-tissue calcification following haematopoietic stem cell transplantation Nephrol. Dial. Transplant., August 1, 2008; 23(8): 2679 - 2684. [Abstract] [Full Text] [PDF]
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 L. L. Demer and Y. Tintut Vascular Calcification: Pathobiology of a Multifaceted Disease Circulation, June 3, 2008; 117(22): 2938 - 2948. [Full Text] [PDF]
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 A. E. Kearns, S. Khosla, and P. J. Kostenuik Receptor Activator of Nuclear Factor {kappa}B Ligand and Osteoprotegerin Regulation of Bone Remodeling in Health and Disease Endocr. Rev., April 1, 2008; 29(2): 155 - 192. [Abstract] [Full Text] [PDF]
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 M. Ignat, M. Teletin, J. Tisserand, K. Khetchoumian, C. Dennefeld, P. Chambon, R. Losson, and M. Mark Arterial calcifications and increased expression of vitamin D receptor targets in mice lacking TIF1{alpha} PNAS, February 19, 2008; 105(7): 2598 - 2603. [Abstract] [Full Text] [PDF]
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S. Morony, Y. Tintut, Z. Zhang, R. C. Cattley, G. Van, D. Dwyer, M. Stolina, P. J. Kostenuik, and L. L. Demer Osteoprotegerin Inhibits Vascular Calcification Without Affecting Atherosclerosis in ldlr( / ) Mice Circulation, January 22, 2008; 117(3): 411 - 420. [Abstract] [Full Text] [PDF]
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 Z. Al-Aly, J.-S. Shao, C.-F. Lai, E. Huang, J. Cai, A. Behrmann, S.-L. Cheng, and D. A. Towler Aortic Msx2-Wnt Calcification Cascade Is Regulated by TNF-{alpha} Dependent Signals in Diabetic Ldlr / Mice Arterioscler Thromb Vasc Biol, December 1, 2007; 27(12): 2589 - 2596. [Abstract] [Full Text] [PDF]
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 T. Stompor AN OVERVIEW OF THE PATHOPHYSIOLOGY OF VASCULAR CALCIFICATION IN CHRONIC KIDNEY DISEASE Perit. Dial. Int., June 1, 2007; 27(Supplement_2): S215 - S222. [Abstract] [Full Text] [PDF]
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R Shetty, A Pepin, A Charest, J Perron, D Doyle, P Voisine, F Dagenais, P Pibarot, and P Mathieu Expression of bone-regulatory proteins in human valve allografts Heart, September 1, 2006; 92(9): 1303 - 1308. [Abstract] [Full Text] [PDF]
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R. Westenfeld, M. Ketteler, and V. M. Brandenburg Anti-RANKL therapy--implications for the bone-vascular-axis in CKD? Denosumab in post-menopausal women with low bone mineral density Nephrol. Dial. Transplant., August 1, 2006; 21(8): 2075 - 2077. [Full Text] [PDF]
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 G.-d. Xiang, L. Xu, L.-s. Zhao, L. Yue, and J. Hou The relationship between plasma osteoprotegerin and endothelium-dependent arterial dilation in type 2 diabetes. Diabetes, July 1, 2006; 55(7): 2126 - 2131. [Abstract] [Full Text] [PDF]
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X. Qin, M. A. Corriere, L. M. Matrisian, and R. J. Guzman Matrix Metalloproteinase Inhibition Attenuates Aortic Calcification Arterioscler Thromb Vasc Biol, July 1, 2006; 26(7): 1510 - 1516. [Abstract] [Full Text] [PDF]
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 D. V. Anand, A. Lahiri, E. Lim, D. Hopkins, and R. Corder The Relationship Between Plasma Osteoprotegerin Levels and Coronary Artery Calcification in Uncomplicated Type 2 Diabetic Subjects J. Am. Coll. Cardiol., May 2, 2006; 47(9): 1850 - 1857. [Abstract] [Full Text] [PDF]
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P. A. Price, W. Si Chan, D. M. Jolson, and M. K. Williamson The Elastic Lamellae of Devitalized Arteries Calcify When Incubated in Serum: Evidence for a Serum Calcification Factor Arterioscler Thromb Vasc Biol, May 1, 2006; 26(5): 1079 - 1085. [Abstract] [Full Text] [PDF]
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L. L. Demer and Y. Tintut Pitting Phosphate Transport Inhibitors Against Vascular Calcification Circ. Res., April 14, 2006; 98(7): 857 - 859. [Full Text] [PDF]
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 I. Lopez, E. Aguilera-Tejero, F. J. Mendoza, Y. Almaden, J. Perez, D. Martin, and M. Rodriguez Calcimimetic R-568 Decreases Extraosseous Calcifications in Uremic Rats Treated with Calcitriol J. Am. Soc. Nephrol., March 1, 2006; 17(3): 795 - 804. [Abstract] [Full Text] [PDF]
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 A. Rogers and R. Eastell Circulating Osteoprotegerin and Receptor Activator for Nuclear Factor {kappa}B Ligand: Clinical Utility in Metabolic Bone Disease Assessment J. Clin. Endocrinol. Metab., November 1, 2005; 90(11): 6323 - 6331. [Abstract] [Full Text] [PDF]
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W. Y. Qunibi Reducing the Burden of Cardiovascular Calcification in Patients with Chronic Kidney Disease J. Am. Soc. Nephrol., November 1, 2005; 16(11_suppl_2): S95 - S102. [Abstract] [Full Text] [PDF]
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 H. H. Dao, R. Essalihi, C. Bouvet, and P. Moreau Evolution and modulation of age-related medial elastocalcinosis: Impact on large artery stiffness and isolated systolic hypertension Cardiovasc Res, May 1, 2005; 66(2): 307 - 317. [Abstract] [Full Text] [PDF]
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P.E. Norman and J.T. Powell Vitamin D, Shedding Light on the Development of Disease in Peripheral Arteries Arterioscler Thromb Vasc Biol, January 1, 2005; 25(1): 39 - 46. [Abstract] [Full Text] [PDF]
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C. M. Giachelli Vascular Calcification Mechanisms J. Am. Soc. Nephrol., December 1, 2004; 15(12): 2959 - 2964. [Abstract] [Full Text] [PDF]
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P. Collin-Osdoby Regulation of Vascular Calcification by Osteoclast Regulatory Factors RANKL and Osteoprotegerin Circ. Res., November 26, 2004; 95(11): 1046 - 1057. [Abstract] [Full Text] [PDF]
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 M. Bern Observations on Possible Effects of Daily Vitamin K Replacement, Especially Upon Warfarin Therapy JPEN J Parenter Enteral Nutr, November 1, 2004; 28(6): 388 - 398. [Abstract] [Full Text] [PDF]
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T. M. Doherty, L. A. Fitzpatrick, D. Inoue, J.-H. Qiao, M. C. Fishbein, R. C. Detrano, P. K. Shah, and T. B. Rajavashisth Molecular, Endocrine, and Genetic Mechanisms of Arterial Calcification Endocr. Rev., August 1, 2004; 25(4): 629 - 672. [Abstract] [Full Text] [PDF]
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M. Soufi, M. Schoppet, A. M. Sattler, M. Herzum, B. Maisch, L. C. Hofbauer, and J. R. Schaefer Osteoprotegerin Gene Polymorphisms in Men with Coronary Artery Disease J. Clin. Endocrinol. Metab., August 1, 2004; 89(8): 3764 - 3768. [Abstract] [Full Text] [PDF]
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M. Schoppet, N. Al-Fakhri, F. E. Franke, N. Katz, P. J. Barth, B. Maisch, K. T. Preissner, and L. C. Hofbauer Localization of Osteoprotegerin, Tumor Necrosis Factor-Related Apoptosis-Inducing Ligand, and Receptor Activator of Nuclear Factor-{kappa}B Ligand in Monckeberg's Sclerosis and Atherosclerosis J. Clin. Endocrinol. Metab., August 1, 2004; 89(8): 4104 - 4112. [Abstract] [Full Text] [PDF]
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 L. C. Hofbauer and M. Schoppet Clinical Implications of the Osteoprotegerin/RANKL/RANK System for Bone and Vascular Diseases JAMA, July 28, 2004; 292(4): 490 - 495. [Abstract] [Full Text] [PDF]
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M. Abedin, Y. Tintut, and L. L. Demer Vascular Calcification: Mechanisms and Clinical Ramifications Arterioscler Thromb Vasc Biol, July 1, 2004; 24(7): 1161 - 1170. [Abstract] [Full Text] [PDF]
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S. Kiechl, G. Schett, G. Wenning, K. Redlich, M. Oberhollenzer, A. Mayr, P. Santer, J. Smolen, W. Poewe, and J. Willeit Osteoprotegerin Is a Risk Factor for Progressive Atherosclerosis and Cardiovascular Disease Circulation, May 11, 2004; 109(18): 2175 - 2180. [Abstract] [Full Text] [PDF]
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 P. A. Price, H. H. June, N. J. Hamlin, and M. K. Williamson Evidence for a Serum Factor That Initiates the Re-calcification of Demineralized Bone J. Biol. Chem., April 30, 2004; 279(18): 19169 - 19180. [Abstract] [Full Text] [PDF]
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 E. J. Samelson, D. P. Kiel, K. E. Broe, Y. Zhang, L. A. Cupples, M. T. Hannan, P. W. F. Wilson, D. Levy, S. A. Williams, and V. Vaccarino Metacarpal Cortical Area and Risk of Coronary Heart Disease: The Framingham Study Am. J. Epidemiol., March 15, 2004; 159(6): 589 - 595. [Abstract] [Full Text] [PDF]
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 T. M. Doherty, L. A. Fitzpatrick, A. Shaheen, T. B. Rajavashisth, and R. C. Detrano Genetic Determinants of Arterial Calcification Associated With Atherosclerosis Mayo Clin. Proc., February 1, 2004; 79(2): 197 - 210. [Abstract] [PDF]
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P. A. Price, M. K. Williamson, T. M. T. Nguyen, and T. N. Than Serum Levels of the Fetuin-Mineral Complex Correlate with Artery Calcification in the Rat J. Biol. Chem., January 16, 2004; 279(3): 1594 - 1600. [Abstract] [Full Text] [PDF]
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J.-S. Shao, S.-L. Cheng, N. Charlton-Kachigian, A. P. Loewy, and D. A. Towler Teriparatide (Human Parathyroid Hormone (1-34)) Inhibits Osteogenic Vascular Calcification in Diabetic Low Density Lipoprotein Receptor-deficient Mice J. Biol. Chem., December 12, 2003; 278(50): 50195 - 50202. [Abstract] [Full Text] [PDF]
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M. Schoppet, A. M. Sattler, J. R. Schaefer, M. Herzum, B. Maisch, and L. C. Hofbauer Increased Osteoprotegerin Serum Levels in Men with Coronary Artery Disease J. Clin. Endocrinol. Metab., March 1, 2003; 88(3): 1024 - 1028. [Abstract] [Full Text] [PDF]
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P. A. Price, H. H. June, J. R. Buckley, and M. K. Williamson SB 242784, a Selective Inhibitor of the Osteoclastic V-H+-ATPase, Inhibits Arterial Calcification in the Rat Circ. Res., September 20, 2002; 91(6): 547 - 552. [Abstract] [Full Text] [PDF]
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 T. M. DOHERTY, H. UZUI, L. A. FITZPATRICK, P. V. TRIPATHI, C. R. DUNSTAN, K. ASOTRA, and T. B. RAJAVASHISTH Rationale for the role of osteoclast-like cells in arterial calcification FASEB J, April 1, 2002; 16(6): 577 - 582. [Abstract] [Full Text] [PDF]
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M. Schoppet, K. T. Preissner, and L. C. Hofbauer RANK Ligand and Osteoprotegerin: Paracrine Regulators of Bone Metabolism and Vascular Function Arterioscler Thromb Vasc Biol, April 1, 2002; 22(4): 549 - 553. [Abstract] [Full Text] [PDF]
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M. Schoppet, K. T. Preissner, and L. C. Hofbauer RANK Ligand and Osteoprotegerin: Paracrine Regulators of Bone Metabolism and Vascular Function Arterioscler Thromb Vasc Biol, April 1, 2002; 22(4): 549 - 553. [Abstract] [Full Text] [PDF]
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