Aortic permeability to LDL as a predictor of aortic cholesterol accumulation in cholesterol-fed rabbits.

Nielsen, Lars Bo; Nordestgaard, Børge G.; Stender, Steen; Kjeldsen, Knud

doi:10.1161/01.atv.12.12.1402

Cited by 62 publications

(45 citation statements)

References 32 publications

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“…This approach enabled us to precisely manipulate the compositions of the perfusate and superfusate solutions and carefully control arterial flow and hydrostatic pressure, hemodynamic parameters known to influence LDL flux into the artery wall. 7,8,37 The approach that we have taken enabled us to study the mechanisms of LDL flux into the artery wall and is a bridge between previous in vitro and cell culture experiments and experiments performed on whole-animal preparations. 5,18,38 The literature suggests that LDL is primarily modified in the arterial wall because of the large antioxidant capacity of the blood.…”

Section: Discussionmentioning

confidence: 99%

“…[1][2][3] Sites of relative increase in LDL permeability have been identified in normal arteries 4 and can be induced by injury to the endothelium. [5][6][7][8][9] Alternatively, others have reported increased binding and decreased efflux of LDL from the vascular wall, even under conditions where LDL influx was not affected. 10,11 Therefore, LDL accumulation in the artery wall potentially occurs by several mechanisms, perhaps depending on the stage of atheroma formation.…”

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confidence: 99%

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Modified LDL–Mediated Increases in Endothelial Layer Permeability Are Attenuated With 17β-Estradiol

Gardner

Banka

Roberts

et al. 1999

ATVB

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Abstract-Current research suggests that estrogen may have primary effects on the artery wall. To investigate the mechanisms of female sex hormone actions in the artery wall, we used an isolated, perfused, rat carotid artery model to examine the effects of estradiol on the rates of accumulation of normal (N-LDL) and minimally modified (MM-LDL) low density lipoprotein in ovariectomized rats. N-LDL, MM-LDL, and oxidized LDL (OX-LDL) were fluorescently labeled and perfused into individual arteries. The rate of LDL accumulation was measured by quantitative fluorescence microscopy before and after treatment with estradiol (1 nmol/L, 272 pg/mL). Estradiol had no effect on the rate of Key Words: artery Ⅲ arteriosclerosis Ⅲ LDL Ⅲ estrogen Ⅲ oxidized LDL Ⅲ endothelium Ⅲ permeability A cardinal characteristic of the development of atherosclerosis is the accumulation of LDL within the arterial wall. 1-3 Sites of relative increase in LDL permeability have been identified in normal arteries 4 and can be induced by injury to the endothelium. 5-9 Alternatively, others have reported increased binding and decreased efflux of LDL from the vascular wall, even under conditions where LDL influx was not affected. 10,11 Therefore, LDL accumulation in the artery wall potentially occurs by several mechanisms, perhaps depending on the stage of atheroma formation.A large body of evidence indicates that modification of LDL in the artery wall promotes atherosclerosis. 12 Recent studies demonstrate evidence of modification of LDL in the blood. [13][14][15][16][17] Furthermore, a previous study showed increased accumulation and degradation of oxidized LDL (OX-LDL) in the artery wall in vivo. 18 These studies suggest that the reason there is increased accumulation and degradation of OX-LDL is because arterial permeability to undegraded, OX-LDL is greater than arterial permeability to native LDL (N-LDL). However, the precise mechanism(s) by which modified LDL (MM-LDL) affects LDL flux in the artery wall, such as increases in permeability to LDL, remains incompletely understood.Modification of LDL (eg, oxidation), either in the circulation or the artery wall, could promote atherosclerosis by increasing LDL accumulation in the artery. Also, alteration of constituents of the artery wall, such as proteoglycans, could influence LDL binding to the artery wall. Furthermore, oxidant-mediated injury of endothelial cell membranes could compromise the endothelial layer barrier to macromolecules in arteries. 5 To counteract oxidant stress effects on LDL and/or the artery wall, a number of potential antioxidants have been examined. In particular, some estrogens (eg, 17␤-estradiol) are known to reduce LDL accumulation in the artery wall 19,20 and to be potent antioxidants. [21][22][23] In addition, estrogens may protect endothelial cells from oxidative damage. 21,22 This action would be expected to prevent increased LDL permeation into the artery wall. Furthermore, estradiol has been shown to inhibit LDL oxidation in vivo at supraphysiological 24 and physiolo...

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Modified LDL–Mediated Increases in Endothelial Layer Permeability Are Attenuated With 17β-Estradiol

Gardner

Banka

Roberts

et al. 1999

ATVB

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“…However, it is disturbing that an increased accumulation due to lipoprotein binding would lead to a flattening of the uptake-versus-time curve, which would give too low rather than too high an estimate of the fractional loss. One way to reconcile these observations is to introduce a "very fast equilibrating pool" or to adopt the concept of plasma contamination 23 ( Figure 5). This would lead to high uptake at early (3 hours) time points, thus restoring the shape of the curve, whereby the 2 types of errors might actually tend to cancel each other.…”

Section: Discussionmentioning

confidence: 99%

Direct Assessment of Lipoprotein Outflow From In Vivo–Labeled Arterial Tissue as Determined in an In Vitro Perfusion System

Björnheden¹,

Bondjers²,

Wiklund³

1998

ATVB

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Abstract-The rate of cholesterol deposition during the atherosclerotic process is determined by the balance between the inflow and outflow of plasma lipoproteins in the arterial wall. Whereas the rate of inflow may be measured directly, the rate of outflow has most often been calculated indirectly from lipoprotein uptake by using the 2-compartment model. One objection against such calculations is that lipoprotein binding is not being considered. In the present study 2 different protocols were used to obtain a direct measure of the outflow of lipoproteins from atherosclerotic rabbit aortas. Thus, 3 rabbits with experimental atherosclerosis were given 125 I-LDL intravenously and 3 were given [ 14 C]cholesterol perorally. Twenty-four hours later the aortas were removed and the outflow of label was monitored during in vitro perfusion. Despite the different protocols, our results were consistent and indicated that fractional loss relative to whole tissue was Ϸ0.01 pool/h, which is 1 order of magnitude lower than current estimates based on the 2-compartment model (0.04 to 0.4 pool/h). Furthermore, whereas as much as 2 ⁄3 to 3 ⁄4 of the tracer that had entered the arterial wall was effectively trapped, the remainder equilibrated at a faster rate (0.06 pool/h). In conclusion, it seems that tissue binding constitutes a prominent and possibly underrated mechanism of lipoprotein deposition, at least in the atherosclerotic rabbit aorta. Furthermore, this means that current estimates of lipoprotein exchange parameters based on the 2-compartment model (eg, fractional loss) may rest on invalid assumptions and should be regarded with caution.

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“…9 Still, arterial geometry and pressure are not sufficient to explain the localization of lesions, since major areas of high risk for atherosclerosis also occur away from the ostia and bifurcations 10 and some arteries subjected to normal arterial blood pressure are little affected by atherosclerosis. 3 -3 In fact, studies with experimental animals have demonstrated that low-density lipoprotein (LDL) metabolism, 11 endothelial permeability to LDL, 12 the glycoprotein coating of endothelial cells, 13 and the activity of acid cholesterol esterase 14 vary among vessels, and this variation could be related to differences in atherosclerosis susceptibility. A further aspect of arterial constitution that has been correlated with regional differences in the incidence of atherosclerosis is the degree of folding of the internal elastic membrane in humans, 15 which somehow reflects the amount of elastin in the vessel wall.…”

Section: ;1:115-124)mentioning

confidence: 99%

Glycosaminoglycan fractions from human arteries presenting diverse susceptibilities to atherosclerosis have different binding affinities to plasma LDL.

Cardoso

Mourāo

1994

Arterioscler Thromb

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The topographic distribution of atherosclerotic lesions is influenced by biochemical factors intrinsic to the arterial wall. In the present work we have investigated whether the composition/chemical structure of glycosaminoglycans constitutes one of these factors. Normal human arteries were obtained at necropsy, and in order of decreasing susceptibility to atherosclerosis, consisted of the abdominal and thoracic aortas and the iliac and pulmonary arteries. The results showed similar concentrations of total glycosaminoglycan and collagen. Of the glycosaminoglycans known to interact with low-density lipoprotein (LDL), dermatan sulfate was present in all arteries in comparable concentrations, but the aortas had a 30% higher content of chondroitin 4/6-sulfate, which in turn was slightly enriched in 6-sulfated disaccharide units. LDLaffinity chromatography with dermatan sulfate+chondroitin 4/6-sulfate fractions demonstrated that increasing affinity to LDL matched an increasing susceptibility to atherosclerosis. Analysis of glycosaminoglycans in the eluates indicated a positive correlation between affinity to LDL and increasing molecular weight and the existence of a fraction of glycosaminoglycans of high affinity to LDL in the aortas only. These results suggest that arterial glycosaminoglycans participate in the multifactorial mechanisms that modulate the differential localization of atherosclerotic lesions. 1 However, factors intrinsic to the arterial bed and its bloodcarrying functions also influence the occurrence of lesions. The primary evidence came from morphological study of necropsy material, which demonstrated that the incidence and/or severity of atherosclerotic lesions differed as a function of anatomic location.2 -3 Additionally, these studies revealed that in affected arteries, lesions tended to be located at critical sites, such as the entrances of vessels and flow dividers, where the effects of fluid turbulence would be more pronounced. Experimental physiological investigations have supported these findings 68 and have shown that the shear force due to blood circulation, chiefly at arterial pressures, is an important cause of endothelial dysfunction at these sites. 9 Still, arterial geometry and pressure are not sufficient to explain the localization of lesions, since major areas of high risk for atherosclerosis also occur away from the ostia and bifurcations 10 and some arteries subjected to normal arterial blood pressure are little affected by atherosclerosis. and the activity of acid cholesterol esterase 14 vary among vessels, and this variation could be related to differences in atherosclerosis susceptibility. A further aspect of arterial constitution that has been correlated with regional differences in the incidence of atherosclerosis is the degree of folding of the internal elastic membrane in humans, 15 which somehow reflects the amount of elastin in the vessel wall.Taken together, the results of these mostly recent studies show that focal metabolic and biochemical factors inherent in...

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Aortic permeability to LDL as a predictor of aortic cholesterol accumulation in cholesterol-fed rabbits.

Cited by 62 publications

References 32 publications

Modified LDL–Mediated Increases in Endothelial Layer Permeability Are Attenuated With 17β-Estradiol

Modified LDL–Mediated Increases in Endothelial Layer Permeability Are Attenuated With 17β-Estradiol

Direct Assessment of Lipoprotein Outflow From In Vivo–Labeled Arterial Tissue as Determined in an In Vitro Perfusion System

Glycosaminoglycan fractions from human arteries presenting diverse susceptibilities to atherosclerosis have different binding affinities to plasma LDL.

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