UMLS:C0004153 - FACTA Search

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Query: UMLS:C0004153 (atherosclerosis)
77,401 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

1. Endothelial dysfunction and vascular smooth muscle cell (VSMC) proliferation are key events in the pathogenesis of atherosclerosis. Vascular permeability factor (VPF), an endothelial-cell-specific multifunctional cytokine, was recently described, and has the potential to contribute to the development of endothelial dysfunction. The present study determines whether cultured human VSMCs express mRNA for VPF and whether VPF mRNA expression is influenced by human VSMC proliferation. 2. A 204 bp cDNA fragment, specific for all known variants of VPF mRNA, was cloned and used to demonstrate that human VSMCs express abundant quantities of VPF mRNA, whereas human endothelial cells do not. VPF mRNA levels were markedly diminished in non-proliferating human VSMCs. In contrast, when human VSMCs were stimulated to proliferate by exposure to serum, there was a rapid 6.6-fold increase (P < 0.01 versus time 0 h) in VPF mRNA expression, which was maximal at 3 h and persisted beyond 24 h. The magnitude of the VPF mRNA response in human VSMCs was dependent on the serum concentration. 3. Platelet-derived growth factor also increased VPF mRNA expression by human VSMCs, thus confirming that recognized growth factors for VSMCs also potently influence the VPF gene. 4. In conclusion, VPF mRNA is expressed by human VSMCs, the magnitude of VPF expression being temporally related to the proliferation of human VSMCs and the potency of the growth-promoting stimulus. We propose that VPF produced by proliferating human VSMCs could act as a paracrine hormone to powerfully influence the permeability and growth of the overlying vascular endothelium.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Serum and platelet-derived growth factor-induced expression of vascular permeability factor mRNA by human vascular smooth muscle cells in vitro. 772 Mar 37

Hyperhomocysteinaemia, defined as an abnormally high plasma homocysteine concentration after an oral methionine load, is common in young (< or = 50 years) patients with peripheral arterial occlusive disease. It is thought to predispose to atherosclerosis by injuring the vascular endothelium. Treatment with pyridoxine and/or folic acid may lower plasma homocysteine levels. In mildly hyperhomocysteinaemic patients with peripheral arterial occlusive disease, we studied the effect of daily treatment with pyridoxine (250 mg) plus folic acid (5 mg) on homocysteine metabolism (i.e. plasma concentrations in the fasting state and after methionine loading, in 48 patients) and on endothelial function (in 18 patients). Endothelial function was estimated as the plasma concentrations of the endothelium-derived proteins, von Willebrand factor (vWF), thrombomodulin (TM), and tissue-type plasminogen activator (tPA). At baseline, fasting homocysteine levels were above normal in 24 of the 48 patients (50%); post-load levels, by definition, were above normal in 100% of patients. After 12 weeks of treatment, fasting and post-load levels were normal in 98 and 100% of patients, respectively. Endothelial function was assessed in 18 patients who completed 1 year of treatment. At baseline, median vWF (235%) and TM (57.1 ng mL-1) levels were above normal. At follow-up, vWF levels had decreased to 170% (P = 0.01) and TM levels had decreased to 49 ng mL-1 (P = 0.04). tPA levels were normal at baseline and did not change. Endothelial dysfunction is present in young patients with peripheral arterial occlusive disease and hyperhomocysteinaemia. Pyridoxine plus folic acid treatment normalizes homocysteine metabolism in virtually all patients, and appears to ameliorate endothelial dysfunction.
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PMID:Hyperhomocysteinaemia and endothelial dysfunction in young patients with peripheral arterial occlusive disease. 778 64

Patients with glycogen storage disease type 1 (GSD-1) often have marked hyperlipidaemia with abnormal lipoprotein profiles. This metabolic abnormality improves, but is not fully corrected, with dietary therapy and therefore these patients may be at high risk for the development of atherosclerosis. Endothelial dysfunction is an early event in atherogenesis and can be detected in children and young adults at high risk. We studied endothelial function, using a non-invasive ultrasonographic method, in the brachial arteries of 6 adult GSD-1a patients (aged 23-33 years) with mean cholesterol of 7.9 mmol/l (range 4.7 to 14.6) and mean triglycerides of 9.1 mmol/l (range 4.1 to 21.3), and 12 age- and sex-matched normolipidaemic controls. Flow-mediated (endothelium-dependent) dilation was similar in patients and controls (8.2% vs. 10.5%; P = 0.20). Although the patient numbers are small, these results are consistent with the surprising lack of clinically evident atherosclerosis in GSD-1. The reasons these patients appear less susceptible to the damaging arterial effects of hyperlipidaemia are unknown. These results may have implications for others with secondary hyperlipidaemias.
Atherosclerosis 1994 Sep 30
PMID:Hyperlipidaemia does not impair vascular endothelial function in glycogen storage disease type 1a. 785 75

Atherosclerosis is characterized by hypertrophy of the vascular media, intimal thickening and lipid-containing plaques. Atherosclerosis is a progressive systemic vascular disease which leads to impaired tissue perfusion due to vascular obstruction. In advanced stages it is often complicated by thrombosis. Recent research demonstrates that atherosclerosis is also a functional disease. In atherosclerosis and hypercholesterolemia, normal vasodilatation is impaired due to endothelial dysfunction. In addition, the ability of the vessel wall to reject adhering and aggregating platelets is deteriorated. Endothelial dysfunction in atherosclerosis is characterized by impaired formation of nitric oxide (NO), formerly known as endothelium-derived relaxing factor (EDRF). NO is continuously formed in the vascular endothelium and promotes tissue perfusion by relaxation of vascular smooth muscle. Endogenously formed NO may also protect against foam cell formation and media hypertrophy, i.e. against the structural component of atherosclerosis. In patients with ischaemic heart disease, the endothelial dysfunction leads to decreased ability to dilate the coronary vessels in response to several forms of physiological stimuli. Endothelial dysfunction in atherosclerosis is reversed by lipid-lowering therapeutic interventions.
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PMID:Nitric oxide (NO) in the cardiovascular system: role in atherosclerosis and hypercholesterolemia. 786 90

To understand the process of atherosclerosis, the homeostatic and protective functions of the endothelium must be considered. The endothelium serves as the interface between blood flow and the vascular tissues. It normally regulates vascular tone and structure through the release of vasoactive substances and maintenance of a nonthrombogenic surface. Endothelial dysfunction, which results from biochemical and hemodynamic stresses associated with cardiovascular risk factors, causes an imbalance in the expression of vasodilating and vasoconstricting substances, as well as excess production of chemoattractant molecules and growth factors. Endothelial dysfunction in the presence of elevated cholesterol levels fosters the development of fatty streaks, which represent the early stage of atherosclerotic plaque. The unstable progression of atherosclerosis can be interrupted and even reversed in both animals and humans, although the exact clinical correlates of progression and regression are not fully understood.
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PMID:Pathobiology of atherosclerosis and plaque complications. 797 10

Nitric oxide (NO) is now considered as the endogenous nitrovasodilator which is mainly derived from vascular endothelial cells in physiological conditions. Biosynthesis of NO is controlled by a family of enzymes, the NO synthases (NOS), that can be divided into two major subgroups, namely the constitutive and the inducible NOS. The constitutive NOS is the principal isoform found in endothelial cells. Endothelial dysfunction, as seen in chronic hypoxic lung diseases, impairs endogenous production of NO, thereby causing and/or aggravating pulmonary hypertension. A logical means to reduce pulmonary hypertension would consist in supplying the patients with exogenous NO. Given by inhalation, NO is a selective pulmonary vasodilator, as it rapidly combines with haemoglobin, which inactivates NO, and therefore prevents the occurrence of systemic hypotension. Endothelial dysfunction resulting in reduced NO synthesis is also likely to account for various cardiovascular disorders, including essential hypertension and coronary atherosclerosis. However, the importance of endogenous NO in the modulation of bronchial tone remains to be established. Current investigations include studies looking at regulatory mechanisms of cellular expression of various NOS isoforms on the one hand and, on the other hand, clinical evaluation of short- and long-term inhalation of NO in patients with primary and secondary pulmonary hypertension.
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PMID:[Role of NO in cardiovascular and respiratory physiology]. 800 51

Our appreciation of the vascular endothelium has changed considerably over the last decade. This organ, finally recognized as such, participates actively in vasomotor regulation and haemostasis. It secretes several relaxing and contracting factors which act locally to determine resting vascular tone. One of the relaxing factors, EDRF/NO plays an important physiological role as it contributes to the rapid adaptation of blood flow to various pharmacological and mechanical stimuli, thereby ensuring maintenance of adequate tissue perfusion. Nitric oxide (NO) is an ubiquitous factor which was crowned "molecule of the year 1992" by the scientific review Science. Its effects extend well beyond those on the cardiovascular system. Endothelial dysfunction is observed in many pathological states such as atherosclerosis, reperfusion injury, postangioplasty endothelial regeneration, degeneration of venous bypass grafts, pure spastic angina, hypertension and diabetes. It is associated with decreased production of EDRF/NO, which probably contributes significantly to the aggravation of endothelial and parietal lesions and to the natural progression of atherosclerotic disease in general. This article describes the principal vasoactive factors secreted by the endothelium and goes on to list the physiologic cardiovascular effects of EDRF/NO in detail, and to review the different pathologies associated with a disorder of secretion of this factor.
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PMID:[EDRF/NO and endothelial functions]. 801 Aug 61

The vascular endothelium is the site of formation of several powerful mediators. One of these is NO, a chemically unstable radical formed by enzymatic conversion of L-arginine in the presence of molecular oxygen. NO elicits relaxation of VSMC by activating cytosolic guanylate cyclase. NO also counteracts platelet adhesion and aggregation. The biological actions of NO make it a key substance in the endogenous defense against vascular occlusion and thrombosis. The basal formation of NO maintains a moderate but significant vasodilation in the systemic resistance vessels and counteracts platelet activity. When blood flow in conduit arteries is increased there is an augmented endothelial formation of NO, eliciting flow-dependent vasodilation. Beside this, several vasodilators (acetylcholine, bradykinin, histamine, substance P) operate by stimulating endothelial NO formation. On the other hand, drugs like nitroglycerin and papaverine operate independently of the vascular endothelium. Vasodilator mechanisms, physiological as well as pharmacological, may therefore be characterized as endothelium-dependent (i.e. NO-mediated), or endothelium-independent (i.e. not mediated by NO). Physiologically, mixed mechanisms occur. Failure of the vascular endothelium to elicit NO-mediated vasodilatation may be due to decreased formation, increased degradation, decreased sensitivity to the NO formed, or a mixture of these factors. Irrespective of the mechanism behind, this is referred to as endothelial dysfunction. Endothelial dysfunction occurs in several cardiovascular settings, like atherosclerosis, hypercholesterolaemia, diabetes, and essential hypertension. Endothelial dysfunction leads to an impaired tissue perfusion, increased local vascular resistance, decreased defense against thrombus formation, and possibly also decreased defense against hypertrophy of the VSMC in the vessel wall media. In patients with CHD, endothelial dysfunction leads to an impaired coronary flow response to physical and mental stress, and to promotion of platelet adherence and aggregability. Endothelial dysfunction is thereby a probable aggravating factor in the atherosclerotic process, adding a functional component on top of the structural lesions characterizing this disease. A particular form of endothelial dysfunction, limited to the arterial resistance vessels, may explain the symptoms and clinical characteristics of microvascular angina. In patients with essential hypertension, endothelial dysfunction prevails, adding a functional component to the structural factors also in this disease. Hitherto, the only therapeutic tools available to restore endothelial dysfunction appear to be restriction of the dietary intake of lipids, possibly reinforced with intake of antioxidants like fish oil and vitamin E. However, large clinical trials to confirm the efficacy of such therapy in reversing endothelial dysfunction have not been conducted. In the future, more directly acting therapeutic regimens, aimed at supporting or substituting the endogenous formation of NO, are likely to appear as well.
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PMID:Endothelial nitric oxide and cardiovascular disease. 815 Dec 63

The endothelium regulates vascular tone by releasing factors involved in relaxation and contraction, in coagulation and thrombus formation, and in growth inhibition and stimulation. Endothelium-dependent relaxations are elicited by transmitters, hormones, platelet substances, and the coagulation system, and by physical stimuli such as the shear stress from circulating blood. They are mediated by the endothelium-derived relaxing factor, recently identified as nitric oxide, which causes vasodilation and platelet deactivation. Other proposed endothelium-derived relaxing factors include a hyperpolarizing factor, lipooxygenase products, and the cytochrome P450 pathway. Endothelium-derived contracting factors are produced by the cyclooxygenase pathway and by endothelial cells, which produce the peptide endothelin-1, a potent vasoconstrictor that under normal conditions circulates at low levels. The endothelium produces both growth inhibitors--normally dominant--and growth stimuli. Denuded or dysfunctional endothelium leads to a proliferative response and intimal hyperplasia in the vessel wall; moreover, platelets adhere to the site and release potent growth factors. Endothelial dysfunction has numerous causes: Aging is associated with increased formation of contracting factor and decreased relaxing factor; denudation, such as by coronary angioplasty, impairs the capacities of regenerated endothelial cells; oxidized low-density lipoproteins and hypercholesterolemia interfere with nitric oxide production; hypertension morphologically and functionally alters the endothelium; and atherosclerosis markedly attenuates some endothelium-dependent relaxations. For patients with coronary bypass grafts, differences in endothelium-derived vasoactive factors between the internal mammary artery and the saphenous vein may be important determinants of graft function, with the mammary artery having more pronounced relaxations than the saphenous vein and thus a higher patency rate.
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PMID:Endothelial regulation of vascular tone and growth. 839 13

We examined whether coronary risk factors and atherosclerotic lesions in the study artery were associated with impaired endothelium-dependent dilation of coronary resistance arteries. Acetylcholine (ACH) at graded doses (1, 3, 10 and 30 micrograms/min) and papaverine (10 mg) were selectively infused into the left anterior descending coronary artery of 28 patients, in whom the study artery was angiographically normal (n = 16) or with mild stenosis < or = 40% (n = 12). Coronary blood flow (CBF) was estimated from the product of mean CBF velocity measured by an intracoronary Doppler catheter and the arterial cross-sectional area of the study artery determined by quantitative arteriography. ACH increased CBF in a dose-dependent manner. However, the maximum CBF response to ACH varied widely among patients (from 50% to 660%). By multivariate analysis, the presence of atherosclerotic lesions in the study artery was an independent predictor for impaired CBF response to ACH (P < 0.01). Hypertension (P < 0.001), hypercholesterolemia (r = -0.52, P < 0.005), age > or = 50 yr (P < 0.01) and total number of coronary risk factors (r = -0.62, P < 0.001) were associated with the impaired increase in CBF with ACH by univariate analysis. The percent increase in CBF evoked with papaverine did not correlate with these risk factors. The results suggest that mild atherosclerotic lesions in the study artery and coronary risk factors are accompanied by impaired endothelium-dependent dilation of coronary resistance arteries evoked with ACH. Endothelial dysfunction of coronary resistance arteries may result in altered regulation of myocardial perfusion in patients with mild coronary atherosclerosis and coronary risk factors.
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PMID:Impaired coronary blood flow response to acetylcholine in patients with coronary risk factors and proximal atherosclerotic lesions. 842 26

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