Eberhard von Hodenberg

Attenuated Progression of Coronary Artery Disease After 6 Years of Multifactorial Risk Intervention Role of Physical Exercise

BACKGROUND It was the aim of this study to assess the long-term effects of physical exercise and low-fat diet on the progression of coronary artery disease. At the beginning of the study, 113 male patients with coronary artery disease were randomized to an intervention group (n=56) or a control group (n=57); 90 patients (80%) could be reevaluated after 6 years. METHODS AND RESULTS Patients in the intervention group (n=40) showed a reduction in total serum cholesterol (6.03+/-1.03 versus 5.67+/-1.01 mmol/L; P<.03) and triglyceride levels (1.94+/-0.8 versus 1.6+/-0.89 mmol/L; P<.005) and maintained their initial body mass index (26+/-2 versus 27+/-2 kg/m2; P=NS), but results were not statistically different from the control group (n=50) (total serum cholesterol, 6.05+/-1.02 versus 5.79+/-0.88 mmol/L; triglycerides, 2.25+/-1.28 versus 1.85+/-0.96 mmol/L [both P=NS]; body mass index, 26+/-2 versus 28+/-3 kg/m2 [P<.0001]). In the intervention group, there was a significant 28% increase in physical work capacity (166+/-59 versus 212+/-89 W; P<.001), whereas values remained essentially unchanged in the control group (165+/-51 versus 170+/-60 W; P=NS; between groups, P<.05). In the intervention group, coronary stenoses progressed at a significantly slower rate than in the control group (P<.0001). Energy expenditure during exercise was assessed in a subgroup; patients with regression of coronary stenoses spent an average of 1784+/-384 kcal/wk (approximately 4 hours of moderate aerobic exercise per week). Multivariate regression analysis identified only physical work capacity as independently contributing to angiographic changes. CONCLUSIONS After 6 years of multifactorial risk intervention, there is significant and persistent improvement in lipoprotein levels and physical work capacity, which results in a significant retardation of disease progression. These beneficial effects appear to be largely due to chronic physical exercise.

Low-Dose Radioactive Endovascular Stents Prevent Smooth Muscle Cell Proliferation and Neointimal Hyperplasia in Rabbits

BACKGROUND Restenosis induced by smooth muscle cell (SMC) migration and proliferation and neointimal thickening limits the clinical success of balloon angioplasty and stent implantation. In this study, the long-term effect of endovascular irradiation via low-dose radioactive stents on neointima formation was compared with conventional stent implantation in a rabbit model. METHODS AND RESULTS Palmaz-Schatz stents were made radioactive in a cyclotron. The stents had a very low activity (maximum, 35 microCi), and thus, manipulation did not require extensive radiation protection. One, 4, 12, and 52 weeks after the implantation of nonradioactive stents and radioactive stents in rabbit iliac arteries, neointimal thickening was analyzed by quantitative histomorphometry. Immunostaining for endothelial cell von Willebrand factor, macrophages, SMC alpha-actin, collagen type I, and proliferating cell nuclear antigen (PCNA) was performed to determine radiation-induced changes in the arterial wall. SMC proliferation was quantified by computer-assisted cell counting of PCNA-immunoreactive cells. Neointima formation was markedly suppressed by the implantation of radioactive stents in a dose-dependent fashion at all observed time points. At peak proliferative activity of SMCs 1 week after nonradioactive stent implantation, 30 +/- 2% of SMCs in the neointima were proliferating, compared with 0.5 +/- 0.1% of SMCs after implantation of stents with an initial activity of 35 microCi (P < .001). The neointima covering radioactive stents was characterized by decreased smooth muscle cellularity and increased extracellular matrix formation. Further, we observed a delayed endothelialization depending on the radiation dose. No difference in vascular thrombosis was found after nonradioactive and radioactive stent implantation. CONCLUSIONS The results of this study clearly indicate that low-dose radioactive endovascular stents potently inhibit SMC proliferation and neointimal hyperplasia in rabbits.

Chemotaxis of the monocyte cell line U937: dependence on cholesterol and early mevalonate pathway products

In the present study we investigated the influence of cholesterol depletion and hydroxymethylglutaryl-coenzyme A reductase (HMG-CoA reductase) inhibition on chemotaxis of the human monocytic cell line U937. Chemotaxis was nearly completely depressed after incubation for 24 h in the absence of lipoproteins. This was accompanied by a significant decrease in cellular cholesterol. Addition of 10 micrograms/ml low density lipoprotein (LDL) for 2 h to the cholesterol-depleted cells restored chemotaxis. Free cholesterol had no effect under these conditions. Inhibition of HMG-CoA reductase by pravastatin (0.01-1.0 mM) for 20 or 72 h also reduced chemotaxis. However, this effect was not accompanied by a decrease in cellular cholesterol when cells were grown in the presence of lipoproteins. The effect of pravastatin could be reversed by the addition of mevalonate. Addition of LDL did not change the response to pravastatin. We propose that the availability of cholesterol plays an important role in cellular chemotaxis. Furthermore, it can be suggested that other products of the mevalonate pathway apart from cholesterol may contribute to the regulation of chemotaxis.

LDL Stimulates Chemotaxis of Human Monocytes Through a Cyclooxygenase-Dependent Pathway

Monocyte migration into the vessel wall is an early step in atherogenesis. Even though a number of chemotactic factors have been identified, the regulation of the chemotactic response is not clearly understood. As the release of arachidonic acid has been implicated in monocyte chemotaxis, we studied the influence of LDL, which can supply this fatty acid to cells, on the chemotactic mobility of monocytes. Migration of human monocytic U937 cells was abolished by a 30-hour incubation in medium containing lipoprotein-depleted 10% fetal calf serum. Thereafter, human VLDL, LDL, acetyl LDL, methyl LDL, HDL, free cholesterol, linoleic acid, oleic acid, or arachidonic acid was added. At the end of varying incubation periods (0.5 to 8 hours), chemotaxis, viability, and cellular cholesterol content were measured. In the same experimental setting we also studied the effects of the pharmacological agents chloroquine, indomethacin, and acetylsalicylic acid on LDL-mediated chemotaxis. Chemotaxis was restored by LDL in a dose- and time-dependent manner starting at concentrations as low as 5 micrograms/mL and at incubations as brief as 30 minutes. The other lipoproteins tested (VLDL, HDL, acetyl LDL, and methyl LDL) as well as free cholesterol had no comparable effect on chemotaxis. Viability and total cholesterol content did not differ among the groups. Simultaneous incubation of cells with chloroquine, indomethacin, and acetylsalicylic acid reduced restitution of chemotaxis by LDL by 71%, 82%, and 68%, respectively. In contrast, the agents had only slight inhibitory effects on the chemotactic mobility of serum-fed control cells. Incubation with linoleic acid showed a 60% restoration of chemotaxis, whereas arachidonic acid stimulated chemotaxis by 140% compared with the positive control. Preincubation of LDL with the monoclonal antibody MB47 directed against LDL resulted in a significantly reduced migratory response. The data suggest a novel cyclooxygenase-dependent regulatory mechanism of chemotaxis by LDL.

Effects of lipoprotein (a) on success rate of thrombolytic therapy in acute myocardial infarction

Lipoprotein (a) [Lp(a)] and plasminogen share a high degree of homology as recently evidenced by amino acid and deoxyribonucleic acid analysis. As Lp(a) is enzymatically inactive, it has been suggested that high levels of Lp(a) may suppress the profibrinolytic activity at the cell surface and increase the risk for arteriosclerosis and thrombosis by competitive inhibition of plasminogen. The present study evaluated whether high levels of Lp(a) influence thrombolytic therapy in patients with acute myocardial infarction. Forty-one patients with acute myocardial infarction received a combination low-dose thrombolytic therapy with recombinant tissue-type plasminogen activator (rt-PA) and human single-chain urokinase-type plasminogen activator (scu-PA). This regimen did not induce plasminemia or a lytic state as indicated by well-maintained levels of fibrinogen. Coronary patency was assessed angiographically 90 minutes after initiation of treatment. Thrombolysis was successful in 30 and unsuccessful in 11 patients. Patients with high Lp(a) levels (greater than or equal to 25 mg/dl) (n = 9) responded equally well to thrombolytic therapy (8 of 9, patency 89%) as did patients with normal or low levels of Lp(a) (22 of 32, patency 70%, difference greater than 0.1). Lp(a) levels did not differ significantly between patients with successful and unsuccessful thrombolysis. Our results demonstrate that high levels of Lp(a) do not affect thrombolysis in patients with acute myocardial infarction when low-dose pharmacologic concentrations of rt-PA and scu-PA are applied in combination.

Cholesterol efflux from macrophages mediated by high-density lipoprotein subfractions, which differ principally in apolipoprotein A-I and apolipoprotein A-II ratios

High-density lipoprotein (HDL) was fractionated by preparative isoelectric focussing into six distinct subpopulations. The major difference between the subfractions was in the molar ratio of apolipoprotein A-I to apolipoprotein A-II, ranging from 2.1 to 0.5. The least acidic particles had little apolipoprotein A-II, were larger and contained the most lipid. The efflux capacity of the HDL subfractions was tested with mouse peritoneal macrophages and a mouse macrophage cell line (P388D1), either fed with acetylated low-density lipoprotein or free cholesterol. All the HDL subfractions were equally able to efflux cholesterol. The efflux was concentration dependant and linear for the first 6 h. The HDL subfractions bound with high affinity (Kd = 6.7-7.9 micrograms/ml) at 4 degrees C to the cell surface of P388D1 cells (211,000-359,000 sites/cell). Ligand blotting showed that all the HDL subfractions bound to membrane polypeptides at 60, 100, and 210 kDa. These HDL binding proteins may represent HDL receptors. In summary HDL particles, which differed principally in ratio of apolipoprotein A-I to apolipoprotein A-II behaved in a similar manner for both cholesterol efflux and cell surface binding.

Variation in the human soluble epoxide hydrolase gene and risk of restenosis after percutaneous coronary intervention

BackgroundRestenosis represents the major limiting factor for the long-term efficacy of percutaneous coronary intervention (PCI). Several genetic factors involved in the regulation of the vascular system have been described to play a role in the pathogenesis of restenosis. We investigated whether the EPHX2 K55R polymorphism, previously linked to significantly higher risk for coronary heart disease (CHD), was associated with the occurrence of restenosis after PCI. The association with incident CHD should have been confirmed and a potential correlation of the EPHX2 K55R variant to an increased risk of hypertension was analysed.MethodsAn overall cohort of 706 patients was studied: This cohort comprised of 435 CHD patients who had undergone successful PCI. Follow-up coronary angiography in all patients was performed 6 months after intervention. Another 271 patients in whom CHD had been excluded by coronary angiography served as controls. From each patient EDTA-blood was drawn at the baseline ward round. Genomic DNA was extracted from these samples and genotyping was performed by real-time PCR and subsequent melting curve analysis.ResultsIn CHD patients 6 month follow-up coronary angiography revealed a restenosis rate of 29.4%, classified as late lumen loss as well as lumen re-narrowing ≥ 50%.Statistical analysis showed an equal genotype distribution in restenosis patients and non-restenosis patients (A/A 82.0% and A/G + G/G 18.0% versus A/A 82.1% and A/G + G/G 17.9%). Moreover, neither a significant difference in the genotype distribution of CHD patients and controls nor an association with increased risk of hypertension was found.ConclusionThe results of the present study indicate that the EPHX2 K55R polymorphism is not associated with restenosis after PCI, with incidence of CHD, or with an increased risk of hypertension and therefore, can not serve as a predictor for risk of CHD or restenosis after PCI.

Effects of lipoprotein(a) on thrombolysis

Lipoprotein(a) (Lp(a)) and plasminogen share a high degree of structural homology. Therefore it has been suggested that elevated levels of Lp(a) may inhibit the profibrinolytic activity at the cell surface and increase the risk of thrombosis by competitive inhibition of plasminogen. In the present study we evaluated whether high levels of Lp(a) affect thrombolytic therapy in patients with acute myocardial infarction. Forty-one patients with acute myocardial infarction were treated with a combination of recombinant tissue-type plasminogen activator and human single-chain urokinase-type plasminogen activator. Coronary patency was assessed angiographically 90 min after initiation of treatment. Thrombolysis was successful in 30 and unsuccessful in 11 patients. Patients with high Lp(a) levels (> 25 mg/dl) (n = 9) responded equally well to thrombolytic therapy (8 of 9, patency 89%) as did patients with normal or low levels of Lp(a) (22 of 32, patency 70%, difference P > 0.1). The results demonstrate that high levels of Lp(a) do not influence thrombolysis in patients with acute myocardial infarction when low-dose pharmacologic concentrations of recombinant tissue-type plasminogen activator and human single chain urokinase-type plasminogen activator are applied in combination.

The role of apolipoproteins in lipid metabolism and atherogenesis: aspects in man and mice

Abnormal levels of plasma lipoproteins are associated with an increased risk of coronary heart disease. Besides dietary factors, multiple genetic defects responsible for dyslipoproteinaemia have been identified. The best-characterized example of a genetic defect causing hyperlipidaemia resulting in premature atherosclerosis is familial hypercholesterolaemia [1]. Patients with this disease have a mutation of the low-density lipoprotein-receptor gene, leading to extensive coronary heart disease at a very young age in homozygotes [1]. Other defects causing dyslipidaemia can include mutations of the genes for apoproteins, transport proteins and enzymes involved in lipoprotein metabolism. Several extensive reviews describe the function of these proteins and the various mutations of the corresponding genes with respect to their influence on atherogenesis [2–7].

Cellular Interactions in Atherogenesis

The very early atherosclerotic lesion (fatty streak) as well as advanced lesions consist of functionally altered endothelial cells, differentiated macrophages, activated T-lymphocytes, and proliferating smooth muscle cells (Ross 1986; Schwartz et al. 1991). These cells are able to secrete multiple biologically active molecules. By means of these mediators the cells can interact with each other, affecting the state of differentiation and proliferation of other neighbouring vascular cells.