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ABSTRACT: Lipid-lowering therapy is associated with reduced cardiovascular risk. The aim of the present study was to investigate whether lipid-lowering therapy might be associated with changes in the concentrations of metabolically important hormone concentrations. We performed a randomised cross-over open-label trial with atorvastatin (10 mg/day) and fenofibrate (200 mg/day), each for 6 weeks separated by a 6-week washout period in 13 patients (5 men, 8 women, age 60.0+/-6.8 years, body mass index 30.0+/-3.0 kg/m2) with type 2 diabetes mellitus and mixed hyperlipoproteinaemia. Plasma ghrelin (RIA, Phoenix Pharmaceuticals, Mountain View, CA, USA), adiponectin (ELISA, Biovendor, Heidelberg, Germany) as well as resistin (ELISA, Linco Research, St. Charles, MO, USA) concentrations were measured before and after atorvastatin as well as before and after fenofibrate. Ghrelin (462+/-84 pg/ml before vs. 464+/-102 pg/ml after atorvastatin, n.s.; 454+/-85 pg/ml before vs. 529+/-266 pg/ml after fenofibrate, n.s.), resistin (24.4+/-7.4 pg/ml before vs. 23.7+/-9.1 pg/ml after atorvastatin, n.s.; 23.4+/-8.2 pg/ml before vs. 19.9+/-5.5 pg/ml after fenofibrate, n.s.), adiponectin (10.89+/-5.33 pg/ml before vs. 12.41+/-5.75 pg/ml after atorvastatin, n.s.; 12.58+/-9.87 pg/ml before vs. 10.27+/-5.23 pg/ml after fenofibrate, n.s.) and insulin levels did not change significantly during lipid-lowering therapy. In patients with type 2 diabetes and mixed hyperlipoproteinaemia, short-term atorvastatin as well as fenofibrate therapy had no significant effects on adiponectin, ghrelin or resistin levels.
Acta Diabetologica 07/2007; 44(2):65-8. · 2.78 Impact Factor
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ABSTRACT: Fasting and postprandial levels of human peptide YY (PYY) were recently found to be lower in obesity. To investigate whether PYY levels are correspondingly high in patients with anorexia nervosa, PYY concentrations were analyzed under basal conditions and in response to a liquid meal. We investigated PYY plasma levels in 16 female anorectic (BMI 15.2+/-0.3 kg/m2) and seven lean subjects (BMI 21.3+/-0.6 kg/m2) before and after ingestion of a liquid meal (250 kcal; 15% protein, 55% carbohydrates, and 30% fat). PYY levels were analyzed using PYY ELISA (DSL, USA). Values are given as mean+/-SEM. Basal PYY levels in anorectic patients (89.0+/-14.4 pg/mL) were not significantly different from lean subjects (64.1+/-12.1 pg/mL). Postprandial PYY levels in healthy volunteers increased significantly after 20 and 60 min (80.4+/-12.7 and 96.0+/-19.9 pg/mL, respectively). In anorectic women PYY was increased at 20 min (137.9+/-19.5 pg/mL) and at 60 min (151.3+/-19.2 pg/mL). No difference was found between both groups. We conclude that basal and postprandial PYY levels in normal weight women are not different from anorectic patients. We could not confirm the recently published blunted postprandial PYY response in anorexia, a finding that merits further study.
Appetite 06/2007; 48(3):301-4. · 2.59 Impact Factor
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ABSTRACT: By far the most common dyslipoproteinema in patients with liver disease is hypertriglyceridemia with decreased HDL cholesterol occurring in fatty liver diseases. Since these latter frequently occur in patients with a metabolic syndrome, it must be assumed that lipid metabolism disorder is associated with a pronounced atherogenic effect. This means that--in contrast to cholestatic liver disease--treatment is almost always indicated. General therapeutic measures (weight reduction, optimization of blood sugar) are to the fore. As medication, metformin, fibrates and insulin sensitizers may be considered since, apart from improving glucose metabolism and hypertriglyceridemia, they also have a direct hepatic effect. It must, however, be noted that the available study data are not yet satisfactory, so that an individual decision must be made as to whether medical treatment of a lipid metabolism disorder makes good lipidological sense and is hepatologically justified.
MMW Fortschritte der Medizin 05/2006; 148(14):37-40.
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ABSTRACT: Glitazones increase the secretion of the adipocyte-derived hormone adiponectin. Furthermore, the gastric signal peptide ghrelin is known to suppress adiponectin expression in adipocyte cell culture models. It is not known whether the increase in adiponectin during glitazone therapy is due to a suppression of ghrelin levels, a decrease of resistin concentrations or an amelioration of glucose control. In 10 patients (age 71+/-9 yr, body mass index 29.9+/-3.6 kg/m(2), HbA1c 6.9+/-0.5%) with Type 2 diabetes, who had already been treated with sulfonylureas, we additionally initiated a pioglitazone therapy (30 mg/day) for 12 weeks. To investigate the pioglitazone effect independently of blood glucose, glycosylated hemoglobin (HbA1c) was kept unchanged by reducing the daily dose of sulfonylurea if necessary. Ghrelin concentration [radioimmunoassay (RIA), Phoenix Pharmaceuticals, Mountain View, CA, USA], adiponectin levels [enzyme-linked immunosorbent assay (ELISA), Biovendor, Heidelberg, Germany] as well as resistin concentrations (ELISA, Linco Research, St. Charles, MO, USA) were measured before and after pioglitazone. Glucose control remained unchanged within the 12-week pioglitazone therapy (HbA1c 6.9+/-0.5% before vs 6.8+/-0.6% after pioglitazone) while body weight increased from 86.6+/-9.2 to 88.0+/-9.4 kg (p<0.05), and insulin concentration decreased from 19.6+/-5.7 to 10.1+/-1.6 microU/ml (p<0.05). Adiponectin concentration increased in all patients from 7.70+/-2.47 to 23.33+/-8.28 microg/ml (p<0.01), while resistin concentrations tended to decrease (by 15%; p=0.059). However, ghrelin remained unchanged during therapy. No correlations were observed either between ghrelin, resistin, insulin and adiponectin, or between body weight and hormone plasma levels. The increase in adiponectin levels during pioglitazone therapy seems to be at least partly independent of blood glucose and insulin concentration as well as of ghrelin levels, and it was not associated with a decrease in resistin concentrations.
Journal of endocrinological investigation 04/2006; 29(3):231-6. · 1.57 Impact Factor
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ABSTRACT: Glycerol kinase deficiency is a rarely diagnosed X-linked recessive disorder which occurs as a complex form together with the adrenal hypoplasia congenita (AHC) or with Duchenne muscular dystrophy (DMD) or as an isolated form either symptomatic or asymptomatic. We report the case of a male adult who had pseudo-hypertriglyceridemia (falsely elevated triglycerides of 552 mg/dl) refractory to lipid-lowering therapy for more than 15 years. Further investigations revealed an isolated, asymptomatic glycerol kinase deficiency. Using polymerase chain reaction and direct DNA sequencing, a novel missense mutation Gly280Ala in the Xp21.3 glycerol kinase gene was found. Comparison between human and E.coli glycerol kinase showed that the mutation affects a highly conserved amino acid in an ATP-binding domain in the active centre. This mutation is assumed to destabilize a hydrogen bond between ligand and enzyme resulting in a reduced activity of glycerol kinase and therefore in hyperglycerolemia.
Experimental and Clinical Endocrinology & Diabetes 08/2005; 113(7):396-403. · 1.69 Impact Factor
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ABSTRACT: The appetite-modulating hormone ghrelin transmits changes in food intake to the central nervous system. In patients with anorexia nervosa, weight gain reduces elevated fasting ghrelin levels to normal, however, less is known about the effects on postprandial ghrelin levels. In 20 female anorectic in-patients (25.6 +/- 1.0 years; body mass index (BMI) 15.1 +/- 0.3 kg/m2) a standardized test with 250 ml fluid meal (250 kcal: 9.4 g protein, 34.4 g carbohydrates, and 8.3 g fat) was performed at three different times (at admission, after partial weight gain of at least 2 kg, and at discharge) and compared to healthy controls (n = 6; BMI 21.1 +/- 0.7 kg/m2). Plasma ghrelin levels were measured preprandially as well as 20 and 60 min postprandially by a commercially available radioimmunoassay (Phoenix Pharmaceuticals, USA). At admission plasma ghrelin levels significantly decreased postprandially (from 871.9 +/- 124 to 620.3 +/- 80 pg/ml 60 min after meal; P < 0.005). After partial weight gain (2.8 +/- 0.1 kg; BMI 16.1 +/- 0.3 kg/m2) postprandial ghrelin concentrations decreased from 597.0 +/- 79 to 414.7 +/- 39 pg/ml (P < 0.0001), at discharge (weight gain: 7.6 +/- 0.5 kg; BMI 17.9 +/- 0.4 kg/m2) from 570.4 +/- 78 to 395.4 +/- 44 pg/ml (P < 0.0001). Mean postprandial ghrelin decrease was not significantly different between the three tests (29, 25, and 26%, respectively) or to controls (20%). In anorectic patients mean postprandial ghrelin decrease did not change during weight gain. These findings indicate that in anorexia nervosa the suppression of ghrelin release by acute changes of energy balance (feeding) is not disturbed and that it is independent from chronic changes in energy balance (weight gain).
Psychoneuroendocrinology 07/2005; 30(6):577-81. · 5.81 Impact Factor
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ABSTRACT: Ezetimibe, a cholesterol absorption inhibitor, can be combined with statins to lower LDL-cholesterol. We evaluated additional ezetimibe (10 mg/day) in a placebo-controlled, double blind, randomized cross-over study in 20 patients (age 56+/-9 years, m:f 10:10, BMI 27.5+/-4.0 kg/m(2)) suffering from severe hypercholesterolemia and CHD who were treated by statins and regular LDL-apheresis. Lipoproteins (cholesterol, triglycerides, LDL-cholesterol, HDL-cholesterol, VLDL-cholesterol, VLDL-triglycerides, lipoprotein(a)) were determined twice (before and during ezetimibe/placebo, each given for 5 weeks), dietary behaviour was analyzed once (3-days-protocol) during each treatment period. During ezetimibe the mean (+/-S.D.) preapheresis LDL-cholesterol concentration decreased from 159+/-26 mg/dl (4.11+/-0.67 mmol/l) to 133+/-28 mg/dl (3.44+/-0.72 mmol/l) (-16+/-11%, P<0.0001, Wilcoxon test) and the postapheresis LDL-cholesterol from 51+/-9 mg/dl (1.32+/-0.23 mmol/l) to 43+/-8 mg/dl (1.11+/-0.21 mmol/l) (-14+/-25%, P<0.05), while there was no significant change during placebo. Mean VLDL-cholesterol fell by 18+/-71% (P<0.05) during ezetimibe and was not significantly changed by placebo (+19+/-70%). Furthermore, during ezetimibe less plasma volume was treated (3725+/-1560 versus 3870+/-1549 ml, P<0.05). Ezetimibe had no effect on pre- and postapheresis triglyceride, HDL-cholesterol and lipoprotein(a) levels. The effect of ezetimibe was independent of the statin dose. Dietary behaviour did not change and no side effects were observed. Thus, in patients with severe LDL-hypercholesterolemia and CHD the addition of ezetimibe to intensive lipid lowering therapy (statins and LDL-apheresis) resulted in a further, clinically significant decrease of LDL-cholesterol.
Atherosclerosis 05/2005; 180(1):107-12. · 3.79 Impact Factor
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ABSTRACT: Patients with diabetes mellitus type 2 are characterized by a typical dyslipoproteinemia. Improvement in glucose control usually also ameliorates this dyslipoproteinemia. It is unclear whether different antidiabetic strategies differ in their effects on the lipid profile. Particularly, it is unknown whether glitazones improve lipid values independently of their effects on glucose metabolism.
Ten patients well controlled on sulfonylureas (HbA1c 6.9 +/- 0.5 %) with diabetic dyslipoproteinemia were treated with additional pioglitazone (30 mg/d) for 3 months. Every 4 weeks the sulfonylurea dose was adjusted to keep HbA1c and fasting glucose constant. Before and after 3 months of pioglitazone therapy lipid metabolism was determined in detail (cholesterol, triglyceride, LDL-cholesterol, HDL-cholesterol, VLDL-cholesterol, VLDL-triglycerides, lipoprotein(a), LDL-subtype distribution by isopycnic density gradient ultracentrifugation).
Although glucose control remained unchanged (HbA1c 6.9 +/- 0.5 % vs. 6.8 +/- 0.6 %; fasting glucose concentration 7.7 +/- 1.1 vs. 7.3 +/- 1.3 mmol/l) we observed a significant reduction in triglyceride concentration (1.9 +/- 0.6 vs. 1.4 +/- 0.5 mmol/l, - 26 %, p < 0.01), a significant increase in HDL-cholesterol concentration (1.2 +/- 0.2 vs. 1.4 +/- 0.2 mmol/l, + 14 %, p < 0.05), a significant decrease in LDL/HDL-ratio (3.03 +/- 0.77 vs. 2.51 +/- 0.61, - 24 %, p < 0.05) and non-significant improvements in total cholesterol, LDL-cholesterol, VLDL-triglycerides, and VLDL-cholesterol concentrations. The LDL-subtype profile improved (significant reduction [- 20 %] in small dense LDL).
This pilot study indicates that at comparable fasting glucose concentration and at comparable HbA1c value pioglitazone is superior to sulfonylureas concerning the improvement of diabetic dyslipoproteinemia. Whether this relates to indirect effects (improvement in insulin sensitivity) or direct effects (stimulation of PPARalpha) remains to be determined.
Experimental and Clinical Endocrinology & Diabetes 02/2005; 113(1):49-52. · 1.69 Impact Factor
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ABSTRACT: LDL can be subfractionated into buoyant (1.020-1.029 g/ml(-1)), intermediate (1.030-1.040 g/ml(-1)), and dense (1.041-1.066 g/ml(-1)) LDLs. We studied the rebound of these LDL-subfractions after LDL apheresis in seven patients with heterozygous familial hypercholesterolemia (FH) regularly treated by apheresis (58 +/- 9 years, LDL-cholesterol = 342 +/- 87 mg/dl(-1), triglycerides = 109 +/- 39 mg/dl(-1)) and high-dose statins. Apolipoprotein B (apoB) concentrations were measured in LDL subfractions immediately after and on days 1, 2, 3, 5, and 7 after apheresis. Compartmental models were developed to test three hypotheses: 1) that dense LDLs are derived from the delipidation of buoyant and intermediate LDLs (model A); 2) that dense LDLs are generated directly from LDL-precursors (model B); or 3) that a model combining both pathways (model C) is necessary to describe the metabolism of dense LDLs. In all models, it was assumed that apoB production and fractional catabolic rate (FCR) did not change with apheresis. Apheresis decreased buoyant, intermediate, and dense LDL-apoB by 60 +/- 12%, 67 +/- 5%, and 69 +/- 11%, respectively. Models B and C, but not model A, described the rebound data. The model with the greatest biological plausibility (model C) was used to estimate metabolic parameters. FCR was 1.05 +/- 0.86 d(-1), 0.48 +/- 0.11 d(-1), and 0.69 +/- 0.24 d(-1) for buoyant, intermediate, and dense LDLs, respectively. Dense LDL production was 17.3 +/- 0.2 mg/kg(-1)/d(-1), 58% of which was derived directly from LDL precursors (VLDL, IDL, or direct secretion), while 42% was derived from buoyant and intermediate LDLs. Thus, our data indicate that in statin-treated patients with heterozygous FH dense LDLs originate from two sources. Whether this is also valid in other metabolic situations (with predominant small, dense LDLs) remains to be determined.
The Journal of Lipid Research 09/2004; 45(8):1459-67. · 5.56 Impact Factor
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ABSTRACT: Hypertriglyceridemia is a risk factor for atherosclerosis that is typically associated with high concentrations of adhesion molecules, impaired hemorrheology and an unfavourable low-density lipoprotein (LDL) subtype distribution. We hypothesised that some of these risk markers might be beneficially influenced by lipid-lowering therapy with atorvastatin in hypertriglyceridemic patients.
Nineteen patents with primary hypertriglyceridemia were given 10 mg of atorvastatin per day for four weeks. Their cholesterol, triglyceride, LDL and high-density lipoprotein cholesterol (HDL-C) levels, LDL subtype profile, hemorrheological parameters and E-selectin, vascular cell adhesion molecule-1 and intercellular adhesion molecule-1 concentrations were measured before and at the end of atorvastatin therapy. The levels of total and LDL cholesterol respectively decreased by 25% and 24% (both p < 0.001). Furthermore, cholesterol was reduced by 8-29% in all seven LDL subfractions (density range: 1.020-1.066 g/mL) (p < 0.05). The reduction in triglyceride concentrations was of marginal significance (9%, p = 0.1), but its degree positively correlated with the reduction of small-dense LDL (r = 0.5, p < 0.025). Plasma viscosity and blood viscosity at low shear rates were respectively reduced by 2% and 16% (both p < 0.05). The effect of the treatment on the concentrations of HDL-C, fibrinogen and adhesion molecules was not significant.
Atorvastatin (10 mg/day) not only reduced the plasma concentrations of atherogenic lipoproteins but also improved the LDL-subtype profile and reduced plasma and blood viscosity in patients with hypertriglyceridemia; however, it failed to significantly lower triglyceride concentrations.
Nutrition Metabolism and Cardiovascular Diseases 04/2003; 13(2):87-92. · 3.73 Impact Factor
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ABSTRACT: The dyslipoproteinemia characterizing patients with type 2 diabetes is a major risk factor for atherosclerosis. Prospective studies indicate that an improved glucose control is associated with lower lipid levels. In this study we evaluated whether an improvement of the lipid status can also be observed in a routine clinical setting. Furthermore, we evaluated how many patients achieve lipid target levels by improving glucose control.
In 51 type 2 diabetics (60 +/- 12 ys., 29 men, 22 women) lipid values were determined before and after improvement of glucose metabolism (6 - 12 weeks, HbA1c 7.9 +/- 1.9 % vs. 7.1 +/- 1.3 %). Patients on lipid-lowering medication or with atherosclerosis were excluded. The improved glucose control was achieved by starting/intensifying treatment with diet (n = 5), acarbose (n = 5), metformin (n = 10), sulfonylurea/glinide (n = 12) or insulin (n = 19).
The decrease in HbA1c was associated with a decrease in total cholesterol (232 +/- 64 vs. 216 +/- 35 mg/dl, p < 0.05) and triglycerides (348 +/- 448 vs. 216 +/- 139 mg/dl, p < 0.01), while HDL- and LDL-cholesterol did not change significantly. Only in patients with triglycerides > 200 mg/dl did changes in HbA1c-levels correlate with changes in triglyceride-levels (r(2) = 0.32, p = 0.012). Lipid target levels were reached in seven of 51 patients (five of 51 patients before improvement of HbA1c).
Although in routine clinical practice an improvement in HbA1c results in better lipid values. This improvement is small and is usually not sufficient to reach lipid target levels.
DMW - Deutsche Medizinische Wochenschrift 05/2002; 127(18):958-62. · 0.53 Impact Factor
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ABSTRACT: The reason for the elevation of fibrinogen concentration in diabetic patients with nephropathy is not known so far. In order to elucidate the mechanism of such an increase in fibrinogen levels, we investigated haemorheological and inflammatory markers in type 2 diabetic patients in a cross-sectional design. Thirty-two non-smoking type 2 diabetic patients (13 women, 19 men; body mass index 29.1+/-5.4 kg/m2, age 62.8+/-12.1 years) were investigated. Patients with C-reactive protein levels >1.5 mg/dl were excluded from the study. Concentration of fibrinogen was measured by immunonephelometry, C-reactive protein by immunoturbidimetry, and interleukin-6 (IL-6) by an enzyme-linked immunosorbent assay, and viscosity of plasma and of whole blood was determined by rotation viscosimetry. Concentrations of inflammatory parameters were well correlated with each other (p<0.05 for all correlations): IL-6 with C-reactive protein (r=0.48), and C-reactive protein with fibrinogen (r=0.41). While no associations were found with concentrations of C-reactive protein or IL-6, urinary albumin excretion was correlated with erythrocyte sedimentation rate (r=0.47) and with fibrinogen concentration (r=0.39; p<0.05). In patients with type 2 diabetes mellitus, urinary albumin excretion was not associated with concentrations of IL-6 or C-reactive protein. These results suggest an IL-6-independent mechanism for increased fibrinogen levels and erythrocyte sedimentation rate in type 2 diabetic patients with increased urinary albumin excretion.
Acta Diabetologica 12/2001; 38(4):153-5. · 2.78 Impact Factor
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ABSTRACT: Most of the published studies concerning platelet aggregation were performed with chemical stimulation procedures, however, mechanical stimulation might be a better simulation of physiological activation of platelets. In order to evaluate the influence of ultrasound on platelet aggregation in vitro, we developed an ultrasound device in a standardized set-up, and we evaluated the influence of lipoproteins and the glycoprotein IIb/IIIa inhibitor tirofiban on ultrasound induced platelet aggregation. A cylindrical shaped plastic test tube with 1 ml of platelet-rich plasma was placed in an ultrasound bath (35 kHz) for 5 s. The ultrasound energy transfer into the sample (Delta W=3.77 J) was calculated using the average temperature increase (averaged by 0.935 degrees C) of the sample. Platelet aggregation was quantified immediately after stimulation with ultrasound or adenosine diphosphate (ADP 2.1 and 4.2 microM) by the Myrenne Aggregometer PA2 at low (40 s(-1)) and afterwards at high (2500 s(-1)) shear. To evaluate the influence of lipoproteins, seven healthy male volunteers were investigated before and after a fat load (50 g fat per m(2) body surface), and 11 patients suffering from hypercholesterolemia and atherosclerotic disease before and after a single low-density lipoprotein (LDL) apheresis. Platelet aggregation after ultrasound stimulation was well correlated with platelet aggregation after ADP (r between 0.50 and 0.95). However, when exposed to high shear, the low shear-induced platelet aggregates were more stable after ultrasound stimulation compared with ADP stimulation either with or without tirofiban. After the fat load triglyceride concentration increased from 0.86+/-0.39 to 2.10+/-1.10 mmol l(-1) (P<0.05) resulting in a reduced formation of platelet aggregates after weak (ADP 2.1 microM) but not after strong (ADP 4.2 microM or ultrasound) stimuli. After a single LDL apheresis LDL cholesterol dropped from 3.99+/-0.90 to 1.06+/-0.55 mmol l(-1) (P<0.005). No changes in platelet aggregation were observed with the exception of a lower aggregation when exposed to high shear after stimulation with 2.1 microM ADP. In conclusion, we found the ultrasound stimulation of platelet-rich plasma easy to perform. The platelet aggregation after ultrasound stimulation correlated well with stimulation after ADP. While a reduction in LDL cholesterol concentration had only slight effects on platelet aggregation, an increase in triglyceride concentration resulted in a reduced formation of platelet aggregates after weak stimulation.
European Journal of Ultrasound 12/2001; 14(2-3):157-66.
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ABSTRACT: Atorvastatin is a potent hydroxy-methyl-glutaryl-coenzyme A (HMG-CoA) reductase inhibitor that decreases low-density lipoprotein (LDL) cholesterol and triglyceride concentrations, but little is known about its effects on LDL subtype distribution in different types of hyperlipoproteinemia. Thus, we evaluated the influence of atorvastatin (10 mg/d, 4 weeks) on lipid concentrations and LDL subtype distribution in patients with hypercholesterolemia (n = 9; LDL cholesterol, 227 +/- 30 mg/dL; triglycerides, 137 +/- 56 mg/dL), patients with type 2 diabetes and dyslipoproteinemia (n = 11; LDL cholesterol, 163 +/- 34 mg/dL; triglycerides, 260 +/- 147 mg/dL), and controls (n = 10; LDL cholesterol, 116 +/- 20 mg/dL; triglycerides, 130 +/- 47 mg/dL). Cholesterol concentration was determined in 7 LDL subfractions isolated by density gradient ultracentrifugation before and during atorvastatin treatment. Atorvastatin decreased LDL cholesterol (-36%, -28%, and -41%, all P <.01) and triglyceride (-4%, NS; -2%, NS; -24%, P <.05) concentrations but had little effect on high-density lipoprotein (HDL) cholesterol (-1%, NS; +10%, P <.05; +6%, NS) in hypercholesterolemic, diabetic, and control subjects, respectively. In all 3 groups, a significant reduction in cholesterol in each LDL subfraction was observed. Large-buoyant (LDL-1, LDL-2) and intermediate-dense (LDL-3, LDL-4) LDL were reduced more than small-dense (LDL-5 through LDL-7) LDL in hypercholesterolemic (-45%, -35%, and -32%, P <.05) and control subjects (-48%, -44%, and -25%, P <.05), but in diabetic patients cholesterol reduction was uniform in all LDL subtypes (-32%, -27%, and -29%, P =.45). Thus, atorvastatin decreases cholesterol concentration in all LDL subfractions in hypercholesterolemic, diabetic, and control subjects. However, the relative reduction of individual LDL subtypes differed between these groups. This finding suggests that the effect of atorvastatin on LDL subtype distribution depends on the type of underlying hyperlipoproteinemia.
Metabolism 09/2001; 50(8):983-8. · 2.66 Impact Factor
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ABSTRACT: Dyslipoproteinemias are associated with hemorrheologic abnormalities (elevated fibrinogen concentration, higher viscosity of plasma and blood). Epidemiologic data suggest that not only elevated lipoprotein concentrations (eg, low-density lipoprotein [LDL] cholesterol), but also hemorrheologic abnormalities could causally be involved in the atherosclerotic process. To elucidate potential effects of hemorrheological disturbances, we investigated patients suffering from primary hyperlipoproteinemias with both low (familial hypertriglyceridemia, n = 25) and high (type III hyperlipoproteinemia, n = 21; familial hypercholesterolemia, n = 19; mixed hyperlipoproteinemia, n = 19) atherosclerotic risk, as well as healthy controls (n = 49) in a cross-sectional design. Dyslipoproteinemias were classified by lipoprotein measurements (using ultracentrifugation), family history, and apolipoprotein E phenotype. Hemorrheology was characterized by the measurement of fibrinogen concentration, viscosity of plasma and blood at different shear rates, and red cell aggregation (RCA) at stasis and low shear. Fibrinogen concentration was lower in controls (2.38 +/- 0.09 g/L) compared with familial hypercholesterolemia (3.19 +/- 0.19 g/L), to type III hyperlipoproteinemia (3.02 +/- 0.12 g/L), to familial hypertriglyceridemia (2.95 +/- 0.21 g/L) and to mixed hyperlipoproteinemia (3.01 +/- 0.12 g/L) (P < .05, respectively) without differences between dyslipoproteinemia groups. Plasma viscosity was higher in patients with type III hyperlipoproteinemia (1.42 +/- 0.03 mPas), with familial hypertriglyceridemia (1.47 +/- 0.04 mPas), and with mixed hyperlipoproteinemia (1.43 +/- 0.02 mPas) compared with controls (1.29 +/- 0.01 mPas) (P < .05, respectively). After including 6 lipoprotein parameters in a general linear model, plasma viscosity, blood viscosity, and RCA were higher in familial hypertriglyceridemia compared with healthy controls and familial hypercholesterolemia (P < .05, respectively). As most of the hemorrheologic abnormalities were still significant after adjusting for lipoprotein concentrations, they seem to be at least partly independent from direct lipoprotein effects. Hemorrheologic abnormalities in familial hypertriglyceridemia (low atherosclerotic risk) were at least as marked as in dyslipoproteinemias with high atherosclerotic risk, suggesting that it might be most important to determine lipoprotein concentrations and to define exactly the type of dyslipoproteinemia for estimating the individual cardiovascular risk in these patients.
Metabolism 03/2001; 50(2):166-70. · 2.66 Impact Factor
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ABSTRACT: Diabetic dyslipoproteinemia characterized by hypertriglyceridemia, low high-density lipoprotein (HDL) cholesterol, and often elevated low-density lipoprotein (LDL) cholesterol with predominance of small, dense LDL is a strong risk factor for atherosclerosis. It is unclear whether fibrate or statin therapy is more effective in these patients. We compared atorvastatin (10 mg/day) with fenofibrate (200 mg/day), each for 6 weeks separated by a 6-week washout period in 13 patients (5 men and 8 women; mean age 60.0+/-6.8 years; body mass index 30.0+/-3.0 kg/m2) with type 2 diabetes mellitus (hemoglobin A1c 7.3+/-1.1%) and mixed hyperlipoproteinemia (LDL cholesterol 164.0+/-37.8 mg/dl, triglycerides 259.7+/-107 mg/dl, HDL cholesterol 48.7+/-11.0 mg/dl) using a randomized, crossover design. Lipid profiles, LDL subfraction distribution, fasting plasma viscosity, red cell aggregation, and fibrinogen concentrations were determined before and after each drug. Atorvastatin decreased all LDL subfractions (LDL cholesterol, -29%; p <0.01) including small, dense LDL. Fenofibrate predominantly decreased triglyceride concentrations (triglycerides, -39%; p <0.005) and induced a shift in LDL subtype distribution from small, dense LDL (-31%) to intermediate-dense LDL (+36%). The concentration of small, dense LDL was comparable during therapy to both drugs (atorvastatin 62.8+/-19.5 mg/dl, fenofibrate 63.0+/-18.1 mg/dl). Both drugs induced an increase in HDL cholesterol (atorvastatin +10%, p <0.05; fenofibrate +11%, p = 0.06). In addition, fenofibrate decreased fibrinogen concentration (-15%, p <0.01) associated with a decrease in plasma viscosity by 3% (p <0.01) and improved red cell aggregation by 15% (p <0.05), whereas atorvastatin did not affect any hemorheologic parameter. We conclude that atorvastatin and fenofibrate can improve lipoprotein metabolism in type 2 diabetes. However, the medications affect different aspects of lipoprotein metabolism.
The American Journal of Cardiology 02/2001; 87(1):44-8. · 3.37 Impact Factor
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Der Internist 11/2000; 41(10):1099-102. · 0.30 Impact Factor
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Archives of Internal Medicine 10/2000; 160(17):2685-6. · 11.46 Impact Factor
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ABSTRACT: Low-density lipoprotein (LDL) apheresis is a treatment option in patients with coronary artery disease and elevated LDL cholesterol concentrations if maximal drug therapy fails to achieve adequate LDL cholesterol reduction. This therapy is more effective when combined with strong lipid-lowering drugs, such as atorvastatin. However, conflicting data have been published concerning the effect of atorvastatin on fibrinogen concentration. Therefore, we investigated the effect of atorvastatin compared to simvastatin on fibrinogen concentration and other hemorheological parameters in patients treated by weekly LDL apheresis. Hemorheological parameters were, studied twice in 9 patients (4 female, 5 male, 54.0+/-8.9 years) with coronary artery disease treated by weekly LDL immunoadsorption, once during concomitant simvastatin therapy (40 mg daily) and once during atorvastatin therapy (40 mg daily). Fibrinogen concentration, plasma and blood viscosity at different shear rates, parameters of red cell aggregation at stasis and shear rate 3/s, and erythrocyte filterability were determined 7 days after the last LDL apheresis after each drug had been given for a minimum for 8 weeks. Fibrinogen concentration did not show any statistically significant difference during therapy with atorvastatin (3.09+/-0.36 g/L) compared to simvastatin (3.13+/-0.77 g/L). Plasma and blood viscosity as well as erythrocyte filterability were also unchanged. The increase in red cell aggregation at stasis during atorvastatin treatment (5.82+/-1.00 U versus 4.89+/-0.48 U during simvastatin; p < 0.05) was inversely correlated with a lower high-density liprotein (HDL) cholesterol concentration (1.17+/-0.21 mmol/L versus 1.31+/-0.30 mmol/L during simvastatin; p < 0.05). LDL cholesterol showed a strong trend to lower concentrations during atorvastatin (4.14+/-0.61 mmol/L versus 4.56+/-0.66 mmol/L during simvastatin; p = 0.07), despite a reduced plasma volume treated (3,547+/-1,239 ml during atorvastatin versus 3,888+/-1,206 mL during simvastatin; p < 0.05). In conclusion, fibrinogen concentration and other hemorheological parameters were unchanged during atorvastatin compared to simvastatin therapy with the exception of a higher red cell aggregation at stasis. Therefore, with respect to hemorheology, we conclude that atorvastatin should not be withheld from hypercholesterolemic patients regularly treated with LDL immunoadsorption.
Therapeutic Apheresis and Dialysis 07/2000; 4(3):244-8.
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ABSTRACT: Epidemiological studies suggest that the plasma fibrinogen concentration is the main determinant of plasma viscosity (PV), but the concentration of other macromolecules (eg, immunoglobulins) and low-density lipoprotein (LDL) cholesterol and triglycerides are also correlated with PV. However, only a few data exist concerning the in vitro effects of these plasma constituents on PV. Therefore, we investigated PV before and after the specific elimination of fibrinogen and LDL in hypercholesterolemic and hypertriglyceridemic plasma. First, hypercholesterolemic samples (n = 7) were pumped simultaneously through 2 columns: a fibrinogen-depleting column containing the pentapeptide Gly-Pro-Arg-Pro-Lys (GPRPK) and a LDL-depleting column containing specific antibodies against apolipoprotein B-100. In the plasma and in each fraction from the column, the cholesterol level was measured enzymatically, fibrinogen was determined by immunonephelometry, and PV was analyzed using a low-shear rotation viscosimeter. After the fibrinogen-depleting column, the fibrinogen concentration decreased from 3.21 +/- 0.20 to 0.94 +/- 0.16 g/L (P < .005), inducing a decrease in PV from 1.27 +/- 0.02 to 1.17 +/- 0.01 mPas (milliPascal seconds) (P < .005). Despite a marked reduction of the LDL cholesterol after the LDL-depleting column (from 6.40 +/- 0.23 to 4.08 +/- 0.32 mmol/L, P < .005), PV remained unchanged. Second, hypertriglyceridemic samples (n = 7) were pumped through the fibrinogen-depleting column, which reduced the fibrinogen concentration from 4.29 +/- 0.79 to 1.62 +/- 0.69 g/L (P < .001) and PV from 1.42 +/- 0.06 to 1.03 +/- 0.05 mPas (P < .01) while the triglyceride concentration remained unchanged. Our results confirm the epidemiological correlation between the fibrinogen concentration and PV in patients with hypercholesterolemia and hypertriglyceridemia. The influence of fibrinogen on PV seems much more pronounced than the direct effect of lipoprotein concentrations. Therefore, the elevated PV in patients with hypercholesterolemia and especially with hypertriglyceridemia seems mainly due to elevated fibrinogen levels.
Metabolism 06/2000; 49(6):810-3. · 2.66 Impact Factor
