Diabetes is associated with posttranslational modifications in plasminogen resulting in reduced plasmin generation and enzyme-specific activity.

Diabetes is associated with hypofibrinolysis by mechanisms that are only partially understood. We investigated the effects of in vivo plasminogen glycation on fibrinolysis, plasmin generation, protein proteolytic activity, and plasminogen-fibrin interactions. Plasma was collected from healthy controls and individuals with type 1 diabetes before and after improving glycemia. Plasma-purified plasmin(ogen) functional activity was evaluated by chromogenic, turbidimetric, and plasmin conversion assays, with surface plasmon resonance employed for fibrin-plasminogen interactions. Plasminogen posttranslational modifications were quantified by mass spectrometry and glycation sites located by peptide mapping. Diabetes was associated with impaired plasma fibrin network lysis, which partly normalized upon improving glycaemia. Purified plasmin(ogen) from diabetic subjects had impaired fibrinolytic activity compared with controls (723 ± 16 and 317 ± 4 s, respectively; P < .01), mainly related to decreased fibrin-dependent plasmin generation and reduced protease activity (Kcat/KM 2.57 ± 1.02 × 10⁻³ and 5.67 ± 0.98 × 10⁻³ M⁻¹s⁻¹, respectively; P < .05). Nε-fructosyl-lysine residue on plasminogen was increased in diabetes compared with controls (6.26 ± 3.43 and 1.82 ± 0.95%mol, respectively; P < .01) with preferential glycation of lysines 107 and 557, sites involved in fibrin binding and plasmin(ogen) cleavage, respectively. Glycation of plasminogen in diabetes directly affects fibrinolysis by decreasing plasmin generation and reducing protein-specific activity, changes that are reversible with modest improvement in glycemic control.

A randomized controlled trial evaluating the erythropoiesis stimulating agent sparing potential of a vitamin E-bonded polysulfone dialysis membrane.

BACKGROUND: Vitamin E (VE) bonded polysulfone dialysis membranes have putative erythropoiesis stimulating agent (ESA)-sparing and anti-inflammatory properties based on data from a small number of studies. We sought to investigate this in a large, prospective 12-month randomized controlled trial. METHODS: Two-hundred and sixty prevalent haemodialysis (HD) patients were randomized to dialysis with VE-bonded polysulfone membranes or non-VE-bonded equivalents. All ESA-dosing was performed by means of a computer-based anaemia management decision support system. Monthly data were used to calculate the ESA resistance index (ERI) and blood tests were performed at baseline, 6 and 12 months for measurement of C-reactive protein (CRP) levels. RESULTS: Of the 260 patients, 123 were randomized to dialysis with the VE-membrane and 12-month data was available for 220 patients. At the study population level, no beneficial effect of the VE membranes on the ERI or CRP levels was observed. Post hoc analyses indicated that there was a significant fall in ERI for patients with the highest baseline ESA resistance dialysed with the VE (9.28 [7.70-12.5] versus 7.70 [5.34-12.7] IU/week/kg/g/dL Hb, P = 0.01) but not the control membranes (9.45 [7.62-12.3] versus 8.14 [4.44-15.6] IU/week/kg/g/dL Hb, P = 0.41); this was not attributable to changes in CRP levels. CONCLUSIONS: Wholesale switching of all chronic HD patients to dialysis with VE-bonded polysulfone membranes appears not to be associated with improvements in ESA-responsiveness or CRP. These membranes may have utility in patients with heightened ESA resistance.

Complement and Cardiovascular Disease--The Missing Link in Haemodialysis Patients.

BACKGROUND: Patients on haemodialysis (HD) have high rates of cardiovascular (CV) disease and activation of the complement system. Despite evidence in non-renal patients that these may be linked, this association has received little attention in HD patients to date. In the setting of a randomised controlled trial we evaluated the relationships between baseline complement levels and subsequent CV events and mortality, in addition to the effects of HD with a vitamin E (VE)-coated dialysis membrane on circulating complement levels. METHODS: A total of 260 HD patients were randomised to dialysis with a VE-coated dialysis membrane or non-VE coated equivalent for 12 months. Blood samples were taken at baseline, 6 and 12 months for measurement of C3, factor D, factor H and SC5b-9 levels. Data were collected prospectively on deaths and CV events. RESULTS: Higher C3 levels at baseline were associated with subsequent CV events (hazard ratio 1.20 (1.01-1.42) per 0.1 mg/ml). Patients with intermediate SC5b-9 levels had significantly lower CV event rates and mortality than those with either high or low levels (p < 0.01). There were no effects of the VE-membranes on the complement components measured nor the clinical endpoints considered. CONCLUSIONS: The levels of C3 and SC5b-9 may have prognostic utility for predicting future CV events and/or mortality in HD patients - a relationship that requires further investigation. Dialysing prevalent HD patients with VE-bonded polysulfone membranes for a period of 12 months did not alter the circulating levels of the alternative complement pathway components considered here.

Fibrinogen and fibrin clot structure in diabetes.

Diabetes is associated with an increased risk of developing cardiovascular disease, which is not fully accounted for by the accumulation of classic cardiovascular risk factors in patients. Recent evidence has demonstrated fibrinogen to be a powerful independent risk marker for cardiovascular disease in the general population, and it is also likely to contribute toward the increased atherosclerotic risk in diabetes. The etiology of hyperfibrinogenemia in diabetes is likely to be multifactorial, and at present the mechanisms involved have not been clarified. However, insulin, insulin resistance and inflammation are likely to be involved, especially in type 2 diabetes. The influence of diabetes in determining an individual's atherothrombotic risk is likely to extend beyond that of elevated fibrinogen levels, and may also act via changes in the structure and function of the fibrin clot that forms. Further research is needed to determine the mechanisms underlying these changes, which may lead to development of future interventions to reduce the excessive vascular risk associated with this disease.

Genetics of fibrin clot structure: a twin study.

Coronary artery thrombosis following plaque rupture is an important feature of myocardial infarction, and studies have highlighted the role of coagulation in this condition. Although genetic and environmental influences on the variance in coagulation protein concentrations have been reported, there are no data on the heritability of structure/function of the final phenotype of the coagulation cascade, the fibrin clot. To assess genetic and environmental contributions to fibrin structure, permeation and turbidity studies were performed in 137 twin pairs (66 monozygotic, 71 dizygotic). The environmental influence (e2) on pore size (Ks) (e2 = 0.61 [95% confidence interval (CI), 0.45-0.80]) and fiber size (e2 = 0.54 [95% CI, 0.39-0.73]) was greater than the heritability (h2 = 0.39 [95% CI, 0.20-0.55] and 0.46 [95% CI, 0.27-0.62], respectively). After correction for fibrinogen levels, the environmental effect persisted for Ks (e2 = 0.61), but genetic influence assumed a greater importance in determining fiber size (h2 = 0.73). Multivariate analysis revealed an overlap in the influence of genetic and environmental factors on fibrinogen levels, Ks, and fiber size. Factor XIII B subunit showed environmental and genetic correlation with fibrinogen and fiber size and a genetic correlation with Ks. The results indicate that genetic and environmental influences are important in determining fibrin clot structure/function.