Impact of pancreas and kidney transplantation on determinants of blood and plasma viscosity.

Simultaneous pancreas and kidney transplantation (PKT) is associated with a deterioration of hemorheology. We investigated the determinants of plasma and blood viscosity (hct. 35%) after PKT (n = 49), in type 1 diabetes (n = 26) and in healthy controls (n = 24). Patients after PKT were subdivided due to their graft function (intact pancreas and kidney graft, n = 26; pancreas rejected, intact kidney graft, n = 23). We examined the correlations of total serum protein, albumin, fibrinogen, alpha 2-macroglobulin, total cholesterol, LDL cholesterol, HDL cholesterol and triglycerides with plasma and blood viscosity (hct. 35%) measured at a continuous shear range of 600-0.2 s-1 with a rotational viscometer (Haake, Germany). Total protein was strongly associated with plasma viscosity in all examined groups (r > 0.5, p < 0.03), it determined blood viscosity over the whole shear range in type 1 diabetic patients, but only at high shear rates after PKT (> or = 100 s-1). The strong association of albumin and blood viscosity in type 1 diabetes and in healthy controls (shear rates > or = 10 s-1) was not found after PKT. Fibrinogen correlated with plasma and blood viscosity (> or = 25 s-1) after PKT (p < 0.03) but no in type 1 diabetic patients or healthy controls. Alpha 2-macroglobulin correlated with plasma and high shear blood viscosity after PKT only after pancreas rejection, no correlation was found after successful PKT. It also correlated with plasma and blood viscosity at low and high shear rates in type 1 diabetes. Total cholesterol and low shear blood viscosity correlated positively in successfully transplanted patients (r > 0.44), but negatively after pancreas rejection (r > -0.44). No correlation was found in type 1 diabetic patients, a positive association was found in healthy controls for plasma and low shear blood viscosity. LDL cholesterol correlated negatively (after pancreas rejection) or positively (healthy controls) with low shear blood viscosity (p < 0.03) and positively with plasma viscosity. HDL cholesterol was negatively associated with high shear blood viscosity in all groups (p < 0.05), except after successful PKT, where no association was found. It did not correlate with plasma viscosity in any group. Triglycerides did not contribute significantly to blood viscosity in the examined groups. The metabolic alterations after PKT influence plasma proteins, lipids and corpuscular elements of blood with regard to their effect on rheology.

Cardiovascular risk profile after simultaneous pancreas and kidney transplantation.

The positive influence of simultaneous pancreas and kidney transplantation (PKT) on the development of diabetic microvascular lesions is well established. On the other hand, little is known on its impact on diabetic macrovascular disease, which is still the major cause of death in diabetes, including patients after PKT. In order to evaluate the influence of PKT on the cardiovascular risk profile, we performed a cross-sectional study on 55 patients. Special attention was given to the hemorheological parameters fibrinogen and plasma viscosity, two important cardiovascular risk factors, which so far have found no attention in the field of PKT research. The patients were subdivided into three groups according to their graft function: group 1-26 patients after successful PKT (no insulin dependency, serum creatinine <2 mg%), group 2-23 patients after PKT and rejection of the pancreas graft (insulin dependency, serum creatinine <2 mg%), group 3-6 patients after PKT with pancreas rejection and renal insufficiency (insulin dependency, serum creatinine >2 mg%, no dialysis). There was a high prevalence of arterial hypertension after PKT (group 1: 65%, group 2: 70%, group 3: 100%). Serum lipids were in the normal range as long as renal function was intact. In renal insufficiency, however, LDL-cholesterol and triglycerides were significantly elevated (p < 0.05). Fibrinogen was significantly raised after PKT (p < 0.001), as was plasma viscosity when the pancreas graft was rejected (p < 0.02). There was a tendency towards elevated fibrinogen levels with decreasing graft function. In conclusion, a number of cardiovascular risk factors were identified in patients after PKT, predominantly arterial hypertension and impaired hemorheology, with elevated fibrinogen levels and plasma viscosity. There is a further enhancement with decreasing graft function.

Formation of plasma advanced glycosylation end products (AGEs) has no influence on plasma viscosity.

Plasma viscosity is mainly determined by large non-spherical proteins. In Type 1 diabetes mellitus, plasma viscosity increases with deterioration of diabetic control. Since protein glycation and formation of advanced glycosylation end products (AGEs) alter the structural and functional properties of proteins, AGEs might influence the rheological properties of plasma proteins. Therefore, we investigated the influence of plasma-AGEs on plasma viscosity in 34 normoalbuminuric diabetic patients (17 Type 1, 17 Type 2) with normal renal and liver function. In an additional experiment, 6 ml plasma of 9 healthy volunteers were incubated under sterile conditions for 14 days at 37.5 degrees C in the presence of 5.2 and 32.9 mmol l(-1) glucose. In diabetic patients, plasma-AGE levels were not correlated with plasma viscosity. Plasma-AGE levels in healthy controls (246 +/- 37 U ml[-1], mean +/- SD) were raised significantly (p<0.001) after the incubation at 37.5 degrees C (392 +/- 57 U ml[-1] and 552 +/- 58 U ml[-1], respectively). However, no difference was found in plasma viscosity pre- and post-incubation (pre-incubation: 1.25 +/- 0.04 mPas, post-incubation: 1.23 +/- 0.03 and 1.24 +/- 0.03, respectively). We conclude that there is no influence of plasma-AGEs on plasma viscosity.

Influence of glycemic control on viscosity and density of plasma and whole blood in type-1 diabetic patients.

The hemorheological properties of blood play an important role in determining blood flow. Blood inertia, as characterized by blood density, controls blood flow in the large arteries, whereas blood viscosity becomes increasingly important with decreasing vessel diameter. In order to evaluate the impact of glycemic control on the rheological properties of blood, we examined viscosity (shear range: 600-0.2 s-1) and density of plasma and whole blood in 26 Type-1 diabetic patients and in 24 healthy controls, matched for age and sex. The diabetic subjects were subdivided into two groups according to their degree of glycemic control: 14 patients with good (HbA1c = 7.1 +/- 0.6%), and 12 patients with poor control (HbA1c = 8.7 +/- 0.7%). Diabetic patients as a whole did not differ from healthy controls in any of the rheological parameters. Subdivision of the patients due to their degree of glycemic control led to a marked rheological separation of Type-1 diabetic subjects with significantly lower plasma (P < 0.008) and whole blood viscosity (P < 0.03 at 10 and 25 s-1), and plasma density (P < 0.05) in well controlled patients. Compared with healthy controls, well controlled diabetic patients had significantly lower values of viscosity (P < 0.005) and density (P < 0.05) of plasma. Poorly controlled patients, on the other hand, did not differ from healthy controls in the examined rheological parameters. There seems to be a positive influence of good glycemic control on hemorheology in Type-1 diabetic patients.

Effect of fibrinogen substitution in afibrinogenemia on hemorheology and platelet function.

Fibrinogen substitution can correct bleeding in afibrinogenemia. We assessed the effect of fibrinogen substitution in a patient lacking immunoreactive fibrinogen. Fibrinogen and thrombin time were not measurable before, but became detectable within 30 min after substitution, parallelled by an increase in ADP-induced platelet aggregation from < 10% to 32%. Platelet adhesion, measured by Stagnation Point Flow Adhesio- Aggregometry, was not detectable prior to substitution but attained normal values thereafter. Scanning electron microscopy of adhering platelets revealed pseudopodia protrusion and spreading. Morphometry revealed two populations of spread platelets one of which demonstrated inhibited spreading as compared to healthy controls. Immunoelectron microscopy revealed normal GPIIb/IIIa receptor expression, both before and after substitution. Dynamic and kinematic viscosity of plasma and whole blood remained below the 99.9% confidence border of a healthy control group. In afibrinogenemia fibrinogen levels as low as 10% of normal concentration sufficed to normalize coagulation, platelet adhesion, and, partially, spreading.