6-ketoprostaglandin-f1-alpha and Hyperglycemia

Having developed a non-insulin-dependent diabetes mellitus (NIDDM) syndrome model in the rabbit using Wirsung duct ligation, it appeared interesting to use it to study the relationship between glycemia and the plasma levels of TXA(2)and PGI(2), and of some other biochemical parameters such as cholesterol, triglycerides, alkaline phosphatase and transaminases. A comparative study was carried out in the sham-operated rabbits (controls, C) and those having their pancreatic duct ligatured (NIDDM, D) at 15, 30, 40, 50 and 60 days post-ligation. On the 40th days, whereas in the controls, glycemia was 1.17 +/- 0.04 g.l(-1), it reached a maximum of 4.62 +/- 0.76 g.l(-1)(25.40 mM) in the NIDDMs. No significant modification was observed either in cholesterolemia or in triglyceridemia in either group. The GOT and GPT were highly increased, from 11.50 +/- 4.00 IU. l(-1)and 27.00 +/- 1.50 IU.l(-1)(C) to 37.50 +/- 5.64 IU.l(-1)(P<0. 001) and 58.50 +/- 7.50 IU.l(-1)(D) (P<0.001) in the NIDDM group, suggesting that hyperglycemia occurred simultaneously with the degeneration of the pancreatic tissue. In parallel, in D rabbits, the plasma levels of TXB(2)and 6 keto PGF(1alpha)were augmented to 68.22 +/- 6.20 pg.ml(-1)versus 22.49 +/- 5.74 pg.ml(-1)(C) (P<0.001), and 127.11 +/- 14.39 pg.ml(-1)versus 48.65 +/- 4.51 pg.ml(-1)(C) (P<0. 001) respectively. Statistical studies showed a significant correlation (P<0.05 and <0.02) between glycemia and the biosynthesis of eicosanoids under study. Moreover, 25 mM was found to be the threshold level of glucose excess essential to increase the TXA(2)and PGI(2)biosynthesis significantly. This supports the results obtained by other authors studying the action of glucose on phospholipase activity and consequent eicosanoid production.

Topics: 6-Ketoprostaglandin F1 alpha; Alkaline Phosphatase; Animals; Blood Glucose; Blood Proteins; Cholesterol; Diabetes Mellitus, Experimental; Diabetes Mellitus, Type 2; Disease Models, Animal; Epoprostenol; Hyperglycemia; Ligation; Pancreatic Ducts; Platelet Aggregation Inhibitors; Rabbits; Thromboxane A2; Thromboxane B2; Time Factors; Transaminases

We analyzed the in vitro effects of sorbitol and fructose on platelet function. Sorbitol and fructose increased platelet aggregation induced with adenosine diphosphate (ADP) or collagen in whole blood, but had no effect in platelet-rich plasma. The concentration that increased basal aggregation by 50% with ADP as the inducer was 12.89 +/- 1.55 mmol/L for fructose, and 18.99 +/- 2.01 mmol/L for sorbitol. When collagen was the inducer, these concentrations were 15.02 +/- 0.98 mmol/L for fructose, and 12.94 +/- 1.57 mmol/L for sorbitol. Both sugars increased, in a concentration-dependent way, the proaggregatory effect of erythrocytes, and erythrocyte uptake of adenosine. Time to uptake of 50% adenosine was 2.1 +/- 0.3 min in control samples, 0.14 +/- 0.01 min in the presence of fructose, and 0.23 +/- 0.03 min with sorbitol. Both sugars reduced vascular prostacyclin synthesis, with 50% inhibitory concentrations of 26.48 +/- 1.97 mmol/L for fructose, and 39.53 +/- 2.81 mmol/L for sorbitol. Both sugars also increased arterial lipid peroxidation by 30% (sorbitol) and 23% (fructose). We conclude that these two sugars enhance platelet function and disrupt the thromboxane/prostacyclin ratio.

Topics: 6-Ketoprostaglandin F1 alpha; Adenosine; Adenosine Diphosphate; Adult; Animals; Aorta; Blood Glucose; Blood Platelets; Collagen; Diabetic Angiopathies; Epoprostenol; Erythrocytes; Fructose; Humans; Hyperglycemia; In Vitro Techniques; Lipid Peroxidation; Male; Platelet Activation; Platelet Aggregation; Rats; Rats, Wistar; Sorbitol; Thromboxane B2