Hans Peter Dr Rer Nat Wolff

The pharmacological profile of the thromboxane A2 antagonist BM 13.177. A new anti-platelet and anti-thrombotic drug

BM 13.177 (4-[2-(benzenesulfonamido)-ethyl]-phenoxyacetic acid) is a representative of a new class of sulfonamidophenylcarboxylic acids which possess platelet-inhibitory and anti-thrombotic activity and inhibits the contraction of rabbit aorta stimulated by PG endoperoxides and TXA2. BM 13.177 5 mg/kg body weight p.o. protected rabbits from arachidonate-induced sudden death and greater than or equal to 10 mg/kg dose-dependently reduced the experimental thrombus formation induced in the rabbit aorta by perivascular administration of silver nitrate. In guinea-pigs, the collagen-induced bronchoconstriction was inhibited in a dose- and time-dependent fashion. The formation of TXA2 and the TXA2-induced platelet aggregation and smooth muscle contraction are probably crucial events in these experimental models. The protective effect of BM 13.177 may, therefore, be due to the TXA2-antagonizing effect of BM 13.177, which has been conclusively demonstrated in human platelets (PATSCHEKE and STEGMEIER, Thrombosis Res., 33, 277-288 (1984). The antagonism of TXA2 is supported by the observation that BM 13.177 also specifically inhibits the contraction of isolated arterial strips from rabbits which were stimulated with the thromboxane A2 mimetic U 46619. Schild-plot with a slope close to unity suggests a competitive type of antagonism. BM 13.177 exhibited neither anti-inflammatory nor ulcer-inducing activity of cyclooxygenase inhibitors. Furthermore it did not block the TXB2 formation in spontaneously clotting blood from rabbits and did not inhibit the release of prostacyclin-like activity from rabbit aortas. The lack of toxicological effects in long-term toxicity studies in rat and dog, together with the absence of objective and subjective side effects in the first human studies have encouraged us to initiate clinical trials in order to evaluate the therapeutic benefit of this new approach in humans.

(−)-BM 13.0913: A new oral antidiabetic agent that improves insulin sensitivity in animal models of type II (non—insulin-dependent) diabetes mellitus

Insulin resistance is one of the key features of non-insulin-dependent diabetes mellitus (NIDDM). Therefore, a drug that causes an improvement in insulin sensitivity would be of great interest for the treatment of NIDDM. In addition to the insulin-sensitizing thiazolidinediones, we have found another class of insulin-sensitizing agents: the alpha-activated carbonic acids. (-)-BM 13.0913, a member of this class, was effective in improving insulin resistance in hyperinsulinemic and hypoinsulinemic insulin-resistant animal models of NIDDM. The 50% effective dose (ED50) for the glucose-lowering action was 4, 2.4, and 8 mg/kg in ob/ob, yellow KK, and db/db mice, respectively. The ED50 for the insulin-lowering action was 14.5, 5, and 26 mg/kg. This rightward shift of the dose-response curve for insulin indicates that improving glucose homeostasis is the primary effect of the drug, followed by an insulin-decreasing action. This effect on glucose homeostasis may be brought about by sensitizing peripheral target tissues to the effects of insulin. An increase in deoxyglucose uptake and glucose oxidation measured in adipocytes from rats that had been treated for 14 days with (-)-BM 13.0913 supports this conclusion. Glucose uptake and oxidation was increased at all insulin concentrations tested, suggesting an improved responsiveness. Insulin sensitivity in adipocytes was not influenced by the drug. Studies in the moderately hypoinsulinemic, low-dose streptozotocin (STZ) diabetic rat with a residual insulin concentration showed a decrease in blood glucose concentrations, as well as a decrease in urinary glucose.(ABSTRACT TRUNCATED AT 250 WORDS)

Blood-glucose-lowering activity of 2-(3-phenylpropoxyimido)-butyrate (BM 13.677).

A single oral or intraperitoneal application of 2-(3-phenylpropoxyimido)-butyrate (BM 13.677) resulted in a dose-dependent blood-glucose-lowering effect in fasted guinea-pigs. The threshold dose and the EC50 were estimated as 25 mg/kg and 63 mg/kg, respectively, which is between that of the biguanides phenformin and metformin. A rise in blood lactate concentrations was observed only at high doses of BM 13.677, but was not related to an irreversible metabolic inhibition. Among several rodent species studied the potency of the drug decreased in the order guinea-pig much greater than mouse greater than rat = rabbit. Inhibition of hepatic gluconeogenesis by the drug was demonstrated in the perfused liver or hepatocytes of guinea-pigs. Inhibition of glucose production by the perfused liver in the presence of 0.1 mM BM 13.677 was dependent on the substrate and decreased in the order: lactate greater than pyruvate greater than alanine much greater than propionate greater than glycerol = fructose. This suggests a specific interaction of the drug with a mitochondrial key reaction of gluconeogenesis. Stimulation of glucose oxidation in rat diaphragm by the compound (EC50 = 0.85 mM) suggests that besides inhibition of gluconeogenesis also extrahepatic effects contribute to the blood-glucose-lowering effects of the drug.