[One point determination of oral caffeine clearance in patients with liver diseases]. / Einpunktbestimmung der oralen Koffeinclearance bei Patienten mit Lebererkrankungen.

Caffeine clearance has been determined in 117 volunteers and patients (including 27 patients with liver cirrhosis) after oral application of 366.1 mg caffeine according to conventional pharmacokinetic methods (Cl = D/AUC). The resulting clearance values can be estimated with adequate accuracy from the plasma concentration at 12h for a concentration range of 2.0 to 6.5 mg/l according to Cl max = Doses/C 12h x t 12h x e and for concentrations higher than 6.5 mg/l according to Cl = Vd x (1n (D/Vd) - 1n C 12h/t 12h Vd is estimated from body weight as Vd = 0.42 x BW. "One - point" - estimation does not provide reliable data for plasma concentrations below 2.0 mg/l.

Effects of a N(6)-disubstituted adenosine derivative on myocardial metabolism and ischemic stress following coronary occlusion.

The effect of N(6)-phenyl-N(6)-allyladenosine (PAA, BM 11.189) on myocardial ischemic stress was evaluated in six open-chest mongrel dogs during repeated coronary occlusions of 3 min. Whereas there was not significant change in hemodynamic parameters before and during coronary occlusions after treatment, PAA reduced significantly epicardial ST-segment elevations (-34%) during ischemia and myocardial release of lactate (-43%), phosphate (-44%), and potassium (-48%) in the early reperfusion period. PAA lowered significantly arterial non esterified fatty acids and converted oxidative myocardial metabolism from lipid to predominantly carbohydrate utilization, reflected by a shift of cardiac respiratory quotient from 0.81 to 1.01. The beneficial effects of PAA on myocardial ischemic injury could be explained by an improved economy of oxidative myocardial energy supply in the jeopardized border zone of the ischemic myocardium.

Changes in myocardial substrate and energy metabolism by S-(4)-hydroxyphenylglycine and an N-(6)-derivative of adenosine.

In 15 mongrel open chest dogs oxidative myocardial carbohydrate utilization was stimulated by activation of pyruvatedehydrogenase with S-(4)-hydroxyphenylglycine (HPG) or by inhibition of lipolysis with N(6)-allyl-N(6)-cyclohexyladenosine (PAA). HPG and PAA shifted cardiac respiratory quotients (RQ) from 0.83 to 0.89 and 0.99, respectively. Oxygen extraction ratio of lactate was significantly increased by both interventions. Arterial nonesterified fatty acids (NEFA) concentration decreased significantly only by PAA. The oxygen saving potency of both interventions was quantified over a wide hemodynamic range by comparing the directly measured myocardial oxygen consumption (MVO2) with the myocardial energy requirements calculated from its hemodynamic determinants according to the Bretschneider formula during base conditions and beta-stimulation. Inhibition of peripheral lipolysis with PAA reduced MVO2 by 14%, enzyme activation with HPG by 8%. The results show that the efficiency of the myocardial energy supply can be influenced by manipulation of the oxidative substrate metabolism.

Different effects of interventions suppressing free fatty acid metabolism on myocardial ischemia.

We studied the effects of different metabolic interventions, which stimulate oxidative myocardial carbohydrate metabolism, on ischemic stress during repeated coronary occlusions of three minutes in open-chest dog hearts. Increase of glucose concentration in plasma and decrease of peripheral lipolysis by glucose-insulin-potassium (n = 6) had no substantial beneficial effects on myocardial damage indicated by hemodynamic, electrocardiographic, and metabolic parameters. Infusion of lactate and pyruvate (10 mM, n = 6) was detrimental. Only activation of pyruvate dehydrogenase by dichloroacetate (n = 6) without influence on plasma osmolality reduced epicardial ST-segment elevations (-42%) and myocardial release of potassium (-36%), phosphate (-58%), and lactate (-39%). Elevations of plasma osmolalities by 10 and 20 mOsm with the metabolically inert mannitol increased ECG changes, functional loss and release of potassium, phosphate, and lactate during ischemia in our model. It is suggested, that the oxygen-saving potency of metabolic interventions can exert univocal beneficial effects in experimental and in clinical conditions only when systemic hyperosmolality and hypervolemia are avoided.