Effect of beta-carboline derivatives on the binding of L-tryptophan and diazepam to bovine and human albumin.

The effects of 12 beta-carboline derivatives on the binding of L-tryptophan and diazepam to bovine and human albumin have been investigated to seek similarities between the indole binding site on albumin and the benzodiazepine receptor in the brain. The binding of L-tryptophan and diazepam was measured at 37 degrees and pH 7.4 by equilibrium dialysis. Norharmane was the most potent inhibitor of the binding of L-tryptophan and diazepam to both bovine and human albumin. The kinetics of the inhibitory effects of several of the beta-carbolines were studied. Norharmane decreased the value (n) for the number of binding sites for the binding of L-tryptophan to both bovine and human albumin. Norharmane and harmane decreased the apparent association (Ka) but increased n for the interaction of diazepam with bovine albumin. Norharmane also had a similar effect on the binding of diazepam to human albumin. The similarities between the inhibitory effects of the beta-carbolines on the binding of L-tryptophan and diazepam to albumin and the affinity of the beta-carbolines for the central benzodiazepine receptor point to some common structural requirements for binding to the receptor and to albumin.

Brain uptake of L-tryptophan and diazepam: the role of plasma protein binding.

The brain uptake index (BUI) of L-tryptophan and diazepam into the right and left hemispheres and the cerebellum has been measured after a bolus injection into the carotid artery of the anaesthetised rat. The effect of a range of albumin concentrations (38 microM to 1.4 mM; 0.25-9 g/100 ml) on the viscosity and osmotic pressure of the bolus was studied as a preliminary to the brain uptake experiments. Dextran (Mr 60,000-90,000) was included in the injection to ensure constant viscosity and osmotic pressure. An increase in albumin concentration up to 2 g/100 ml substantially reduced the BUI of L-tryptophan, but a further increase in albumin concentration up to 9 g/100 ml resulted in only a slow fall in the BUI of L-tryptophan which was not proportional to the larger fall in the concentration of unbound L-tryptophan. Furthermore, the use of norharmane as an inhibitor of L-tryptophan binding did not reveal a simple relationship between its unbound concentration and BUI. A decrease in the unbound concentration of diazepam also reduced its BUI, but again there was no straightforward relationship between this and unbound diazepam concentration. The differences observed in the BUI of inulin from solutions of either dextran or albumin indicate not only that each macromolecule may exert particular effects on the BUI, perhaps by an influence on cerebral blood flow, but also show how difficult it is to devise solutions for injection which differ in respect of only one variable, that of the unbound ligand concentration.

Milk transfer of rhein in the rhesus monkey.

A HPLC method was developed to measure rhein, a laxatively active metabolite of sennosides A + B, in milk and plasma. Samples from 2 lactating rhesus monkeys were taken over 48 h after oral administration of sennosides (1 mg kg-1). Detectable rhein levels were found in plasma between 2 and 12 h and in milk between 4 and 12 h after administration, but rhein excretion in milk seems to be far below the dose necessary to elicit a laxative effect in the suckling offspring.