A randomised clinical study of verapamil in addition to combination chemotherapy in small cell lung cancer. West of Scotland Lung Cancer Research Group, and the Aberdeen Oncology Group

Influence of S9788, a new modulator of multidrug resistance, on the cellular accumulation and subcellular distribution of daunorubicin in P-glycoprotein-expressing MCF7 human breast adenocarcinoma cells

A triazinoaminopiperidine derivative synthesized as a modulator of multidrug resistance, S9788, was investigated in the human breast adenocarcinoma MCF7DXR cell line expressing P-glycoprotein. In addition to being less sensitive to daunorubicin, the resistant cell line showed dramatic alterations in the subcellular distribution of daunorubicin, as observed via fluorescence microscopy and quantified via tritiated daunorubicin nuclear distribution analysis. Compared to verapamil and cyclosporin A at 2 and 5 mumol/liter, S9788 proved to be more potent in restoring the cellular accumulation and the subcellular distribution of daunorubicin in the resistant cells. Significant activity of S9788 was observed at 2 mumol/liter, which is clinically achievable, and S9788 restored the nuclear distribution of the drug to the level observed in the parental sensitive cell line. Consequently, the restoration of the cytotoxicity of daunorubicin by S9788 was nearly complete (> 90%) at 2 mumol/liter, wheras cyclosporin A reached this level of activity at 5 mumol/liter, and verapamil was always less active at both concentrations. These results suggest that the modulation of multidrug resistance by S9788 is not only related to the enhancement of the cellular accumulation but also especially by the restoration of the subcellular distribution of the drugs to their nuclear sites of action.

Antitumour effects and pharmacokinetics of combination of vinblastine with a staurosporine derivative, NA-382, in P388/ADR-bearing mice

The effects of a staurosporine derivative, N-ethoxycarbonyl-7-oxostaurosporine (NA-382), on the pharmacokinetics of vinblastine were evaluated, compared with those of verapamil, in multidrug-resistant P388/ADR-bearing mice. At first, the in-vitro experiments indicated that NA-382 permeated into the cells better and were more effective in combined cytotoxicity with vinblastine and on accumulation of vinblastine than with verapamil in P388/ADR cells. In combined intraperitoneal injection with vinblastine (200 micrograms kg-1) into P388/ADR-bearing mice, NA-382 in a suspension form (10 mg kg-1) prolonged the life-span of the mice near to that of P388/S-bearing mice treated with vinblastine alone, but verapamil even at the maximum tolerated dosage (30 mg kg-1) barely affected the in-vivo antitumour effect of vinblastine. When simultaneously administered with vinblastine to P388/ADR-bearing mice, NA-382 maintained significantly higher vinblastine levels in the tumour cells for 24 h and gave a larger area under the time-intracellular vinblastine concentration curve (0 to 24 h) than those receiving vinblastine alone, with long retention of the agent in ascitic fluid. Verapamil increased the cellular vinblastine content for only 6 h, accompanying a rapid elimination of the agent from the ascitic fluid. This study indicates that NA-382 is more effective against multidrug-resistance than verapamil, and its suspension is also advantageous for cancer chemotherapy of multidrug-resistant tumours.

Influence of metabolites on protein binding of verapamil enantiomers

This study investigated the effect of verapamil metabolites on R- and S-verapamil protein binding in plasma samples collected from subjects prior to rac-verapamil dosing and following single dose and steady state rac-verapamil dosing. In vitro studies of the effects of norverapamil, D617 and D620 on R- and S-verapamil protein binding were also performed. Protein binding of R- and S-verapamil was unchanged following single and multiple doses of rac-verapamil as compared with protein binding in pre-dose samples. In vitro, norverapamil had no effect on R- and S-verapamil protein binding up to 1000 ng ml-1. Norverapamil 5000 ng ml-1 caused a 30% increase in free fraction of both R- and S-verapamil. D617 and D620 concentrations up to 5000 ng ml-1 had no effect on R- and S-verapamil protein binding. We conclude the metabolites of verapamil have no clinically significant effect on R- and S-verapamil protein binding.