David J. Moore

High-performance liquid chromatographic assay for the antitumor glycoside phyllanthoside and its stability in plasma of several species

Phyllanthoside is a glycoside isolated from the roots of the Central American tree Phyllanthus acuminatus Vahl with antitumor activity against murine B-16 melanoma and P-388 leukemia. We report a reversed-phase high-performance liquid chromatographic assay for phyllanthoside in plasma using a 25-cm RP-18, 5-micron column with a linear 10-min gradient of 50% to 100% methanol in 0.3 M sodium acetate, pH 4.0, at a flow-rate of 1.5 ml/min. Eluting peaks were detected at 270 nm. The lower limit of sensitivity of the assay for phyllanthoside in 0.5 ml plasma following ethyl acetate extraction at pH 7.0 was 0.25 micrograms/ml and the coefficient of variation at 1 microgram/ml was +/- 7.4%. Phyllanthoside was very rapidly broken down by mouse and rat plasma in vitro to an unidentified less polar metabolite. Formation of this metabolite was completely inhibited by preheating mouse plasma to 100 degrees C for 10 min. When mouse plasma was diluted 1:50 with water the half-life of phyllanthoside disappearance at 37 degrees C was 2.0 min. Breakdown of phyllanthoside in plasma from other species was slower than in mouse and the initial half-life at 37 degrees C in dog plasma was 30 min, in monkey plasma 33 min and in human plasma 38 min. The same less polar metabolite as in mouse plasma was formed slowly by plasma of monkey and dog. Phyllanthoside did not accumulate in human red blood cells. Binding of phyllanthoside to human plasma protein determined by ultrafiltration at 4 degrees C was 70%.

A high-performance liquid chromatography assay for measuring integrated biphenyl metabolism by intact cells: Its use with rat liver and human liver and kidney

A rapid, sensitive high-performance liquid chromatography assay with fluorescence detection for measuring biphenyl metabolism by intact cells has been developed. The assay does not require organic solvent extraction or enzymatic digestion for the measurement of hydroxybiphenyl conjugates. The lower limit of detectability for 4-hydroxybiphenyl is 5 pmol injected. Rat hepatocytes incubated with biphenyl form predominantly 4-hydroxybiphenyl sulfate with lesser amounts of 4-hydroxybiphenyl glucuronide and free hydroxybiphenyls, and small amounts of 3-hydroxybiphenyl sulfate and 3-hydroxybiphenyl glucuronide. Slices of fresh human liver incubated with biphenyl form predominantly 4-hydroxybiphenyl glucuronide with some free hydroxybiphenyl and small amounts of 4-hydroxybiphenyl sulfate. 4-Hydroxybiphenyl glucuronide formation by human liver shows a lag time that is not abolished by preincubating the liver without substrate. Human kidney slices incubated with biphenyl form 4-hydroxybiphenyl glucuronide and 4-hydroxybiphenyl sulfate at rates less than one-tenth those seen with human liver. Human kidney slices do not form detectable free hydroxybiphenyl. There is wide intersubject variability in the rates of hydroxybiphenyl metabolite formation by human liver and kidney.

In vitro cytotoxicity of pyrazine-2-diazohydroxide: specificity for hypoxic cells and effects of microsomal coincubation

SummaryThe antitumor drug pyrazine-2-diazohydroxide exhibits cytotoxicity to A204 tumor cells in vitro under acid conditions. The IC50 with a 1 hr drug exposure at pH of 7.4 was 61 μg/ml and at pH of 6.0 it was 31 μg/ml. It is suggested that the increased cytotoxicity is due to the acid catalyzed formation of a reactive pyrizinyldiazonium ion from pyrazine-2-diazohydroxide. Pyrazine-2-diazohydroxide is also more cytotoxic to A204 cells under hypoxic conditions in the presence of glucose with an IC50 at pH 7.4 of 22 μg/ml. The increased cytotoxicity of pyrazine-2-diazohydroxide under acid and hypoxic conditions may favor selective toxicity to solid tumors in vivo. Coincubation with rat hepatic microsomes increased the cytotoxicity of pyrazine-2-diazohydroxide to A204 cells. The effect did not require NADPH and was not due to formation of metabolites. There was an increased rate of degradation of pyrazine-2-diazohydroxide in the presence of microsomes, presumably with formation of the pyrizinyldiazonium ion. The final degradation product 2-hydroxypyrazine was not cytotoxic to A204 cells. The effect of microsomes on pyrazine-2-diazohydroxide cytotoxicity is probably of little in vivo significance.

Gas chromatographic assay for the new antitumor agent pyrazine-2-diazohydroxide (diazohydroxide) and its stability in buffer, blood and plasma

Diazohydroxide is a new antitumor agent being considered for clinical trial. A sensitive and specific assay for diazohydroxide in physiological media, plasma and blood has been developed based on conversion of diazohydroxide to 2-chloropyrazine in the presence of strong hydrochloric acid. The 2-chloropyrazine is extracted into the ethyl acetate and separated by capillary gas chromatography with nitrogen-phosphorus detection. Using 0.2 ml plasma the assay was linear up to 100 micrograms/ml diazohydroxide and had a lower limit of detectability for diazohydroxide of 50 ng/ml. The coefficient of variation of the assay at 1 micrograms/ml was 6.7%. Breakdown of diazohydroxide was rapid under mild acid conditions but slower under alkaline conditions,. The half-life of diazohydroxide in 0.1 M sodium phosphate buffer, pH 6.0, at room temperature was 5 min and at pH 8.0, 480 min. Breakdown of diazohydroxide in plasma was biphasic. In fresh mouse plasma diazohydroxide had a terminal half-life at 37 degrees C of 72 min while in fresh human plasma the terminal half-life was 23 min and in fresh blood 21 min. Diazohydroxide accumulated in red blood cells at 37 degrees C to a concentration 68% above the concentration in plasma. Diazohydroxide was 49% bound to human plasma proteins at room temperature.

Disposition and metabolism of the antitumor agent pyrazine-2-diazohydroxide in mouse and beagle dog

SummaryThe pharmacokinetics and metabolism of pyrazine-2-diazohydroxide have been studied in the beagle dog and mouse. When pyrazine-2-diazohydroxide was administered to beagle dogs at a dose of 18.6 mg/kg (428 mg/m2) by i. v. bolus, the plasma half-life (t1/2) was 7.3 min, the apparent volume of distribution (Vd) 577 ml/kg, and the total body clearance (Cl) 55 ml/min per kg. In mice given pyrazine-2-diazohydroxide by i. v. bolus at 100 mg/kg (428 mg/m2), the t1/2 was 5.8 min, the Vd 250 ml/kg, and the Cl 30 ml/min per kg. When [2-14C]pyrazine-2-diazohydroxide was infused i. v. to mice at 100 mg/kg over 8 h, the Cl for parent drug was 122 ml/min per kg. The major product formed from pyrazine-2-diazohydroxide was 2-hydroxypyrazine, which accounted for 80% of the total radioactivity in the plasma after a 6-h drug infusion. These were three other metabolites in plasma, two more polar than pyrazine-2-diazohydroxide, which accounted for 7% of the radioactivity, and one less polar, which accounted for 5% of the radioactivity. Following an i. v. bolus dose of [2-14C]pyrazine-2-diazohydroxide, 79% of the radioactivity was excreted in the urine in 24 h, 3% in the feces, and 0.4% in the expired air; 18% remained in the carcass. The liver and kidney showed the highest tissue levels of radioactivity. 2-Hydroxypyrazine accounted for 45% of the urinary radioactivity, pyrazine-2-diazohydroxide for 14%, and a glucuronide or sulfate conjugate of 2-hydroxypyrazine for 17%. Twenty-four percent of the radioactivity eluted near the void volume on high-performance liquid chromatography and was not identified.

Disposition and metabolism of the antitumor glycoside phyllanthoside in mouse and beagle dog

SummaryPhyllanthoside is a naturally occurring glycoside with activity against IP transplantable murine tumors. Phyllanthoside administered IV, to mice at a nontoxic dose of 16 mg/kg could not be detected in blood or plasma even 30 s after administration. There was rapid formation of a less polar metabolite, which disappeared with a half-life of about 10 min. When phyllanthoside was administered as an IV bolus to beagle dogs at doses of 0.1, 0.5, and 3.0 mg/kg the mean half-life of phyllanthoside elimination from plasma was 1.3 min and total body clearance 85.8 ml min-1 kg-1. A second phase of elimination was seen but could not be accurately defined. Only trace amounts of the less polar metabolite were detected in dog plasma. Infusion of phyllanthoside to beagle dogs at doses of 0.5 and 3.0 mg/kg over 70 min gave values for an initial half-life of 0.3 and 0.6 min, a terminal half-life of 99.4 and 16.5 min, and a total body clearance of 11.2 and 49.2 ml min-1 kg-1, respectively. The highest nontoxi dose of phyllanthoside in dog was 0.1 mg/kg, while doses of 0.5 mg/kg and 3.0 mg/kg resulted in ataxia and death of the dog. There was no difference in toxicity to dog according to whether phyllanthoside was given by IV bolus or continuous infusion. Isolated hepatocytes from rat metabolized phyllanthoside at a rate of 4.4 μg/min per 106 cells to form the less polar metabolite. Coculture with isolated hepatocytes decreased the cytotoxicity of phyllanthoside to A204 human rhabdomyosarcoma cell line growing in soft agarose. It is suggested that rapid metabolism of phyllanthoside in mouse as against dog might account for the lower toxicity of phyllanthoside in mouse, and might also account for the reported poor antitumor activity of IV-administered phyllanthoside in the mouse.

Isolation, identification and biological activity of a phyllanthoside metabolite produced in vitro by mouse plasma

SummaryThe antitumor agent phyllanthoside is rapidly metabolized in vitro by mouse plasma [4]. This metabolite has now been isolated from mouse plasma and its structural properties and cytotoxicity characterized. The isolated metabolite was estimated to be >98% pure by HPLC analysis. Mass spectral analysis (fast atom bombardment and tandem mass spectrometry) indicated that the metabolite was the aglycone of phyllanthoside that resulted from the cleavage of the ester bond linking the aglycone and the disaccharide moieties of phyllanthoside. This identification was based on identical collision-induced dissociation spectra of both phyllanthoside and the metabolite. The aglycone was not formed by mouse plasma that had been boiled, filtered to remove proteins, or treated with 1.0 mM diisopropyl fluorophosphate. These results suggest that aglycone formation occurs as a result of plasma esterase activity. Michaelis-Menten constants, Vmax and Km, for conversion of phyllanthoside to the aglycone at 22°C were estimated to be 1.1 mmol/ml plasma/min and 2.0 mM, respectively. Concentrations of phyllanthoside and metabolite required to inhibit cell-colony formation by human A204 rhabdomyosarcoma in vitro were 0.47 nM and 24 μM, respectively. The toxicity of phyllanthoside, and perhaps its efficacy as an antitumor agent in mice, may depend on its rate of conversion to the aglycone.