Constitutive variability in the pharmacokinetics of the natural retinoid, all-trans-retinoic acid, and its modulation by ketoconazole.

BACKGROUND: All-trans-retinoic acid (all-trans RA) induces complete remission in most patients with acute promyelocytic leukemia (APL). However, continuous oral dosing results in progressive decline in plasma drug concentrations, which is associated with relapse and resistance to this retinoid. We speculated that the decline in drug levels, indicating acquired resistance, resulted partly from inducible cytochrome-P450 oxidative enzymes, which can catabolize all-trans RA. PURPOSE: We studied the clinical pharmacology of all-trans RA in cancer patients to determine possible mechanisms of acquired resistance and evaluated the potential for reversal by ketoconazole, an inhibitor of cytochrome-P450 oxidative enzymes. METHODS: Serial plasma samples were obtained from 54 patients with APL or advanced lung cancer after a single oral dose of all-trans RA (45 mg/m2). In the 34 patients with advanced lung cancer, all-trans RA (45 mg/m2) was administered twice daily for 4 weeks, and, on days 2, 28, and 29, serial plasma samples were again obtained after a single 45-mg/m2 dose. One hour prior to drug administration on days 2 and 29, a single oral dose (200-1200 mg) of ketoconazole was administered. Endogenous plasma concentrations of all-trans RA and 13-cis-retinoic acid were measured in a subset of these patients and in 11 with early-stage lung cancer. RESULTS: The mean area under the curve for plasma drug concentration times time (AUC) for all-trans RA on day 1 varied substantially among patients. Compared with patients with APL, the 28 patients with advanced lung cancer who completed therapy demonstrated significantly lower AUC levels on day 1 (P = .06); a subgroup with levels less than 300 ng/mL per hour on day 1 had lower endogenous plasma all-trans RA concentrations than patients with APL or early-stage lung cancer or 14 normal subjects. Following continuous oral treatment, the mean day 28 AUC for all-trans RA was significantly lower than that on day 1 (213 ng/mL per hour versus 467 ng/mL per hour; P < .01), a decline significantly attenuated by ketoconazole, which increased the mean plasma all-trans RA AUC on day 29 to 375 ng/mL per hour (P < .01). CONCLUSION: Reported variability for the pharmacokinetics of all-trans RA may result from disease-related or population-based differences in basal catabolic rates influenced by genetic or environmental factors. However, the pattern of inducible catabolism of all-trans RA is not disease specific. Ketoconazole attenuates this accelerated catabolism, suggesting that oxidation by cytochrome-P450 enzymes is an important pathway for both constitutive and induced pathways of all-trans RA metabolism.

Clinical pharmacology of oral all-trans retinoic acid in patients with acute promyelocytic leukemia.

All-trans retinoic acid (RA) induces leukemic cell differentiation and complete remission in a high proportion of patients with acute promyelocytic leukemia (APL). However, remissions induced by all-trans RA tend to be brief, and relapses are associated with resistance to further treatment in vivo, although the leukemic cells appear to retain sensitivity to the cytodifferentiating effects of all-trans RA in vitro. The clinical pharmacology of all-trans RA was examined in 13 patients with APL. The drug was administered at a constant dose of 45 mg/m2/day, given as a single dose on the first day of therapy and in two divided doses thereafter. Plasma and urinary concentrations of the parent drug and metabolites were quantitated by reverse-phase high-performance liquid chromatography and, where required, by a combination of normal-phase liquid chromatography/negative chemical ionization mass spectrometry. In patients with APL, basal levels of endogenous retinol and natural retinoids were within the normal range. Peak plasma levels of all-trans RA (347 +/- 266 ng/ml, mean +/- SD) were reached 1-2 h after drug ingestion and decayed in a monoexponential fashion with a half-life of 0.8 +/- 0.1 h. The only drug metabolite detected in plasma or urine was 4-oxo-all-trans RA (present in urine as the glucuronide conjugate). This metabolite accounted for less than 10% of the circulating drug in plasma, and its cumulative urinary excretion accounted for less than 1% of the administered dose. The drug was not found in cerebrospinal fluid. Continued oral administration of all-trans RA was associated with a significant decrease in both the plasma peak levels and the area under the concentration-time curve (P = 0.01 and 0.004, respectively) when measured after 2-6 weeks of treatment. We previously reported that a decrease in plasma area under the concentration-time curve was highly correlated with clinical relapse. Observations in a subset of patients in this study suggested that, in fact, the major decrease occurred early, within the first 7 days of treatment. These changes were associated with a 10-fold increase in urinary excretion of 4-oxo-all-trans RA glucuronide, suggesting that the accelerated clearance from plasma was associated with increased drug catabolism. The rapid disappearance may explain early relapse from remissions induced by all-trans RA; clinical "resistance" to all-trans RA may either wholly or in part result from an inability to sustain effective plasma concentrations of all-trans RA during continuous treatment.(ABSTRACT TRUNCATED AT 400 WORDS)

Clinical pharmacology of all-trans retinoic acid.

The clinical pharmacology of all-trans retinoic acid (RA) has distinct differences from that of its widely studied stereoisomer 13-cis retinoic acid (cRA). RA is much more rapidly cleared from plasma following oral administration; their respective half-lives are < 1 h and 13 h. There is extensive accumulation of the 4-oxo-cRA in plasma following repeated doses of cRA, while 4-oxo-RA is only a minor metabolite in plasma following RA administration. The extent of isomerization in vivo differs for the two retinoids. In contrast to cRA, where up to a 1:3 ratio of RA to cRA is observed in patient plasma following drug administration, cRA concentrations in excess of 10 ng/ml are rarely observed in plasma of patients receiving exogenous RA. RA administration produces autoinduction of its own oxidative catabolism; this effect does not occur with cRA. These pharmacokinetic differences have been observed in leukemia and solid tumor patients. Detailed analysis of the results of the population studied suggest that both constitutive and RA-induced hypercatabolism of RA occurs. Both of these hypercatabolic states can be modulated by concurrent administration of ketoconazole, an inhibitor of cytochrome P-450 and lipoxygenase-mediated oxidations.

Clinical pharmacology of all-trans retinoic acid.

The clinical pharmacology of all-trans retinoic acid (RA) has distinct differences from that of its widely studied stereoisomer 13-cis retinoic acid (cRA). RA is much more rapidly cleared from plasma following oral administration; their respective half-lives are < 1 h and 13 h. There is extensive accumulation of the 4-oxo-cRA in plasma following repeated doses of cRA, while 4-oxo-RA is only a minor metabolite in plasma following RA administration. The extent of isomerization in vivo differs for the two retinoids. In contrast to cRA, where up to a 1:3 ratio of RA to cRA is observed in patient plasma following drug administration, cRA concentrations in excess of 10 ng/ml are rarely observed in plasma of patients receiving exogenous RA. RA administration produces autoinduction of its own oxidative catabolism; this effect does not occur with cRA. These pharmacokinetic differences have been observed in leukemia and solid tumor patients. Detailed analysis of the results of the population studied suggest that both constitutive and RA-induced hypercatabolism of RA occurs. Both of these hypercatabolic states can be modulated by concurrent administration of ketoconazole, an inhibitor of cytochrome P-450 and lipoxygenase-mediated oxidations.

Hydroxyl radical production and DNA damage induced by anthracycline-iron complex.

Adriamycin-Fe3+ complex catalyzes the formation of hydroxyl radical from hydrogen peroxide but the DNA-adriamycin-iron ternary complex is much more effective. 11-Deoxyadriamycin, which shows no spectral evidence of complex formation with iron, was ineffective. The generation of hydroxyl radical by adriamycin-Fe3+ complex in the presence of DNA correlates with its ability to cleave DNA. Hydroxyl radicals are thus implicated as the reactive oxygen species involved in the DNA damage caused by the adriamycin-Fe3+ complex.

The comparative pharmacokinetics of pentamethylmelamine in man, rat, and mouse.

The pharmacokinetics of pentamethylmelamine (PMM) have been investigated in mouse (Balb C-, CBA/LAC, nude), rat (Wistar), and man. In all three species, PMM was extensively demethylated to N2,N2,N4,N6-tetramethylmelamine and N2,N4,N6-trimethylmelamine, although marked species differences in the rate of metabolism were observed. PMM metabolism was more rapid in the mouse (plasma t1/2 = less than 15 min) than in the rat (plasma t1/2 = 40 min), and slower in man (plasma t1/2 = 102 min) than in either mouse or rat. Furthermore, the peak plasma concentrations of N-methylolmelamines, intermediates generated during oxidative N-demethylation, were correspondingly higher in the mouse (563-773 microM) than in the rat (211 microM), whilst in man they were undetectable (less than 50 microM). In view of the highly cytotoxic nature of N-methylolmelamines, we conclude that these pharmacokinetic differences may be related to the antitumour effectiveness of PMM in mouse, rat, and man.

Modulation of all-trans retinoic acid pharmacokinetics by liarozole.

Continuous oral dosing with all-trans retinoic acid (RA) is associated with a progressive decrease in plasma drug concentrations that has been linked to relapse and retinoid resistance in patients with acute promyelocytic leukemia (APL). Since oxidation by cytochrome P-450 enzymes is critical in the catabolism of this drug, we evaluated whether pretreatment with an inhibitor of this system, liarozole, could attenuate this phenomenon. A total of 20 patients with solid tumors completed a 4-week course of all-trans RA therapy. On days 1, 2, 28, and 29, serial plasma samples were obtained from these patients after ingestion of a single oral dose (45 mg/m2) of all-trans RA. On days 2 and 29, liarozole was given 1 h prior to ingestion of all-trans RA at single doses ranging from 75 to 300 mg. The areas under the plasma RA concentration x time curves (AUCs) were then compared in the presence and absence of pretreatment. Following continuous oral treatment, the mean day-28 AUC of all-trans RA was significantly lower than the group mean level on day 1 (504 vs 132 ng h-1 ml-1; P = 0.05). This decline in plasma concentrations on day 28 was partially reversed by liarozole, which increased the mean plasma all-trans RA AUC on day 29 to 243 ng h-1 ml-1 (P = 0.004). The lowest dose of liarozole that reliably produced this effect was 300 mg. No enhanced toxicity was associated with liarozole administration. We conclude that liarozole at a dose of 300 mg effectively attenuates the induced decline in all-trans RA plasma concentrations that occurs with continuous treatment. This combination may be useful in attenuating or reversing retinoid resistance.

A phase I/II pharmacokinetic and pharmacogenomic study of calcitriol in combination with cisplatin and docetaxel in advanced non-small-cell lung cancer.

BACKGROUND: Preclinical studies demonstrated antiproliferative synergy of 1,25-D3 (calcitriol) with cisplatin. The goals of this phase I/II study were to determine the recommended phase II dose (RP2D) of 1,25-D3 with cisplatin and docetaxel and its efficacy in metastatic non-small-cell lung cancer. METHODS: Patients were ≥18 years, PS 0-1 with normal organ function. In the phase I portion, patients received escalating doses of 1,25-D3 intravenously every 21 days prior to docetaxel 75 mg/m(2) and cisplatin 75 mg/m(2) using standard 3 + 3 design, targeting dose-limiting toxicity (DLT) rate <33 %. Dose levels of 1,25-D3 were 30, 45, 60, and 80 mcg/m(2). A two-stage design was employed for phase II portion. We correlated CYP24A1 tagSNPs with clinical outcome and 1,25-D3 pharmacokinetics (PK). RESULTS: 34 patients were enrolled. At 80 mcg/m(2), 2/4 patients had DLTs of grade 4 neutropenia. Hypercalcemia was not observed. The RP2D of 1,25-D3 was 60 mcg/m(2). Among 20 evaluable phase II patients, there were 2 confirmed, 4 unconfirmed partial responses (PR), and 9 stable disease (SD). Median time to progression was 5.8 months (95 % CI 3.4, 6.5), and median overall survival 8.7 months (95 % CI 7.6, 39.4). CYP24A1 SNP rs3787554 (C > T) correlated with disease progression (P = 0.03) and CYP24A1 SNP rs2762939 (C > G) trended toward PR/SD (P = 0.08). There was no association between 1,25-D3 PK and CYP24A1 SNPs. CONCLUSIONS: The RP2D of 1,25-D3 with docetaxel and cisplatin was 60 mcg/m(2) every 21 days. Pre-specified endpoint of 50 % confirmed RR was not met in the phase II study. Functional SNPs in CYP24A1 may inform future studies individualizing 1,25-D3.

A prospective clinical trial of cholecalciferol 2000 IU/day in colorectal cancer patients: evidence of a chemotherapy-response interaction.

BACKGROUND: We have previously reported a negative correlation between the effect of chemotherapy and 25-hydroxy vitamin D(3) (25-D(3)) levels in patients with colorectal cancer. Based on this finding, we hypothesized that the response to vitamin D(3) supplementation may be attenuated in patients with colorectal cancer. AIM: To determine 25-D(3) response to 2000 IU/day vitamin D(3) supplementation in patients with colorectal cancer. MATERIALS AND METHODS: Fifty evaluable colorectal cancer patients were treated with vitamin D(3) at 2000 IU/day for 6 months. Serum 25-D(3) levels were measured at baseline, 3, and 6 months of supplementation. RESULTS: The mean 25-D(3) level was 17.5 ng/ml at baseline, 31.6 ng/ml at 3 months, and 33.8 ng/ml at 6 months. The most important factor in determining 25-D(3) response was chemotherapy status. A rise in 25-D(3) of ≥10 ng/ml at the 3-month interval was observed in 92% of chemotherapy-free patients vs. 39% of chemotherapy patients. Similar differences in response were noted at the 6-month interval. CONCLUSION: Depressed 25-D(3) levels are common in patients with colorectal cancer. Active chemotherapy is associated with an attenuated response to 2000 IU of D(3) supplementation in this patient population. Alternative vitamin D(3) dosing schedules need further investigation in colorectal cancer patients undergoing chemotherapy.

A randomized phase II study of two doses of vorinostat in combination with 5-FU/LV in patients with refractory colorectal cancer.

BACKGROUND: Vorinostat is synergistic with 5-FU in vitro and in vivo models. A combination of these two agents was associated with clinical activity in 5-FU refractory colorectal cancer patients in a phase I clinical trial, therefore warranting the conduct of this prospective phase II study. PATIENTS AND METHODS: Patients with refractory metastatic colorectal cancer were randomized in a two-stage design to receive vorinostat at 800 or 1,400 mg/day once a day × 3, every 2 weeks. 5-FU, preceded by leucovorin, was administered as a bolus followed by a 46-h infusion on days 2 and 3 of vorinostat. A pre-specified 2-month progression-free survival (PFS) rate of 27/43 patients per arm was needed to deem an arm interesting for further investigation. RESULTS: The high-dose vorinostat arm did not reach the needed efficacy endpoint at completion of the first stage, with only 8 out of 15 patients being alive and progression free at 2 months. The low-dose vorinostat arm proceeded to accrue 43 patients with a 2-month PFS rate of 53% (23 out 43), including one partial response. The median PFS and overall survival on the low-dose arm were 2.4 and 6.5 months, respectively. Both treatment arms were well tolerated. No differences were noted in the pharmacokinetics of vorinostat at the 800- or 1,400-mg dose-levels, suggesting bioavailability saturation. CONCLUSIONS: While the addition of vorinostat to 5-FU resulted in 1 partial response and in some disease stabilizations, the limited activity does not warrant the unselected use of this combination in chemotherapy-refractory colorectal cancer.

Specific and sensitive high-performance liquid chromatographic method with fluorescence detection for measurement of lometrexol and its polyglutamates in biologic samples.

A reversed-phase high-performance liquid chromatographic (HPLC) assay is described for the quantitative determination of lometrexol in biological samples; the assay is rapid, simple, specific, and highly sensitive. The method requires the dissociation of lometrexol from folate-binding proteins present in blood and formation of a fluorescent oxidized derivative of the compound. The dissociation of lometrexol from folate-binding proteins was achieved by acidification to pH 3.5 using ammonium formate, followed by serum protein precipitation with perchloric acid. The protein-free lometrexol was subsequently oxidized by MnO2 at 90 degrees C for 10 min. Chromatographic separation of lometrexol without interference was achieved on a C18 reversed-phase column with a convex gradient, using acetonitrile-0.1% ammonium formate, pH 7.0, as the mobile phase. In human serum and urine the calibration curve was linear between 5 and 300 nM. The lower limit of quantification was 5 nM. The method has been applied successfully to measure serum and urinary levels of lometrexol in patients.

5-Iminodaunomycin. An anthracycline with unique properties.

5-Iminodaunomycin forms a 3:1 complex with Fe(III) at pH 7.4. Drug-metal complex formation is associated with a marked decline in absorbance at 548 and 593 nm and the appearance of a broad band above 625 nm. The 5-iminodaunomycin-Fe(III) complex reacts with hydrogen peroxide to yield .OH radicals. This reaction is at a maximum at a drug/iron ratio of 2:1, and the yield is far less than that obtained with the doxorubicin-iron complex. In contrast to the results with doxorubicin, the production of .OH declines markedly at high 5-iminodaunomycin/iron ratios. There is a close parallel between the formation of hydroxyl radicals and the ability of the 5-iminodaunomycin complex to nick supercoiled SV40 DNA. The suppression of both .OH and DNA damage at high 5-iminodaunomycin:iron ratios is the result of several factors. 1) The presence of DNA stimulates .OH production from the doxorubicin complex, but not 5-iminodaunomycin; 2) doxorubicin reduces its chelated Fe(III) to Fe(II), but 5-iminodaunomycin does not; 3) 5-iminodaunomycin forms such a stable drug-metal complex that solvent water and, therefore, presumably H2O2, has diminished access to the chelated iron. The affinity of 5-iminodaunomycin is such that it can quantitatively abstract iron from doxorubicin. As a result, 5-iminodaunomycin is an effective competitive inhibitor of .OH radical formation by the doxorubicin-iron complex.

Pentamethylmelamine (PMM): Phase I clinical and pharmacokinetic studies.

PMM is a water-soluble alternative to HMM. PMM has been administered as an intravenous infusion to 17 patients in a Phase I clinical trial. The dose-limiting toxicities were nausea and vomiting which were observed in all patients at 500 mg m-2 and above. The dose was not escalated above 1300 mg m-2 where nausea and vomiting were severe, prolonged (greater than 24 h) and poorly controlled by anti-emetics. Haematological, hepatic and renal toxicities were not observed. Neurological toxicity was not observed at low doses (less than 500 mg/m2) but could not be determined at higher doses due to intensive anti-emetic therapy. Pharmacokinetic studies (100-500 mg m-2) indicated that PMM plasma levels are dose-dependent and that the PMM disposition-phase half-life is prolonged in patients with abnormal liver function. It is concluded that the severe toxicity of PMM will limit the clinical utility of this compound and hence Phase II trials are not recommended.