Plasma pharmacokinetics and tissue distribution of 17-(allylamino)-17-demethoxygeldanamycin (NSC 330507) in CD2F1 mice1.

PURPOSE: 17-(Allylamino)-17-demethoxygeldanamycin (17AAG) is a benzoquinone ansamycin compound agent that has entered clinical trials. Studies were performed in mice to: (1) define the plasma pharmacokinetics, tissue distribution, and urinary excretion of 17AAG after i.v. delivery; (2) to define the bioavailability of 17AAG after i.p. and oral delivery; and (3) to characterize the concentrations of 17AAG metabolites in plasma and tissue. MATERIALS AND METHODS: All studies were performed in female CD2F1 mice. Preliminary toxicity studies used 17AAG i.v. bolus doses of 20, 40 and 60 mg/kg. Pharmacokinetic studies used i.v. 17AAG doses of 60, 40, and 26.67 mg/kg and i.p. and oral doses of 40 mg/kg. The plasma concentration versus time data were analyzed by compartmental and noncompartmental methods. The concentrations of 17AAG were also determined in brain, heart, lung, liver, kidney, spleen, skeletal muscle, and fat. Urinary drug excretion was calculated until 24 h after treatment. RESULTS: A 60 mg/kg dose of 17AAG, in its initial, microdispersed formulation, caused no changes in appearance, appetite, waste elimination, or survival of treated animals as compared to vehicle-treated controls. Bolus i.v. delivery of 60 mg/kg microdispersed 17AAG produced "peak" plasma 17AAG concentrations between 5.8 and 19.3 micrograms/ml in mice killed 5 min after injection. Sequential reduction of the 17AAG dose to 40 and 26.67 mg/kg resulted in "peak" plasma 17AAG concentrations between 8.9 and 19.0 micrograms/ml, and 4.8 and 6.1 micrograms/ml, respectively. Noncompartmental analysis of the plasma 17AAG concentration versus time data showed an increase in AUC from 402 to 625 and 1738 micrograms/ml.min when the 17AAG dose increased from 26.67 to 40 and 60 mg/kg, respectively. Across the range of doses studied, 17AAG total body clearance varied from 34 to 66 ml/min per kg. Compartmental modeling of the plasma 17AAG concentration versus time data showed that the data were fitted best by a two-compartment, open, linear model. In each study, substantial concentrations of a material, subsequently identified as 17-(amino)-17-demethoxygeldanamycin (17AG), were measured in plasma. A subsequent, lyophilized formulation of 17AAG proved excessively toxic when delivered i.v. at 60 mg/kg. A repeat i.v. study using a 40 mg/kg dose of this new formulation produced peak plasma 17AAG concentrations of 20.2-38.4 micrograms/ml, and a 17AAG AUC of 912 micrograms/ml.min, which was approximately 50% greater than the AUC produced by a 40 mg/kg dose of microdispersed 17AAG. The bioavailabilities of 17AAG after i.p. and oral delivery were 99% and 24%, respectively. Minimal amounts of 17AAG and 17AG were detected in the urine. After i.v. bolus delivery to mice, 17AAG distributed rapidly to all tissues, except the brain. Substantial concentrations of 17AG were measured in each tissue. CONCLUSIONS: 17AAG has excellent bioavailability when given i.p. but only modest bioavailability when given orally and is metabolized to 17AG and other metabolites when given i.v., i.p., or orally. 17AAG is widely distributed to tissues. These pharmacokinetic data generated have proven relevant to the design of recently initiated clinical trials of 17AAG and could be useful in their interpretation.

Fragilysin, the enterotoxin from Bacteroides fragilis, enhances the serum antibody response to antigen co-administered by the intranasal route.

Fragilysin, an extracellular zinc metalloprotease produced by enterotoxigenic strains of the anaerobic bacterium Bacteroides fragilis, disrupts the paracellular barrier by cleavage of the intercellular proteins between epithelial cells resulting in fluid secretion. Intranasal immunization of mice with fragilysin and co-administered ovalbumin (Ova) resulted in an Ova-specific serum IgG response that was over 18000-fold higher than Ova alone, as well as detectable levels of serum IgA. Serum IgG titers were comparable with those seen when whole cholera toxin was used as the adjuvant, although the responses obtained with fragilysin showed more variability between mice. Metalloproteases to which fragilysin is structurally related were ineffective as mucosal adjuvants. Our results and similar studies with enterotoxins that affect the paracellular barrier suggest that alteration of mucosal permeability may play an important role in the mechanisms of adjuvanticity.

Pharmacokinetics and antitumor properties in tumor-bearing mice of an enediol analogue inhibitor of glyoxalase I.

PURPOSE: The enediol analogue S-(N-p-chlorophenyl-N-hydroxycarbamoyl)glutathione (CHG) is a powerful, mechanism-based, competitive inhibitor of the methylglyoxal-detoxifying enzyme glyoxalase I. The [glycyl,glutamyl]diethyl ester prodrug form of this compound (CHG(Et)2) inhibits the growth of different tumor cell lines in vitro, apparently by inducing elevated levels of intracellular methylglyoxal. The purpose of this study was to evaluate the pharmacokinetic properties of CHG(Et)2 in plasma esterase-deficient C57BL/6 (Es-1e) mice after intravenous (i.v.) or intraperitoneal (i.p.) administration of bolus doses of CHG(Et)2. In addition, the in vivo antitumor properties of CHG(Et)2 were evaluated against murine B16 melanoma in these mice, and against androgen-independent human prostate PC3 tumor and human colon HT-29 adenocarcinoma in plasma esterase-deficient nude mice. METHODS: Pharmacokinetics were evaluated after either i.v. or i.p. administration of CHG(Et)2 at the maximally tolerated dose of 120 mg/kg to both tumor-free male and female mice and male and female mice bearing subcutaneous B16 tumors. Tissue concentrations of CHG(Et)2, CHG and the [glycyl]monoethyl ester CHG(Et) were measured as a function of time by reverse-phase C18 high-performance liquid chromatography of deproteinized tissue samples. The efficacy of CHG(Et)2 in tumor-bearing mice was evaluated after i.v. bolus administration of CHG(Et)2 at 80 or 120 mg/kg for 5 days each week for 2 weeks, or after 14 days continuous infusion of CHG(Et)2 using Alzet mini-osmotic pumps. Hydroxypropyl-beta-cyclodextrin was used as a vehicle in the efficacy studies. RESULTS: Intravenous administration of CHG(Et)2 resulted in the rapid appearance of CHG(Et)2 in the plasma of tumor-bearing mice with a peak value of 40-60 microM, followed by a first-order decrease with a half-life of about 10 min. There was a corresponding increase in the concentration of inhibitory CHG in the B16 tumors, with a maximum concentration in the range 30-60 microM occurring at 15 min, followed by a decrease to a plateau value of about 6 microM after 120 min. Neither CHG(Et)2 nor its hydrolysis products were detectable in plasma, after i.p. administration of CHG(Et)2 to tumor-free female mice. From the efficacy studies, dosing schedules were identified that resulted in antitumor effects comparable to those observed with the standard antitumor agents Adriamycin (with B16 tumors), cisplatin (with PC3 tumors), and vincristine (with HT-29 tumors). CONCLUSION: This is the first demonstration that a mechanism-based competitive inhibitor of glyoxalase I effectively inhibits the growth of solid tumors in mice when delivered as the diethyl ester prodrug.

Plasma pharmacokinetics and tissue distribution in CD2F1 mice of Pc4 (NSC 676418), a silicone phthalocyanine photodynamic sensitizing agent.

PURPOSE: Pc4 is a silicone phthalocyanine photosensitizing agent that is entering clinical trials. Studies were undertaken in mice to develop a suitable formulation and analytical methodology for use in pharmacokinetic studies and to define the plasma pharmacokinetics, tissue distribution, and urinary excretion of Pc4 after i.v. delivery. METHODS: An HPLC method suitable for separation and quantification of Pc4 was developed and validated for use in mouse plasma, tissues, and urine. The stability of Pc4 was characterized in a variety of formulations as well as in mouse plasma. Before pursuing pharmacokinetic studies, preliminary toxicity studies were undertaken. These studies utilized Pc4 formulated in diluent 12:0. 154 M NaCl (1:3, v:v). Pharmacokinetic studies involved Pc4 doses of 40 mg/kg, 10 mg/kg and 2 mg/kg administered as i.v. boluses to female, CD2F1 mice. Doses of 40 mg/kg, 10 mg/kg, and 2 mg/kg were studied with drug formulated in diluent 12:0.154 M NaCl (1:3, v:v). Doses of 10 mg/kg and 2 mg/kg were also studied with drug formulated in a vehicle consisting of polyethylene glycol:Tween 80:0. 01 M sodium phosphate buffer, pH 7.0 (40:0.2:59.8, v:v:v). Compartmental and non-compartmental analyses were applied to the plasma concentration-versus-time data. Concentrations of Pc4 were also determined in a variety of tissues, including brain, lung, liver, kidney, skeletal muscle, skin, heart, spleen, and abdominal fat. Urine was collected from animals treated with each of the doses of Pc4 mentioned above, and daily, as well as cumulative drug excretion was calculated until 168 h after treatment. RESULTS: At a dose of 80 mg/kg, two of five male and two of five female mice were dead by 24 h after injection. Pathologic examination revealed gross findings of blue discoloration affecting many tissues, with lungs that were grossly hemorrhagic and very blue-black. Microscopic examination of the lungs revealed mild acute interstitial pneumonia, with perivascular edema and inflammation, and a detectable margination of neutrophils around larger pulmonary blood vessels. Animals sacrificed 14 days after treatment showed mild granulomatous pneumonia, characterized by clusters of multi-nucleated giant cells, with fewer macrophages and neutrophils. The giant cells frequently contained phagocytized particles, which were clear and relatively fusiform. All mice treated with 40 mg/kg or 20 mg/kg survived and returned to pretreatment weight during the 14 days after treatment. Intravenous bolus delivery of Pc4, at a dose of 40 mg/kg, produced "peak" plasma Pc4 concentrations between 7.81 and 8.92 microg/ml in mice killed at 5 min after injection (the earliest time studied after drug delivery). Sequential reduction of the Pc4 dose to 10 mg/kg in diluent 12:0.154 M NaCl (1:3, v:v), 10 mg/kg in polyethylene glycol:Tween 80:sodium phosphate buffer (40:0.2:59.8, v:v:v), 2 mg/kg in diluent 12:0.154 M NaCl (1:3, v:v), and, finally, 2 mg/kg in polyethylene glycol:Tween 80:sodium phosphate buffer (40:0.2:59.8, v:v:v) resulted in "peak" plasma Pc4 concentrations between 2.07 and 3.24, 0.68 and 0.98 microg/ml, and 0.29 and 0.41 microg/ml, respectively. Pc4 persisted in plasma for prolonged periods of time (72-168 h). Non-compartmental analysis of plasma Pc4 concentration-versus-time data showed an increase in area under the plasma Pc4 concentration-versus-time curve (AUC) when the dose of Pc4 increased from 2 mg/kg to 40 mg/kg. Across the 20-fold range of doses studied, total body clearance (CL(tb)) varied from 376 to 1106 ml h(-1) kg(-1). Compartmental modeling of plasma Pc4 concentration versus time data showed the data to be fit best by a two-compartment, open, linear model. Minimal amounts of Pc4 were detected in the urine of mice. After i.v. bolus delivery to mice, Pc4 distributed rapidly to all tissues and persisted in most tissues for the duration of each pharmacokinetic study. Tissue exposure, as measured by AUC, increased in a dose-dependent fash

Plasma pharmacokinetics of butyrate after intravenous administration of sodium butyrate or oral administration of tributyrin or sodium butyrate to mice and rats.

PURPOSE: To define the plasma concentrations of butyrate achieved and the profile of plasma butyrate concentrations versus time in mice and rats treated with tributyrin or sodium butyrate. METHODS: Female CD2F1 mice were treated with tributyrin by oral gavage or with sodium butyrate by i.v. bolus or oral gavage. Oral tributyrin doses delivered to mice were 3.1, 5.2, 7.8, and 10.3 g/kg. Intravenous sodium butyrate doses were 0.31, 0.62, 0.94, and 1.25 g/kg. Oral sodium butyrate was given to mice at 5 g/kg. Subsequently, similar studies were performed in female Sprague-Dawley rats. Rats were given tributyrin by oral gavage at doses of 3.6, 5.2, or 10.3 g/kg or sodium butyrate i.v. at a dose of 500 mg/kg. Plasma butyrate concentrations were determined by gas chromatography. RESULTS: In mice, oral dosing with tributyrin resulted in detectable plasma butyrate concentrations as early as at 5 min after treatment and produced peak plasma butyrate concentrations at between 15 and 60 min after dosing. Peak plasma butyrate concentrations increased proportionally with increasing tributyrin dose, but as the oral tributyrin dose increased there was a greater than proportional increase in the area under the curve of plasma butyrate concentrations versus time (AUC). At a tributyrin dose of 10.3 g/kg, plasma butyrate concentrations peaked at approximately 1.75 mM and remained >1 mM for between 10 and 60 min after dosing. However, approximately 10% of mice treated with this dose died acutely. At a tributyrin dose of 7.8 g/kg, plasma butyrate concentrations reached approximately 1 mM by 15 min after dosing and remained between 0.8 and 1 mM until 60 min after dosing. No mouse treated with this dose died acutely. Mice given tributyrin doses of 5.2 and 3.1 g/kg achieved peak plasma butyrate concentrations of approximately 0.9 and 0.5 mM, respectively, by 45 min after dosing. Plasma butyrate concentrations in these mice remained above 0.1 mM until 120 and 90 min after dosing, respectively. The four i.v. doses of sodium butyrate resulted in plasma concentration-time profiles that also indicated nonlinear pharmacokinetics and were well described by a one-compartment model with saturable elimination. Values recorded for the Michaelis-Menten constant (Km) and the maximal velocity of the process (Vmax) ranged between 1.02 and 5.65 mM and 0.60 and 1.82 mmol/min, respectively. Values noted for the volume of the central compartment (Vc) varied between 0.48 and 0.72 l/kg. At 1.25 g/kg, i.v. sodium butyrate produced peak plasma butyrate concentrations of 10.5-17.7 mM, and plasma butyrate concentrations remained above 1 mM for 20-30 min. Sodium butyrate delivered orally to mice at 5 g/kg produced peak plasma butyrate concentrations of approximately 9 mM at 15 min after dosing and plasma butyrate concentrations exceeding 1 mM for 90 min after dosing. In rats the 10.3-g/kg oral dose of tributyrin produced peak plasma butyrate concentrations of approximately 3 mM by 75 min after dosing and butyrate concentrations exceeding 1 mM from 30 to 90 min after dosing. The plasma butyrate concentrations produced in rats by 5.2- and 3.6-g/kg doses were appropriately lower than those produced by the 10.3-g/kg dose, and there was no evidence of nonlinearity. The 500-mg/kg i.v. dose of sodium butyrate produced peak plasma butyrate concentrations in rats of approximately 11 mM, and the decline in plasma butyrate concentrations with time after dosing was consistent with saturable clearance. CONCLUSION: These studies document the ability to use oral administration of tributyrin to achieve pharmacologically relevant concentrations of butyrate in rodent plasma. They also document the nonlinear nature of butyrate clearance. These data are being used in the design of clinical trials of oral tributyrin in patients with malignancies and hemoglobinopathies.

Antitumor activity, distribution, and metabolism of 13-cis-retinoic acid as a single agent or in combination with tamoxifen in established human MCF-7 xenografts in mice.

PURPOSE: The efficacy of 13-cis-retinoic acid (13-CRA) given as a single agent or in combination with tamoxifen (TAM) was determined in athymic nude mice bearing advanced s.c. MCF-7 human breast cancers. METHODS: 13-CRA alone was given by gavage at doses ranging from 26.4 to 200 mg/kg. TAM alone was given by gavage at doses of 7.5, 15, 30, or 60 mg/kg. For combination studies, each dose of TAM was followed 4 h later by 13-CRA at doses of 25, 50, 100, or 200 mg/kg. All treatments began on day 12 and were continued for 3 weeks. RESULTS: The median time to two doublings recorded for the control and for 13-CRA and TAM given as single agents at the highest dose were 22.2, 29.2, and 54.7 days, respectively. In combination, 100 and 200 mg/kg 13-CRA with 7.5 mg/kg TAM resulted in a delay in tumor growth at least as high as that achieved with highest-dose TAM alone, but the effect was not synergistic. Pharmacokinetic analysis of 13-CRA was performed in plasma, liver, and tumor from mice bearing 0.5- to 2.0 g carcinomas following a single dose of 100 mg/kg 13-CRA. Results showed that 13-CRA was metabolized differently in various tissues, but concentrations of 13-CRA detected in tumor were in the range reported to be active in vitro. all-trans-Retinoic acid (ATRA) concentrations were about 5% of the 13-CRA concentrations detected in plasma, 68% of those found in liver, and 20% of those found in tumor. 4-oxo-CRA represented between 2% and 10% of 13-CRA concentrations detected in plasma and liver but was not detected in tumor. Furthermore there was no difference in peak plasma 13-CRA concentrations found in the same tissues at 30 min after a single dose or after the eighth dose of 100 mg/kg 13-CRA or 13-CRA and TAM. Mean 13-CRA concentrations detected in liver and tumor were 50-90% and 16-30% of plasma peak concentrations, respectively. No difference in 4-oxo-CRA concentration was observed between the treatment groups. CONCLUSIONS: These data suggest that 13-CRA is not effective against established human breast tumor xenografts despite the stability of the pharmacokinetics of 13-CRA and the generation of ATRA as a metabolite. The addition of 13-CRA to TAM did not improve the efficacy of TAM against these estrogen-receptor-positive xenografts.

Tumor-targeted apoptosis by a novel spermine analogue, 1,12-diaziridinyl-4,9-diazadodecane, results in therapeutic efficacy and enhanced radiosensitivity of human prostate cancer.

Interference with polyamine transport and biosynthesis has emerged as an important anticancer strategy involving polyamine analogues and specific inhibitors of key biosynthetic enzymes. Because the prostate gland has a high polyamine content, by using the polyamine transporter for selective uptake into cancer cells, alkylating polyamines are likely to be highly effective against prostatic tumors. We have recently synthesized a novel class of spermine analogues, the lead compound of which has efficacy against human cancer cells (P. S. Callery et al., U. S. patent, 5,612,239, Issued March 17, 1997.). In this study, to investigate the potential therapeutic efficacy of the lead spermine analogue 1,12-diaziridinyl-4, 9-diazadodecane (BIS), against advanced prostate cancer, we examined the in vitro effect and in vivo efficacy of the compound in two androgen-independent human prostate cancer cell lines, PC-3 and DU-145. BIS exhibited a dose-dependent cytotoxic effect against prostate cancer cells via induction of apoptosis. Treatment of cells with BIS (1 microM) for 24 h resulted in a significant induction of apoptosis (24%). Exposure of BIS-treated PC-3 prostate cancer cells to gamma-irradiation resulted in a significant increase in the number of cells undergoing apoptosis and a subsequent decrease in the IC50. Furthermore, BIS treatment led to a significant enhancement of loss of clonogenic survival in irradiated prostate cancer cells (both PC-3 and DU-145). In vivo efficacy trials demonstrated a significant antitumor effect of BIS against both PC-3 and DU-145 tumor xenografts in severe combined immunodeficient mice in a dose-dependent pattern at maximally tolerated doses. Terminal transferase end-labeling analysis indicated that BIS-mediated tumor regression in vivo occurs via induction of apoptosis among prostatic tumor cells. These results suggest that the novel spermine analogue BIS: (a) has a potent antitumor effect against prostatic tumors via induction of apoptosis; and (b) increases the radiosensitivity of human prostate cancer cells by decreasing the apoptotic threshold to radiation. This study may have important clinical implications for the manipulation of this antitumor activity of the polyamine analogue for the optimization of the therapeutic efficacy of radiation in patients with advanced prostate cancer.

In vitro metabolism by mouse and human liver preparations of halomon, an antitumor halogenated monoterpene.

OBJECTIVES: To characterize the enzymes responsible for and metabolites produced from the metabolism of halomon, a halogenated monoterpene that is isolated from the red algae Portieria hornemanii and has in vitro activity in the NCI screen against brain, renal, and colon cancer cell lines. MATERIALS AND METHODS: Mouse and human liver fractions, prepared by homogenization and differential centrifugation, were incubated with halomon, extracted with toluene, and analyzed by gas chromatography. RESULTS: In the presence of NADPH, mouse-liver 9,000-g supernatant (S9) fractions metabolized halomon, but boiled S9 fractions did not. NADH could not substitute for NADPH. Further separation of murine hepatic S9 fractions produced a microsomal fraction that contained all of the halomon-metabolizing activity; cytosol had none. Carbon monoxide reduced murine hepatic microsomal metabolism of halomon, whereas an anaerobic, N2 environment greatly accelerated the disappearance of halomon. Human hepatic microsomes metabolized halomon and required NADPH to do so. Carbon monoxide completely inhibited human hepatic microsomal metabolism of halomon. Unlike murine hepatic microsomal metabolism of halomon, anaerobic conditions did not enhance the metabolism of halomon by human hepatic microsomes. Neither 100 microM diethyldithiocarbamate, 1 microM quinidine, 100 microM ciprofloxacin, 3 microM ketoconazole, nor 100 microM sulfinpyrazone inhibited the metabolism of halomon by human hepatic microsomes. Both murine and human hepatic microsomes produced a metabolite of halomon. The mass spectrum of this metabolite indicated the loss of one chlorine atom and one bromine atom. CONCLUSIONS: Halomon is metabolized by mouse and human hepatic cytochrome P-450 enzymes, the identities of which remain unknown. Hepatic metabolism of halomon is very consistent with the concentrations of halomon measured in mouse tissues and urine after i.v. administration of the drug.

Synthesis and antitumor evaluation of a highly potent cytotoxic DNA cross-linking polyamine analogue, 1,12-diaziridinyl-4,9-diazadodecane.

A diaziridinylspermine analogue, 1,12-diaziridinyl-4,9-diazadodecane (NSC-667005), was synthesized as a bisalkylating agent with a polyamine backbone. DNA cross-linking was detected in the reaction of linearized pBR322 DNA with 1,12-diaziridinyl-4,9-diazadodecane at concentrations comparable with that required for cross-linking by two nitrogen mustard drugs, mechlorethamine and melphalan. A significant increase in life span of female CD2F1 mice bearing L1210 murine leukemia was observed after intravenous administration of 1,12-diaziridinyl-4,9-diazadodecane in doses of less than 2.7 mg/kg, given on days 1, 5, and 9 of treatment.

Plasma pharmacokinetics, bioavailability, and tissue distribution in CD2F1 mice of halomon, an antitumor halogenated monoterpene isolated from the red algae Portieria hornemannii.

The purpose of the present study was to define the plasma pharmacokinetics, bioavailability, and tissue distribution in mice of halomon, a halogenated monoterpene from Portieria hornemanii that is active in vitro against brain-, renal-, and colon-cancer cell lines. Halomon formulated in cremophor:ethanol:0.154 M NaCl (1:1:6, by vol.) was injected i.v. at 20, 60, 90, or 135 mg/kg into female CD2F1 mice. Doses of 135 mg/kg were also given i.p., s.c., and by enteral gavage to female CD2F1 mice and i.v. to male CD2F1 mice. Plasma halomon concentrations were measured with a gas-chromatography system using electron-capture detection. Halomon concentrations were also determined in the brains, hearts, lungs, livers, kidneys, spleens, skeletal muscles, fat, red blood cells, and, if present, testes of mice given 135 mg/kg i.v. Halomon plasma pharmacokinetics were well fit by a two-compartment, open linear model and were linear between 20 and 135 mg/kg. Population estimates of parameters describing halomon plasma pharmacokinetics in female CD2F1 mice were developed with a standard two-stage technique and also by simultaneous modeling of data from 20-, 60-, 90-, and 135-mg/kg i.v. studies in female mice. Halomon bioavailability was 45%, 47%, and 4% after i.p., s.c., and enteral dosing, respectively. Urinary excretion of the parent compound was minimal. Halomon was distributed widely to all tissues studied but was concentrated and persisted in fat. Halomon concentrations measured in the brain were comparable with concomitant concentrations detected in plasma and most other tissues. These data and models are helpful in the simulation and evaluation of conditions produced by preclinical screening and toxicology studies.

Plasma pharmacokinetics and urinary excretion of the polyamine analogue 1, 19-bis(ethylamino)-5, 10, 15-triazanonadecane in CD2F1 mice.

The pharmacokinetics of 1, 19-bis(ethylamino)-5, 10, 15-triazanonadecane (BE-4-4-4-4) were determined in CD2F1 female mice after administration of i.v. bolus doses of 20 mg/kg (approximately the dose lethal to 10% of the study animals, approximately LD10) as well as 15, 10, and 5 mg/kg and after s.c., i.p., or p.o. doses of 20 mg/kg. BE-4-4-4-4 in plasma and urine was derivatized with dansyl chloride and measured by gradient high-performance liquid chromatography (HPLC) with fluorescence detection. Data were modeled by noncompartmental and compartmental methods. The declines observed in plasma BE-4-4-4-4 concentrations after i.v. delivery of 20, 15, 10, and 5 mg/kg were modeled simultaneously using an interval of 2000 min between doses and were best approximated by a two-compartment, open, linear model. The time courses of plasma BE-4-4-4-4 concentrations after i.p. and s.c. delivery were fit best by a two-compartment, open, linear model with first-order absorption. Peak plasma concentrations of BE-4-4-4-4 measured following an i.v. dose of 20 mg/kg ranged between 30 and 33 microgram/ml, the terminal elimination half-life was 94 min, and the volume of distribution (Vdss) was 850 ml/kg. The plasma pharmacokinetics of BE-4-4-4-4 were linear with dose. BE-4-4-4-4 (0.5 and 2.0 microM) in mouse plasma was approximately 67% protein-bound. Bio-availabilities after i.p., s.c., and p.o. delivery were 40%, 50%, and approximately 3%, respectively. Urinary excretion of parent BE-4-4-4-4 in the first 24 h after dosing accounted for less than 30% of the delivered dose. As BE-4-4-4-4 proceeds toward and undergoes clinical evaluation, the data and analytical method presented herein should prove useful in formulating a dose-escalation strategy and, possibly, evaluating toxicities encountered.

Retinoic acid nuclear receptor beta inhibits breast carcinoma anchorage independent growth.

Retinoids modulate cellular proliferation and mediate gene function through a series of nuclear receptors. The retinoic acid nuclear receptor beta (RAR beta) plays an important role in the differentiation of a number of cell types. We now demonstrate that RAR beta expression is confined to normal mammary tissue and is not expressed in either immortalized normal or malignant cell lines. Treatment of RAR beta-transfected MDA-MB-231 cells with 1 microM all-trans-retinoic acid (RA) significantly inhibited monolayer growth of the cells which express recombinant RAR beta. RAR beta-expressing MDA-MB-231 cells formed significantly smaller and fewer colonies in soft agar than the mock-transfected cells. Addition of 1 microM RA stimulated colony size and number in the RAR beta-transfected MDA-MB-231 cells. In contrast to the RAR beta-expressing cells, colony formation by the RAR alpha-expressing cells was similar to the mock-transfected controls and the addition of 1 microM RA to the RAR alpha-transfected cells inhibited colony formation. While demonstrating decreased colony formation in agar, RAR beta-expressing MDA-MB-231 cells failed to exhibit decreased growth in SCID mice. Our results show that RAR beta functions as a negative regulator of growth in breast epithelial cells. In addition, the growth of these cells is differentially regulated by RAR alpha and RAR beta which is most likely the result of the modulation of different genes.

Plasma pharmacokinetics and tissue distribution of paclitaxel in CD2F1 mice.

We defined the pharmacokinetics of paclitaxel after i.v., i.p., p.o., and s.c. administration of 22.5 mg/kg to CD2F1 mice. Additional mice were studied after i.v. bolus dosing at 11.25 mg/kg or 3-h continuous i.v. infusions delivered at 43.24 micrograms kg-1 min-1. Plasma was sampled between 5 min and 40 h after dosing. Brains, hearts, lungs, livers, kidneys, skeletal muscles, and, where applicable, testicles were sampled after i.v. dosing at 22.5 mg/kg. Liquid-liquid extraction followed by isocratic high-performance liquid chromatography (HPLC) with UV detection was used to determine paclitaxel concentrations in plasma and tissues. After i.v. administration to male mice, paclitaxel clearance (CLtb) was 3.25 ml min-1 kg-1 and the terminal half-life (t1/2) was 69 min. After i.v. administration to female mice, paclitaxel CLtb was 4.54 ml min-1 kg-1 and the terminal t1/2 was 43 min. The bioavailability of paclitaxel was approximately 10%, 0, and 0 after i.p., p.o., and s.c. administration, respectively. Paclitaxel bioavailability after i.p. administration was the same when the drug was delivered in a small volume to mimic the delivery method used to evaluate in vivo antitumor efficacy or when it was delivered in a large volume to simulate clinical protocols using i.p. regional therapy. Paclitaxel was not detected in the plasma of mice after i.p. delivery of the drug as a suspension in Klucel: Tween 80. Pharmacokinetic parameters were similar after i.v. delivery of paclitaxel at 22.5 and 11.25 mg/kg; however, the CLtb calculated in these studies was much lower than that associated with 3-h continuous i.v. infusions. After i.v. administration, paclitaxel was distributed extensively to all tissues but the brain and testicle. These data are useful in interpreting preclinical efficacy studies of paclitaxel and predicting human pharmacokinetics through scaling techniques.