Pharmacokinetics and toxicity of ciprofloxacin in adult horses.

Using a randomized, cross-over study design, ciprofloxacin was administered i.g. to eight adult mares at a dose of 20 mg/kg, and to seven of the eight horses at a dose of 5 mg/kg by bolus i.v. injection. The mean C(0) was 20.5 µg/mL (±8.8) immediately after i.v. administration. The C(max) was 0.6 µg/mL (±0.36) at T(max) 1.46 (±0.66) h after the administration of oral ciprofloxacin. The mean elimination half-life after i.v. administration was 5.8 (±1.6) h, and after oral administration the terminal half-life was 3.6 (±1.7) h. The overall mean systemic availability of the oral dose was 10.5 (±2.8)%. Transient adverse effects of mild to moderate severity included agitation, excitement and muscle fasciculation, followed by lethargy, cutaneous edema and loss of appetite developed in all seven horses after i.v. administration. All seven horses developed mild transient diarrhea at 36-48 after i.v. dosing. All eight horses dosed intragastrically experienced adverse events attributable to ciprofloxacin administration. Adverse events included mild transient diarrhea to severe colitis, endotoxemia and laminitis necessitating euthanasia of three horses on humane grounds. The high incidences of adverse events preclude oral and rapid i.v. push administration of ciprofloxacin.

Toremifene: pharmacologic and pharmacokinetic basis of reversing multidrug resistance.

Triphenylethylene compounds, such as tamoxifen, have shown chemosensitizing activity independent of estrogen receptor status in doxorubicin-resistant cells. We examined the chemosensitizing activity of a new triphenylethylene, toremifene, and its major metabolites in a doxorubicin-resistant human breast cell line, MCF-7/DOX. In addition, we examined the chemosensitizing activity of unbound plasma toremifene and its metabolites isolated from patients treated with toremifene doses of 20 to 400 mg/d. MCF-7/DOX cells were exposed to ultrafiltrate plasma specimens in the absence and presence of doxorubicin. These latter studies were single-blinded. Toremifene and its major metabolites were capable of sensitizing multidrug-resistant cells to doxorubicin. The degree of chemosensitizing activity in vitro correlated with the plasma concentrations of toremifene and its metabolites (P less than .05). Plasma samples isolated from patients receiving high-dose toremifene (400 mg/d) had the greatest chemosensitizing activity. We present evidence that toremifene and its metabolites can sensitize resistant MCF-7/DOX cells to doxorubicin, that this effect is concentration-dependent, and that sensitizing activity can be detected at clinically achieved concentrations.

Identification of estrogenic tamoxifen metabolite(s) in tamoxifen-resistant human breast tumors.

PURPOSE: We have shown previously that acquired tamoxifen resistance in an in vivo experimental model is associated with reduced tamoxifen accumulation, isomerization of trans-4-hydroxytamoxifen, and tamoxifen-stimulated tumor growth. The purpose of this study is to isolate and verify the presence of estrogenic tamoxifen metabolites in human breast tumors using high-performance liquid chromatography (HPLC) and mass-spectrometry (MS) techniques. PATIENTS AND METHODS: In the present study, we used HPLC and MS to identify the presence of estrogenic metabolites in tumor samples excised from athymic nude mice and in human breast tumors isolated from patients receiving adjuvant tamoxifen therapy. RESULTS: We identified the presence of metabolite E, a known estrogenic metabolite of tamoxifen, in tamoxifen-resistant MCF-7 human breast tumors implanted in athymic nude mice, as well as in tumors from patients with clinical resistance. Additionally, we separated another estrogenic metabolite, bisphenol, by HPLC, and this was also tentatively confirmed by MS analysis. CONCLUSION: These data suggest that cellular tamoxifen metabolism to estrogenic metabolites may in part contribute to stimulating the growth of hormone-responsive breast tumors following prolonged exposure to tamoxifen. Further evaluation of the relationship between cellular metabolism and acquired tamoxifen resistance is warranted.

Tamoxifen and the isomers of 4-hydroxytamoxifen in tamoxifen-resistant tumors from breast cancer patients.

PURPOSE: The antiestrogen tamoxifen is effective in therapy for breast cancer. However, its use is limited by the eventual development of acquired tamoxifen resistance in many patients. The mechanisms responsible for tamoxifen resistance remain unknown; loss of estrogen receptor (ER), selection of hormone-independent breast cancer clones, or alterations in serum tamoxifen levels after long-term use do not explain acquired resistance in most patients. Using an experimental model in which human breast cancer cells develop resistance in athymic mice treated with tamoxifen, we have recently shown that acquired resistance is associated with markedly reduced cellular concentrations of tamoxifen and by isomerization of the trans-4-hydroxy metabolite to the less potent cis isomer. MATERIALS AND METHODS: Using a sensitive high-performance liquid chromatography (HPLC) assay, we have now measured levels of tamoxifen and its major metabolites in a series of 14 tumors from patients treated with tamoxifen. The duration of therapy ranged from 1 month to 6 years. RESULTS: Tumor tamoxifen levels varied over a wide range. Low concentrations were observed in tumors from eight patients, all demonstrating progressive disease at the time of biopsy after a minimum duration of treatment of 6 months. Six tumors had moderate to high tamoxifen levels, two from patients responding to tamoxifen, one from a patient with stable disease, and three from patients with disease progression. Both the cis and trans isomers of the potent antiestrogenic metabolite 4-hydroxy-tamoxifen were detected in 11 tumors. Six tumors had high ratios of the cis to trans isomer (1.10:2.06), all from patients not responding to tamoxifen. The five tumors with low cis:trans ratios included the two tumors from responding patients and three from patients with progression. All but one of the 11 nonresponding patients had either a low tumor tamoxifen level, a high cis:trans ratio, or both. CONCLUSION: This study clearly demonstrates a wide range of tumor tamoxifen levels and accumulation of the less antiestrogenic cis isomer of 4-hydroxytamoxifen in some patients on tamoxifen therapy. Additional study is necessary to determine if these metabolic profiles are related to the development of tamoxifen resistance.

Pharmacology of antineoplastic agents in pregnancy.

The use of antineoplastic agents in pregnant women poses obvious risks to both the patient and the developing fetus, particularly during organogenesis. While the use of antineoplastics during pregnancy is often unavoidable, the physician may limit the risks by having a clear knowledge of the pharmacology and teratogenic potential of individual agents. Specific physiologic changes in the pregnant patient, such as enhanced renal excretion of drugs, increased or decreased hepatic function, altered gastrointestinal absorption and enterohepatic circulation, altered plasma protein binding, an increase in plasma volume (50%), and creation of a fluid filled 3rd compartment (amniotic fluid) for water soluble drugs may all significantly influence the pharmacology of antineoplastic agents. These physiological changes may effect the pregnant patients ability to absorb orally administered drugs, metabolize drugs to either active or inactive metabolites, and eliminate cytotoxically active drugs. A resulting reduction in concentration x time (C x T) for drug exposure to the maternal system may reduce the efficacy of the antineoplastic agents, while an increase in C x T may expose the patient and her fetus to undue toxicity. The timing of drug administration to gestational age is also a critical factor for some drugs. While many drugs result in adverse effects on the fetus regardless of gestational age, others appear to pose less of a threat if administered beyond the first trimester. This review addresses the pharmacology, pharmacokinetics and the teratogenic potential of individual antineoplastic agents that are commonly used in pregnant patients. The aim of this review is to help the physician select, on a patient specific basis, antineoplastic agents that avoid at least some of the fetal risk involved while maintaining efficacy in the treatment of the patient.

Tamoxifen resistance in breast cancer.

Tamoxifen (TAM) resistance is the underlying cause of treatment failure in many breast cancer patients receiving TAM. The mechanism(s) involved in TAM resistance are poorly understood. A variety of mechanisms have been proposed but only limited evidence exists to substantiate them. Studies have now shown that in many patients TAM resistance is not related to the down regulation or loss of estrogen receptors (ER). Variant ER have been identified, but their significance clinically remains to be proven. Since breast cancer cells secrete several estrogen-regulated growth factors and growth inhibitors that may have autocrine or paracrine activity, altered growth factor production is another possible mechanism for TAM resistance. Tissue-specific transcription activating factors that may alter how the signal induced by TAM binding to the receptor is interpreted by the cell also require further investigation. An increase in antiestrogen binding sites (AEBS), which could effectively partition TAM and reduce its concentration at the ER has also been proposed as a potential mechanism. Pharmacologic mechanisms, such as a shift in metabolism toward the accumulation of estrogenic metabolites, are supported by recent data demonstrating metabolite E and bisphenol in tumors from TAM-resistant patients. Furthermore, a decrease in tumor TAM accumulation and an altered metabolite profile have been reported in TAM-resistant breast tumors grown in nude mice. These and other studies suggest that TAM resistance may be multifactorial in nature, but definitive identification of mechanisms that are operative in clinical TAM resistance requires further study.

Cisplatin rescue therapy: experience with sodium thiosulfate, WR2721, and diethyldithiocarbamate.

Cisplatin has a steep dose response curve for both antitumor and adverse effects. Therapeutic strategies aimed at reducing toxicity and allowing dose escalation of intravenous cisplatin, such as administration in hypertonic saline and pharmacokinetically based dosing schedules, have been partially successful in reducing nephrotoxicity and bone marrow suppression. However, new dose-limiting toxicities consisting of peripheral neuropathy and ototoxicity have emerged, which continue to restrict potential use of high dose cisplatin therapy. Intraperitoneal administration of high dose cisplatin also offers the potential of markedly increased local drug exposure if systemic toxicity can be avoided. Proposed chemoprotective agents, including sodium thiosulfate, WR2721, and diethyldithiocarbamate (DDTC) are being extensively examined as "rescue agents" for either regional or systemic administration of cisplatin. Although each agent offers unique advantages to be considered in developing successful rescue therapy, many questions remain regarding molecular and pharmacokinetic interactions with cisplatin, appropriate dosing schedules, and effects on antineoplastic activity. We present a review of current investigations of chemoprotectors for prevention of cisplatin-related toxicities.

Prolonged tamoxifen exposure selects a breast cancer cell clone that is stable in vitro and in vivo.

The effects of long-term tamoxifen exposure on cell growth and cell cycle kinetics were compared between oestrogen receptor (ER)-positive (MCF-7) and ER-negative (MDA-MB-231) cell lines. In the MCF-7 cell line, prolonged tamoxifen exposure (0.5 mumol/l for > 100 days) blocked cells in G0-G1 of the cell cycle, and slowed the doubling time of cells from 30 to 59 h. These effects corresponded to an increase in the cellular accumulation of tamoxifen over time [mean area under concentration curve (AUC) = 77.92 mumoles/10(6)/cells/day]. In contrast, in the MDA-MB-231 cell line, long-term tamoxifen exposure had no obvious effect on the doubling time, and reduced cellular tamoxifen accumulation (mean AUC = 50.50 mumoles/10(6)/cells/day) compared to the MCF-7 cells. Flow cytometric analysis of MDA-MB-231 cells demonstrated that a new tetraploid clone emerged following 56 days of tamoxifen exposure. Inoculation of the MDA-MB-231 tetraploid clone and MDA-MB-231 wildtype cells into the opposite flanks of athymic nude mice resulted in the rapid growth of tetraploid tumours. The tetraploid tumours maintained their ploidy following tamoxifen treatment for nine consecutive serial transplantations. Histological examination of the fifth transplant generation xenografts revealed that the tetraploid tumour had a 25-30 times greater mass, area of haemorrhage and necrosis, a slightly higher mitotic index and was more anaplastic than the control neoplasm. The control wildtype MDA-MB-231 tumours maintained a stable ploidy following tamoxifen treatment until the eighth and ninth transplantation, when a tetraploid population appeared, suggesting that tamoxifen treatment may select for this clone in vivo. These studies suggest that prolonged tamoxifen exposure may select for new, stable, fast growing cell clones in vitro as well as in vivo.

Clinical pharmacokinetics of drugs used in the treatment of breast cancer.

This article reviews the absorption, bioavailability, distribution, metabolism, and elimination patterns of the agents most commonly used for the treatment of breast cancer. Although the majority of the pharmacokinetic studies reviewed have been examined in non-breast cancer patients, the kinetic findings are not significantly altered by disease state. The anthracyclines, antimetabolites, alkylating agents, antioestrogens and mitotic inhibitors are among the classes of agents used to treat breast cancer. Although extensively examined, cancer pharmacokinetic research has resulted in very few clinically relevant findings in breast cancer.

Targeting chemosensitizing doses of toremifene based on protein binding.

Toremifene is currently being evaluated as a chemosensitizing agent in doxorubicin-resistant patients. Although concentrations of > 2 microM reverse resistance in vitro, target concentrations required to reverse multidrug resistance (MDR) in vivo may be highly influenced by variables such as protein binding in serum. We examined the effects of high serum concentrations on the cellular accumulation of toremifene in an MDR MDA-MB-A-1 human breast-cancer cell line. We then examined the cellular accumulation of doxorubicin at various toremifene concentrations in 5% - 100% serum. We also measured the concentrations of toremifene and its major metabolites in plasma specimens obtained from two patients receiving 360 mg/day for 5 days in a phase I study. Our results show that (1) high serum concentrations decrease toremifene accumulation, (2) toremifene concentrations of < or = 2.5 microM enhance doxorubicin accumulation, and (3) patients achieve plasma toremifene concentrations of 10-15 microM following doses of 360 mg/day x 5 days. Our findings suggest that in vivo toremifene concentrations well above those used to reverse resistance in vitro are required to overcome the effect of high serum-protein binding.

Pharmacokinetics of toremifene and its metabolites in patients with advanced breast cancer.

A multicenter phase I pharmacokinetic study of a new triphenylethylene antiestrogen, toremifene, was examined in 70 patients with advanced breast cancer. Patients were randomized to receive single daily oral doses of either 10, 20, 40, 60, 200, or 400 mg for 8 weeks. Plasma toremifene and its major metabolites. N-desmethyltoremifene and 4-hydroxytoremifene, were determined weekly during therapy and at 0, 7, 14, and 21 days after the discontinuation of therapy. The time to reach steady-state plasma concentrations was between 1 and 5 weeks, with steady-state being achieved earlier (1-2 weeks) at daily doses of 200 and 400 mg. The time to peak concentration following oral doses of toremifene ranged from 1.5 to 4.5 h. The terminal half-life of elimination was 5.0, 6.0, and 5.0 days for toremifene, desmethyltoremifene, and 4-hydroxytoremifene, respectively. Plasma concentrations of 4-hydroxytoremifene were detectable only at high doses (200 and 400 mg/day) of toremifene. The results of this phase I pharmacokinetic study show that toremifene has metabolic and kinetic patterns that are similar to those previously reported with tamoxifen.

Pharmacokinetics of cisplatin in patients receiving interleukin-2-containing treatment regimens.

Plasma cisplatin pharmacokinetics were determined in 6 patients enrolled in a phase I trial of combined high-dose cisplatin and Interleukin-2 (IL-2) therapy. Cisplatin (100 mg/m2) was given in 3% saline as a 3-h infusion on days 1 and 8 of each 28-day cycle; IL-2(2-4 x 10(6) units/m2) was given as an i.v. bolus on days 15-19 in a dose escalation trial. Peak total and ultrafiltrate plasma platinum concentrations were 1.15 and 0.172 micrograms/ml for cycle 1 and 1.2 and 0.124 micrograms/ml for cycle 3, respectively. The AUCs for total and ultrafiltrate plasma platinum were 7.33 and 0.965 micrograms/ml per hour for cycle 1 and 8.48 and 0.924 micrograms/ml per hour for cycle 3, respectively. Total body clearances for total and ultrafiltrate platinum were 0.051 and 0.525 ml/h for cycle 1 and 0.042 and 0.443 ml/h for cycle 3, respectively. These data demonstrate no significant effects of IL-2 on the plasma pharmacokinetics of cisplatin in the dose schedule given and support the feasibility of this combined modality therapy.

Tissue distribution of transdermal toremifene.

PURPOSE: Toremifene is an orally administered triphenylethylene derivative with antiestrogenic activity that is primarily used in the treatment of patients with metastatic breast cancer. The purpose of this study was to evaluate the therapeutic advantage of local (transdermal) administration of toremifene in several animal models. Local (subcutaneous and skin) versus systemic concentrations of toremifene were evaluated serially following transdermal application of the drug. With high local concentrations and minimal distribution to other organs via the circulation, topical toremifene may deliver maximal therapeutic effects to local tissue while avoiding the side effects seen with systemic therapy. METHODS: Three animal models (nude mice, baboons, and a horse) were used to examine topically administered toremifene for kinetic measurements. RESULTS: In nude mice implanted subcutaneously with MDA-MB-231 human breast tumors, topical toremifene (2.5 mg/day x 5 days) produced greater than 50-fold higher tumor concentrations compared with intraperitoneal (i.p.) administration (1.0 mg/day x 5 days). Systemic distribution in plasma, uterus, and liver was lower following topical than following i.p. administration. In nude mice inoculated subcutaneously with estrogen receptor-positive (ER +) MCF-7 human breast cancer cells, topical toremifene and 4-hydroxytoremifene (4-OH) prevented tumor growth in the presence of estradiol. In four nontumor-bearing baboons that were given transdermal toremifene, relatively high distribution of drug was noted in normal breast tissue and fat, compared with undetectable serum concentrations. Finally, a new topical formulation of toremifene (a gel preparation for human use, Orion-Farmos, Finland) achieved high local tumor toremifene concentrations in a horse melanoma, with minimal systemic distribution. CONCLUSIONS: Transdermal toremifene can achieve high local tissue concentrations with minimal systemic distribution.

Toremifene enhances cell cycle block and growth inhibition by vinblastine in multidrug resistant human breast cancer cells.

The clinical study of compounds that modulate multidrug resistance has been hindered by both the toxicities of these agents and the inability to monitor their effectiveness at the level of the tumor cell. Previously, toremifene has been shown to be well tolerated clinically and to sensitize multidrug resistant cells to the effects of cytotoxic chemotherapeutic agents. The chemosensitizing properties of toremifene in estrogen receptor negative, multidrug resistant MDA-MB-A1 human breast cancer cells were studied using flow cytometric analysis and growth inhibition assays. Cell cycle kinetics of MDA-MB-A1 cells were not significantly affected by treatment with either toremifene, N-desmethyltoremifene, Toremifene IV or vinblastine alone, as the majority of cells remained in G0/G1. However, preincubation with toremifene or one of its metabolites for 72 hours followed by treatment for one hour with vinblastine caused a marked shift of cells to G2/M, as cells appeared to be blocked in that phase of the cell cycle. This result was nearly identical to the effect of vinblastine alone on vinblastine-sensitive MDA-MB-231 breast cancer cells and can be interpreted as a "resensitization" by toremifene of MDA-MB-A1 cells to vinblastine. This chemosensitizing effect of toremifene was accompanied by an enhanced inhibition of cell growth by vinblastine. The chemosensitizing effects of toremifene or one of its metabolites in combination with cytotoxic chemotherapy can be effectively monitored by flow cytometry, an easily accessible technique.

A breast cancer clone selected by tamoxifen has increased growth rate and reduced sensitivity to doxorubicin.

The in vivo growth rate and the chemosensitivity patterns of a cell clone selected by tamoxifen from the estrogen receptor-negative human breast cancer cell line MDA-MB-231 was studied in the nude mouse model and with flow cytometry. To investigate the growth rate of the wild-type and clone cells in vivo, the cells were inoculated into the opposite flanks of 5 male nude mice. Drug sensitivity to doxorubicin (10 ng/mL), vinblastine (1 ng/mL), and paclitaxel (1 ng/mL) was examined in wild-type/clone cell mixture using flow cytometry. Northern blot technique was used to study the expression of mdr-1 messenger RNA in both the wild-type and the clone cells. The tumors derived from the clone and wild-type cells were, following a 3-week growth period, 260.2 +/- 78.8 mm2 vs. 68.3 +/- 50.8 mm2 in size, respectively (P < 0.001). Following a 28-day continuous exposure, doxorubicin was selectively, toxic to the wild-type cells, while having no apparent effect on the clone population. However, paclitaxel- and vinblastine-treated wild-type/clone cell mixtures did not exhibit a differential cytotoxic effect on either cell population. It was concluded that the clone selected by tamoxifen shows an aggressive growth rate in vivo and an altered chemosensitivity pattern to doxorubicin in vitro.

Liposome-encapsulated amphotericin B: a promising new treatment for disseminated fungal infections.

Amphotericin B therapy is hampered by numerous adverse effects but remains the treatment of choice for disseminated fungal infections. A new form of amphotericin B delivery, which utilizes liposome vesicles, is currently under investigation. Preliminary evidence suggests that liposome-encapsulated amphotericin B has a wider therapeutic index than free amphotericin B and allows for the use of larger total doses. The mechanism of reduced toxicity and enhanced activity may be associated with a liposome donor effect, an erythrocyte protective effect, and a liposome-targeting ability. Liposome-encapsulated amphotericin B tends to be entrapped or taken up by organs rich in reticuloendothelial cells--a particular advantage since disseminated fungal infections localize in these areas. This liposome-encapsulated preparation appears to represent a promising new form of antifungal therapy that may reduce the dose-limiting toxicities of amphotericin B and improve treatment response.

Tamoxifen for the prevention of breast cancer: no.

The tamoxifen chemoprevention trial in health women is ongoing in over 250 cancer treatment centers. The use of tamoxifen for the treatment of postmenopausal women with known breast cancer has been touted as a medical breakthrough by many physicians. However, the ongoing trial which enroll high-risk healthy women above the age of 34, has been controversial since its initiation in 1991. Congressional hearings, editorial, and statistical analyses concerning the scientific basis of the trial have emerged over the past year. This chapter presents the newest scientific facts, and speculates on the unknown risks of using tamoxifen as a chemopreventive in healthy women.

Symptoms of posttraumatic stress disorder in adolescents with conduct disorder: sex differences and onset patterns.

OBJECTIVE: To examine sex differences in the rate and symptoms of posttraumatic stress disorder (PTSD), trauma exposure, and onset patterns in youth with conduct disorder (CD). METHOD: Youth admitted to a clinical facility for severe behaviour problems completed the Diagnostic Interview for Children and Adolescents--Revised (DICA-R) to assess the presence of CD and PTSD. RESULTS: Over one-half of CD youth reported exposure to trauma, yet only 17% met criteria for PTSD. PTSD was more frequent in CD girls (28%) than in boys (10%), and girls experienced greater symptom intensity and anhedonia, difficulty feeling love or affection, and disturbance of sleep and concentration. Girls more frequently reported sexual assault, while boys were more likely to report accidents, physical assaults, and witnessing the death of a loved one. Retrospective reports indicated that PTSD tended to develop subsequent to CD. CONCLUSIONS: Exposure to trauma is common among CD youth; however, diagnostic procedures should be adapted for increased sensitivity to PTSD. The development of CD may increase the risk for PTSD, particularly in girls, by exposing youth to situations in which they are traumatized. The role of trauma in CD should be routinely examined by clinicians and warrants further research.