UMLS:C0027651 - FACTA Search

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Topotecan is a semi-synthetic, water soluble topoisomerase I inhibitor which has recently been approved for the treatment of ovarian cancers after failure of first-line therapy. A number of different dosing schedules are being investigated in clinical trials including oral administration, a daily infusion on 5- or 3-consecutive days and a continuous infusion for 21 days. A 30-minute infusion of topotecan 1.5 mg/m2 on 5 consecutive days every 3 weeks, as standard schedule, produced response rates of 13.8 to 20.5% in the 3 largest phase II/III studies in women with advanced ovarian cancers who had either failed to respond or had relapsed after an initial response to platinum-based chemotherapy (N = 92 to 139), continuous 21-day infusion of topotecan 0.3 to 0.5 mg/m2 has shown efficacy in 2 small phase II studies. There were no statistically significant difference in efficacy between topotecan (1.5 mg/m2/day for 5 consecutive days every 21 days) and paclitaxel (175 mg/m2/day given over 3-h every 21 days) in the randomized phase III study. In 3 large clinical trials, response to topotecan was higher in patients who were platinum sensitive (19.2 to 29%) than in those whose disease was platinum resistant or refractory (11.3 to 13.3%) not statistically significant in 1 study, statistical analysis not reported in the other 2 trials. Myelosuppression, particularly neutropenia, is the dose-limiting toxicity of topotecan. It is reversible, dose-related and non-cumulative. In 2 large studies, topotecan produced grade 4 neutropenia in 78 and 79% of patients and in 40 and 37% of all treatment courses (febrile neutropenia occurred during 3% of 552 courses in 1 study). Grade 4 thrombocytopenia was seen in 18 and 25% of patients and in 6 and 10% of all courses, respectively. Grade 4 neutropenia was significantly more common in patients receiving topotecan than in those receiving paclitaxel (79 vs 23%), as was grade 4 thrombocytopenia (25 vs 2%), in a single randomized clinical trial. Non-hematological adverse events during topotecan therapy were mostly mild. A step beyond is the combination treatment including topotecan as a 3- or 5 days schedule plus a platinum compounds or topoisomerase II inhibitor. These associations of drugs are based on the preclinical data of the in vitro studies showing a synergy of the anti-tumor activity. A novel schedule of topotecan is also the "alternating" chemotherapy consisting of different doublet of drugs given as a sequential way or as a really sequential topotecan therapy. Both methods of combining topotecan as second/salvage treatment or front line therapy are being investigated by numerous authors. Preliminary data suggest interesting results in terms of efficacy, manageable toxicity and new schedules of treatment for topotecan. Low dosages of drug in combination with other agent do not seem to influence the well-known data of efficacy or safety of topotecan literature. Probably the 3-day schedule allows a combination treatment, otherwise not feasible with the standard 5-day administration.
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PMID:[Topotecan: prospects for using it in combination therapy for ovarian carcinoma]. 1078 95

Topotecan (TPT) is a DNA-Topoisomerase I poison that exhibits antitumor activity. TPT, like other DNA-damaging agents, arrests or delays cell cycle progression during S- and G2-phase in a wide variety of tumor-derived cell lines. Particularly, the G2-arrest gives time for the cell to repair its DNA lesions prior to starting a new cell cycle. Based on these observations, we assessed the interaction between TPT and G2/M-active agents in p53-mutated cell lines of diverse origin in order to achieve cell toxicity. Two short-term sequential schedules were administered (TPT --> G2/M-active drug at the interval of greatest TPT-induced G2/M-phase cell arrest, and G2/M-active drug --> TPT), in three human tumor-derived cell lines with proven sensitivity to the following drugs: Bleomycin in HEp-2 (squamous larynx carcinoma); Docetaxel in SKBr-3 (breast adenocarcinoma); Etoposide in NCI-H23 (non-small-cell lung cancer). Our results show that: 1) Sequential TPT --> G2/M-active drugs are synergistic when administration overlapped the maximum percentage of TPT-induced G2/M-phase cell arrest interval in all three mutated p53 cell lines; 2) the reverse sequential schedule (G2/M-active drug --> TPT) was antagonistic, and being only additive for Etoposide --> TPT association. In conclusion, our findings further support the potential cytotoxic role of TPT in combination with other active drugs when the correct schedule of administration is applied. In addition, they provide a rationale for new applications in clinical trials using short-term sequential TPT --> G2/M-active drugs.
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PMID:Cytotoxic effects of topotecan combined with various active G2/M-phase anticancer drugs in human tumor-derived cell lines. 1085 93

Topotecan was encapsulated in sphingomyelin/cholesterol liposomes using an ionophore-generated proton gradient. After i.v. injection, liposomal topotecan was eliminated from the plasma much more slowly than free drug, resulting in a 400-fold increase in plasma area under the curve. Further, high-performance liquid chromatography analysis of plasma samples demonstrated that topotecan was protected from hydrolysis within the liposomal carrier with >80% of the drug remaining as the active, lactone species up to 24 h. The improved pharmacokinetics observed with liposomal topotecan correlated with increased efficacy in both murine and human tumor models. In the L1210 ascitic tumor model, optimal doses of liposomal topotecan resulted in a 60-day survival rate of 60-80%, whereas in a L1210 liver metastasis model, 100% long-term survival (>60 days) was achieved. In contrast, long-term survivors were rarely seen after treatment with free topotecan. Further, in a human breast carcinoma model (MDA 435/LCC6), liposomal topotecan provided greatly improved increase in life span relative to the free drug. These results suggest that liposomal encapsulation can significantly enhance the therapeutic activity of topotecan.
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PMID:Liposomal encapsulation of topotecan enhances anticancer efficacy in murine and human xenograft models. 1091 44

From October 1995 to March 1997, a phase II trial of topotecan was carried out in chemotherapy-naive women with advanced, persistent, or recurrent uterine leiomyosarcomas. Thirty-six patients were entered. Median age was 53 years. Performance status was 0 (50%) in 18, 1 (36%) in 13, and 2 (14%) in 5. Most patients, 33 (92%), had undergone prior surgery, and 8 (22%) prior radiation therapy. Topotecan, 1.5 mg/m2. was administered intravenously daily for 5 days, every 3 weeks, until progression of disease or adverse affects prohibited further therapy. Patients received 1 to 13 courses with a median of 3 courses. The most frequent grade 4 adverse effects were neutropenia in 28 (78%), leukopenia in 8 (22%), thrombocytopenia in 3 (8%), and anemia in 3 (8%). Complete response was seen in 1 (3%), partial response in 3 (8%), stable disease in 12 (33%), and increasing tumor in 20 (56%). Thus topotecan at this dose and schedule does not appear to have major activity in uterine leiomyosarcomas.
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PMID:Phase II trial of topotecan in patients with advanced, persistent, or recurrent uterine leiomyosarcomas: a Gynecologic Oncology Group Study. 1095 63

Few chemotherapy agents have demonstrated activity in patients with myelodysplastic syndromes (MDS) and supportive management remains the standard of care. An increasing number of new drugs in development are being directed at specific molecular or biological targets of these diseases. Topotecan, a topoisomerase I inhibitor, has shown single-agent activity and is now being combined with other agents, including cytarabine. The aminothiol amifostine induces responses in about 30% of patients; however, its role is still being clarified. Agents that inhibit histone deacetylase and target DNA hypermethylation, thus permitting derepression of normal genes, include 5-azacytidine, decitabine, phenylbutyrate, and depsipeptide. Arsenic trioxide has demonstrated impressive activity in acute promyelocytic leukemia and preclinical data suggest the potential for activity in MDS. UCN-01 is a novel agent that inhibits protein kinase C and other protein kinases important for progression through the G1 and G2 phases of the cell cycle. Dolastatin-10 has extremely potent in vitro activity against a variety of tumor cell lines. Since its dose-limiting toxicities include myelosuppression, it is being studied in acute myelogenous leukemia (AML) and MDS. Ras may play a role in MDS, and activation of this gene and its signaling pathways may require farnesylation. Several farnesyl transferase inhibitors are now available for study in patients with MDS. An increasing body of data suggests a possible role for angiogenesis in MDS, and several antiangiogenesis agents are in clinical trials, including thalidomide, SU5416, and anti-vascular endothelial growth factor (VEGF) antibodies. Development of new drugs and regimens will be facilitated by recently developed standardized response criteria. Future clinical trials should focus on rational combinations of these agents and others with the goal of curing patients with MDS.
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PMID:Novel therapeutic agents for the treatment of myelodysplastic syndromes. 1104 23

The natural alkaloid camptothecin is the lead compound of a new class of antitumor agents with a unique mechanism of action (i.e. inhibition of DNA topoisomerase I). The pharmacological interest of these agents has generated a large number of derivatives and analogues endowed with potent cytotoxic activity, two of them being in clinical use as antitumor drugs. We have synthesized a new series of camptothecins substituted in position 7 with an alkyl or alkenyl chain bearing cyano and/or carbethoxy groups. These compounds showed potent cytotoxic activity in vitro against the human non-small-cell lung carcinoma H460 cell line, most of them exhibiting IC(50) values in the 0.05-1 microM range, more active than topotecan used as a reference compound. In particular 7-cyano-20S-camptothecin (5a) showed high in vitro cytotoxicity against a topotecan-resistant H460 cell subline (H460/TPT) and a cisplatin-resistant ovarian carcinoma subline (IGROV-1/Pt 1). In an in vivo evaluation of the antitumor activity, 5a appeared significantly more effective than topotecan in the H460 tumor model and comparable with topotecan in a small-cell lung carcinoma model and a colon carcinoma model. The efficacy and good tolerability of this compound increase interest for further preclinical development.
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PMID:Novel 7-substituted camptothecins with potent antitumor activity. 1105 1

The efficacy of topoisomerase (Topo) I-active drugs may be improved by better understanding the molecular and cellular responses of tumor compared to normal cells after genotoxic insults. Ionizing radiation (IR) + Topo I-active drugs (e.g., Topotecan) caused synergistic cell killing in various human cancer cells, even in cells from highly radioresistant tumors. Topo I poisons had to be added either during or immediately after IR. Synergy was caused by DNA lesion modification mechanisms as well as by concomitant stimulation of two pathways of cell death: necrosis (IR) + apoptosis (Topo I poisons). Cumulative data favor a mechanism of synergistic cell killing caused by altered DNA lesion modification and enhanced apoptosis. However, alterations in cell cycle regulation may also play a role in the synergy between these two agents in certain human cancers. We recently showed that NF-kappa B, a known anti-apoptotic factor, was activated in various cancer cells after poisoning Topo I using clinically active drugs. NF-kappa B activation was dependent on initial nuclear DNA damage followed by cytoplasmic signaling events. Cytoplasmic signaling leading to NF-kappa B activation after Topo I poisons was diminished in cytoplasts (lacking nuclei) and in CEM/C2 cells that expressed a mutant Topo I protein that did not interact with Topo I-active drugs. NF-kappa B activation was intensified in S-phase and blocked by aphidicolin, suggesting that activation was a result of double-strand break formation due to Topo I poisoning and DNA replication. Dominant-negative I kappa B expression augmented Topo I poison-mediated apoptosis. Elucidation of molecular signal transduction pathways after Topo I drug-IR combinations may lead to improved radiotherapy by blocking anti-apoptotic NF-kappa B responses. Recent data also indicate that synergy caused by IR + Topo I poisons is different from radiosensitization by beta-lapachone (beta-lap), a "reported" Topo I and II-alpha poison in vitro. In fact, beta-lap does not kill cells by poisoning either Topo I or II-alpha in vivo. Instead, the compound is "activated" by an IR (damage)-inducible enzyme, NAD(P)H:quinone oxidoreductase (NQO1), a gene cloned as x-ray-inducible transcript #3, xip3. Unlike the lesion modification pathway induced by IR + Topo I drugs, beta-lap kills cells via NQO1 futile cycle metabolism. Downstream apoptosis caused by beta-lap appears to be noncaspase-mediated, involving calpain or a calpain-like protease. Thus, although Topo I poisons or beta-lap in combination with IR both synergistically kill cancer cells, the mechanisms are very different.
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PMID:Cellular and molecular responses to topoisomerase I poisons. Exploiting synergy for improved radiotherapy. 1119 3

Recurrent or metastatic squamous carcinoma of the head and neck (RMSCHN) is a modestly chemoresponsive tumor; however, currently available agents have failed to improve survival. New active agents are needed for the treatment of this disease. Topotecan is a topoisomerase inhibitor that demonstrated initial promising activity in squamous carcinoma of the head and neck. The Eastern Cooperative Oncology Group conducted a phase II trial of topotecan to determine the efficacy and toxicity of a weekly treatment schedule in patients with RMSCHN. Patients with metastatic or locally recurrent squamous carcinoma of the head and neck were treated with topotecan 1.5 mg/m2 x 24 hours by continuous infusion on days 1, 8, 15, and 22 of each 35-day cycle. Patients were stratified in two cohorts: chemonaive and previously treated. Sixteen chemonaive and 16 previously treated patients were registered on study. Grade III/IV neutropenia and anemia occurred in 16% and 18% of patients, respectively. No responses were observed in either cohort. Median survival for previously untreated patients was 4.6 months and 3.2 months for previously treated patients. Topotecan failed to demonstrate efficacy in patients with RMSCHN. Further evaluation of this agent is not planned.
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PMID:Lack of efficacy of topotecan in the treatment of metastatic or recurrent squamous carcinoma of the head and neck: an Eastern Cooperative Oncology Group Trial (E3393). 1123 52

Although characterized by a highly variable phenotype and multiple genetic alterations, glioblastomas are considered monoclonal in origin. We here report on a 64-yr-old patient who developed a second glioblastoma in the left frontal lobe 10 yr after surgical resection of a glioblastoma of right frontal lobe. The first tumor contained 2 p53 mutations, in codon 213 (CGA-->TGA, Arg-->stop) and codon 306 (CGA-->TGA, Arg-->stop), further, 1 missense PTEN mutation (codon 257, TTC-->TTA, Phe-->Leu) and a silent PTEN mutation (codon 154, TTC-->TTT, Phe-->Phe). The second glioblastoma also contained multiple, but different mutations: p53 mutations in codons 158 (CGC-->CAC, Arg-->His) and 273 (CGT-->TGT, Arg-->Cys), and a PTEN mutation in codon 233 (CGA-->TGA, Arg-->Stop). Both neoplasms had a homozygous p16 deletion. The discordant pattern of mutations indicates that the second glioblastoma was not a recurrence but an independent second glioblastoma. The presence in these neoplasms of multiple mutations in tumor suppressor genes suggests the involvement of a novel disease mechanism but there was no indication of a DNA mismatch repair deficiency or of an inherited tumor syndrome.
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PMID:Second primary glioblastoma. 1127 8

Clinical radioimmunotherapy (RIT) of solid tumors holds great promise, but as yet has been unable to deliver tumoricidal radiation doses without unacceptable toxicity. Our experimental approach aims to potentiate the therapeutic action of radioimmunoconjugates at the tumor site and thus improve the efficacy of RIT by combination with other treatment modalities. The topoisomerase I inhibitors are a unique class of chemotherapeutic agents that interfere with DNA breakage-reunion by inhibiting the action of topoisomerase I. Preclinical studies suggest that prolonged infusion of topoisomerase I inhibitors enhances cell toxicity due to ionizing radiation. We evaluated the efficacy of combined treatment with continuous administration of topotecan and 90Y-MX-DPTA BrE3 monoclonal antibody (which recognizes an epitope of breast epithelial mucin expressed in most breast cancers) on human mammary carcinoma xenografts in nude mice. Topotecan or 90Y-BrE3 treatment alone delayed overall tumor growth rate transiently but did not affect survival. The combination of RIT with topotecan substantially reduced growth of relatively large established tumors and caused complete tumor regressions and prolonged tumor-free survival in a substantial proportion of treated animals. In vitro studies demonstrated an increase in apoptotic rate and a decrease in cell proliferation of tumor cell lines treated with this combination. We combined the radiosensitization property of topotecan and the specificity of systemic RIT to establish a novel therapy for solid tumors in an experimental tumor xenograft model.
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PMID:Radiosensitization of tumor-targeted radioimmunotherapy with prolonged topotecan infusion in human breast cancer xenografts. 1130 78

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