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Query: EC:5.99.1.2 (
topoisomerase
)
9,166
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
CI-921 (NSC 343499; 9-[[2-methoxy-4-[(methylsulphonyl)amino]phenyl]amino] -N,5-dimethyl- 4-acridinecarboxamide) is a
topoisomerase
II poison with high experimental antitumour activity. It was administered by 15 min infusion to 16 evaluable patients with non-small cell lung cancer (NSCLC) (7 with no prior treatment, 9 patients in relapse following surgery/radiotherapy) at a dose (648 mg/m2 divided over 3 days, repeated every 3 weeks) determined by phase I trial. Patients had a median performance status of 1 (WHO), and median age of 61 years. The histology comprised squamous carcinoma (11), adenocarcinoma (1), mixed histology (2), bronchio-alveolar carcinoma (1) and large cell undifferentiated carcinoma (1). Neutropenia grade greater than or equal to 3 was seen in 15 patients, infections with recovery in 3, and grand mal seizures in 1 patient. Grade less than or equal to 2
nausea and vomiting
occurred in 66% courses and phlebitis in the infusion arm in 37%. 1 patient with squamous cell carcinoma achieved a partial response lasting 5 months. Further testing in this and other tumour types using multiple daily schedules is warranted.
...
PMID:Phase II study of the amsacrine analogue CI-921 (NSC 343499) in non-small cell lung cancer. 166 18
The epipodophyllotoxin derivative etoposide (VP-16) has been in widespread use both alone and in combination chemotherapy for the past decade. It has phase-specific cytotoxicity that acts in the last S and G2 phases of the cell cycle. Although its mode of action is not certain, it appears to act by causing breaks in DNA by interaction with DNA-
topoisomerase
II or by the formation of free radicals. Most studies show biexponential decay after the intravenous (IV) administration of etoposide. Approximately 30% to 70% of administered etoposide is excreted, with approximately 45% present in the urine. Etoposide is available in oral and IV preparations. It is highly schedule-dependent, with once-daily doses (e.g., for 5 to 8 days every 21 days) giving results superior to intermittent administration. The bioavailability of oral etoposide is approximately 50%, but its absorption is not linear with increasing dose (e.g., greater than 200 mg/d, bioavailability decreases). Factors influencing the bioavailability of oral etoposide include patient status, concurrent medications, hepatic and renal function, and
nausea and vomiting
. In numerous clinical trials, etoposide has demonstrated excellent activity against a range of tumors, including small cell lung cancer (SCLC), malignant lymphomas, gestational trophoblastic tumors, Ewing's and soft tissue sarcomas, and germ cell tumors, with more modest activity in other tumors (e.g., non-SCLC). Although few comparative studies have been carried out, available data suggest that oral etoposide administered daily during 5 to 8 days is similar to the IV preparation in range of activity. In a study of 53 elderly patients with SCLC treated with etoposide (200 mg/d for five times), there was a response rate of 79% and a median survival of 9.5 months. These results were similar to those achieved with more intensive IV regimens. Several studies of chronic oral etoposide (50 mg/m2/d for 21 times) have been reported recently. Responses were observed in SCLC and germ cell tumors among patients who had relapsed after standard etoposide-containing regimens. These data suggest that etoposide may be a "new" drug when given in this schedule. The high response rates with oral etoposide suggest that oral administration may be substituted for IV administration. This substitution may allow for greater flexibility in chemotherapeutic administration, less hospitalization, and more acceptable toxicity.
...
PMID:The pharmacology of intravenous and oral etoposide. 198 31
The chemistry, pharmacology, pharmacokinetics, clinical efficacy, adverse effects, and pharmacodynamics of etoposide are reviewed. Etoposide, although similar in chemical structure to podophyllotoxin, has a different mechanism of cytotoxicity compared with its parent compound. Etoposide may stabilize type II
topoisomerase
-DNA complexes, preventing rejoining of single- and double-strand DNA breaks. Etoposide may also require cellular activation into intermediates, which then bind to DNA and disrupt cellular function. Oral etoposide has an average bioavailability of 50% (range, 17%-137%), with substantial intrapatient and interpatient variability. Etoposide is widely distributed in the body and is highly bound to plasma proteins (greater than 95%). Approximately 50% (range, 20%-81%) of an etoposide dose is recovered in the urine as parent drug or glucuronide, with the remainder of the dose being unaccounted for. The disposition of etoposide in patients with renal and hepatic dysfunction is discussed. Etoposide is effective in combination with other agents against lung cancer, and response rates of 90% in small-cell lung cancer have been observed. When etoposide is used in combination with other agents, response rates of approximately 80% have been observed in patients with testicular cancer. The activity of etoposide in treating leukemia, lymphoma, and breast and ovarian carcinomas and other tumors is discussed. The impact of etoposide on prolonging survival in lung and testicular cancer is addressed, and studies evaluating the pharmacodynamics of etoposide are described. Adverse effects associated with etoposide therapy include myelosuppression, alopecia,
nausea and vomiting
, mucositis, and hypotension after rapid intravenous administration. Etoposide has demonstrated considerable clinical efficacy against a broad spectrum of tumors.
...
PMID:Etoposide: an update. 279 80
Anthracyclines are widely used and effective antineoplastic drugs. Although active against a wide variety of solid tumours and haematological malignancies, their clinical use is hindered by tumour resistance and toxicity to healthy tissue. Modification of the general anthracycline ring structure results in analogues with different but overlapping antitumour and tolerability profiles. Activity of the anthracyclines is related to
topoisomerase
II inhibition, which occurs as a result of anthracycline intercalation between adjacent DNA base pairs. Production of hydroxyl free radicals is associated with antitumour effects and toxicity to healthy tissues. Myocardial tissue is particularly susceptible to free radical damage. Development of tumour cell resistance to anthracyclines involves a number of mechanisms, including P-glycoprotein-mediated resistance. The classical dose-limiting adverse effects of this class of drugs are acute myelosuppression and cumulative dose-related cardiotoxicity. Anthracycline-induced cardiomyopathy is often irreversible and may lead to clinical congestive heart failure. Other toxicities of the anthracyclines, including stomatitis,
nausea and vomiting
, alopecia and 'radiation recall' reactions, are generally reversible. Anthracycline-induced cardiotoxicity may be reduced or prevented by an administration schedule that produces low peak plasma drug concentrations. Administration of dexrazoxane also provides cardioprotection. Dose intensification of anthracyclines may partly overcome resistance but is associated with reduced tolerability. Liposomal encapsulation of doxorubicin or daunorubicin alters the pharmacokinetic properties of the drugs. Increased distribution in tumours, prolonged circulation and reduced free drug concentrations in plasma may increase antitumour activity and improve the tolerability of the anthracyclines.
...
PMID:Anthracyclines in the treatment of cancer. An overview. 936 55
The activity of topotecan was evaluated in patients with myelodysplastic syndrome (MDS) and chronic myelomonocytic leukemia (CMML). Sixty patients with a diagnosis of MDS (n = 30) or CMML (n = 30) were treated. Their median age was 66 years, with 50 patients (83%) being over 60 years of age at time of study entry. Chromosomal abnormalities were present in 50% of patients and thrombocytopenia of less than 50 x 10(9)/L in 50%. Topotecan was administered as 2 mg/m2 by continuous infusion over 24 hours daily for five days (10 mg/m2 per course) every 4 to 6 weeks for two courses, then at maximum tolerated dose level (1-2 mg/m2 by continuous infusion over 24 hours daily for five days) once every 4-8 weeks for a maximum of 12 courses. Evaluation of outcome and of differences among subgroups was performed according to standard methods; the criteria for response were those used for acute leukemia. Nineteen patients (31%) achieved a complete response (CR). A CR was achieved in 11 of 30 patients with MDS (37%) and in eight of 30 with CMML (27%). A CR was achieved in 10 of 23 patients with previously untreated MDS (43%). Eight of 11 patients who presented with cytogenetic abnormalities (five of which involved chromosome 5 and/or 7 abnormalities) and achieved CR, were evaluated cytogenetically in CR: all were cytogenetically normal in CR. Characteristics associated with a higher CR rate were lack of previous chemotherapy, absence of ras oncogene mutations, and presence of less than 10% monocytes in either peripheral blood or bone marrow. In contrast, CR rates were similar by different agent groups, by different karyotype abnormalities, and by other pre-therapy peripheral blood counts. Non-myelosuppressive side effects were mucositis in 67% of patients (severe [grade 3-4] 23%), diarrhea in 38% (severe 17%), and
nausea and vomiting
in 28% (severe 5%). Febrile episodes during neutropenia occurred in 85% of patients and documented infections in 47 %. Mortality in the first four weeks was 20%. With a median follow-up duration of 31 months, the 12 month survival rate was 38%, median survival time 10.5 months, and median remission duration 7.5 months. In summary, topotecan has significant single-agent activity in MDS and CMML. Complete responses associated with topotecan therapy often involve the disappearance of abnormal, poor-prognosis karyotypes, which is particularly encouraging. Future strategies to optimize topotecan's role include combination regimens with
topoisomerase
II reactive agents, cytarabine, or hypomethylating agents (azacytidine and decitabine).
...
PMID:Results of topotecan single-agent therapy in patients with myelodysplastic syndromes and chronic myelomonocytic leukemia. 992 42
Dexrazoxane is a bidentate chelator of divalent cations. Pretreatment with short infusions of dexrazoxane prior to bolus doxorubicin has been shown to lessen the incidence and severity of anthracycline-associated cardiac toxicity. However, because of rapid, diffusion-mediated cellular uptake and the short plasma half-life of dexrazoxane, combined with prolonged cellular retention of doxorubicin, dexrazoxane may be more effective when administered as a continuous infusion. Thus, a Phase I pharmacokinetic trial of a 96-h infusion of dexrazoxane was performed. Dexrazoxane doses were escalated in cohorts of 3 to 6 patients per dose level. All patients received granulocyte-colony stimulating factor at a dose of 5 microg/kg/day starting 24 h after completion of the dexrazoxane infusion. Plasma samples were collected and analyzed for dexrazoxane by high-performance liquid chromatography. Urine collections were performed at baseline and during the infusion to determine the renal clearance of dexrazoxane and the excretion rate of divalent cations. Twenty-two patients were enrolled at doses ranging from 125 to 250 mg/m(2)/day. Grade 3 and 4 toxicities included grade 4 thrombocytopenia in 2 patients treated at 250 mg/m(2)/day, grade 3 thrombocytopenia and grade 4
nausea and vomiting
in 1 patient treated at 221 mg/m(2)/day, grade 4 diarrhea and grade 3
nausea and vomiting
in 1 patient treated at 221 mg/m(2)/day, and grade 3 hypertension in 1 patient treated at 166.25 mg/m(2)/day. Steady-state dexrazoxane levels ranged from 496 microg/l (2.2 microM) to 1639 microg/l (7.4 microM). Dexrazoxane plasma CL(ss) and elimination t(1/2) were 7.2 +/- 1.6 l/h/m(2) and 2.0 +/- 0.8 h, respectively. The mean percentage of administered dexrazoxane recovered in the urine at steady state was 30% (range, 10-66%). Urinary iron and zinc excretion during the dexrazoxane infusion increased in 12 of 18 and 19 of 19 patients by a median of 3.7- and 2.4-fold, respectively. These results suggest that dexrazoxane as a 96-h infusion can be safely administered with granulocyte-colony stimulating factor at doses that achieve plasma levels that have been demonstrated previously to inhibit
topoisomerase
II activity and to induce apoptosis in vitro. Additional studies will be required to determine whether the combination of continuous infusions of dexrazoxane and doxorubicin would provide enhanced cardioprotection compared with the currently recommended bolus or short infusion schedules.
...
PMID:Phase I trial of 96-hour continuous infusion of dexrazoxane in patients with advanced malignancies. 1141 Apr 92
The inhibition of topoisomerase I by topotecan results in a compensatory increase in
topoisomerase
II associated with increased in vitro sensitivity of tumors to etoposide. Maximal synergy has been observed for the sequence of topotecan followed by etoposide. Carboplatin has clinical activity when combined with either of these two agents. These interactions were the pharmacologic rationale for topotecan p.o. days 1-5, carboplatin i.v. day 6, and etoposide p.o. days 6-10. Three successive dose levels were explored: (1) topotecan 2mg/day, carboplatin AUC 5, etoposide 150 mg/day; (2) topotecan 3mg/day, carboplatin AUC 5, etoposide 150 mg/day; and (3) topotecan 3mg/day, carboplatin AUC 5, etoposide 200mg/day. Filgrastim 5 microg/kg/day was injected s.c. days 11-18. Up to 6 cycles were administered every 21 days. Eligible patients had measurable or evaluable, extensive disease, small lung cell lung cancer, no prior chemotherapy, ECOG performance status 0-2, and adequate hematologic, renal, and hepatic function. Follow-up was weekly for CBC. Tumor response was assessed after 2 and 6 cycles. Dose limiting toxicity (DLT) was defined as any of the following in cycle 1: grade 3 or 4 non-hematologic toxicity other than
nausea and vomiting
, grade 4 neutropenia lasting more than 3 days, neutropenic fever or sepsis, grade 4 thrombocytopenia, or failure to recover neutrophils >or=1500/microl or platelets >or=100,000/microl by day 28. Ten patients were enrolled: median age 62 (range, 50-79); female/male 4/6; and performance status 0/1/2 in 2/7/1. Three patients each were treated on dose levels 1 and 2 without DLT. The first 2 patients entered on dose level 3 had no DLT. The third patient on dose level 3 developed grade 4 neutropenia lasting more than 3 days, neutropenic fever, and grade 4 thrombocytopenia on day 15 of cycle 1. The fourth patient on dose level 3 developed grade 4 thrombocytopenia on day 18 of cycle 1. One patient received only 1 cycle and was not evaluable for response. Seven patients completed 6 cycles: 1 had a complete response and 6 achieved a partial response. The third patient on dose level 3 received 2 cycles and had stable disease, but had to be removed from protocol treatment because of grade 4 neutropenia despite dose reduction in cycle 2. The fourth patient on dose level 3 achieved a partial response, but had to be removed from protocol therapy after cycle 5 because of recurrent grade 4 thrombocytopenia. In conclusion, neutropenia and thrombocytopenia were dose-limiting. The maximum tolerated dose (MTD) is topotecan 3mg/day p.o. days 1-5, carboplatin AUC 5i.v. day 6, and etoposide 150 mg/day p.o. days 6-10 with filgrastim.
...
PMID:Phase I and pharmacologic study of sequential topotecan-carboplatin-etoposide in patients with extensive stage small cell lung cancer. 1704 3
Currently, approximately 40 drugs are registered for the chemotherapeutic treatment of cancer, the vast majority of which either interact directly with DNA (eg, alkylating, methylating, platinating agents,
topoisomerase
inhibitors), or affect DNA synthesis (antimetabolites). Whilst such agents remain of great importance in combination chemotherapy regimens, many cancer drug discovery groups have questioned whether any further significant gains may be made through the development of novel DNA-interactive drugs. Such agents tend to be associated with dose-limiting antiproliferative tissue toxicities (eg, myelo-suppression,
nausea and vomiting
, diarrhea or mucositis) which is indicative of their general lack of selectivity in targeting tumor versus normal tissue DNA. Perhaps surprisingly to some, Dr D Von Hoff (University of Texas Health Science Center, San Antonio, Texas, USA) proposed that the investigation of DNA-interactive agents is still yielding some promising agents. He illustrated this with the following new agents.
...
PMID:DNA-interactive agents. 1846 68
