UMLS:C0149925 - FACTA Search

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Query: UMLS:C0149925 (small cell lung cancer)
6,491 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Cell lines, LC-5 and LC-172, were established from tumors of a small cell lung cancer patient prior to and after combination chemotherapy including etoposide (VP-16), when drug-resistant tumors developed in relapse. A VP-16-resistant cell line, LC-172/VP, was selected from the LC-172 cells in culture in multiple steps with VP-16. LC-172 cells were 3.5-fold resistant to VP-16 in growth inhibition, and 3.3-fold resistant to adriamycin as compared with LC-5 cells. LC-172/VP cells showed large differences in cross-resistance to topoisomerase II-targeting drugs such as VP-16, 200-fold, adriamycin, 10-fold, and MST-16, 4.3-fold; the cells were moderately refractory, 5.5-fold, to vincristine. VP-16 accumulation in the cells was similar in three cell lines. Topoisomerase II unknotting activity was reduced 7- to 10-fold in LC-172/VP and 1.5- to 2-fold in LC-172 cells compared with LC-5 cells, while relaxing activity of topoisomerase I appeared to be unchanged. Topoisomerase II protein was also reduced 5- to 10-fold in LC-172/VP and marginally so in LC-172 cells. Topoisomerase II alpha and II beta were each reduced 10-fold and 2-fold, respectively, in LC-172/VP cells, while they were both slightly decreased (-1.5-fold), respectively, in LC-172 cells compared with LC-5 cells. No apparent alteration in ATP requirement for catalytic activity and in sensitivity to VP-16 was observed for topoisomerase II from the three cell lines. Taken together, these results suggested that resistance to VP-16 in LC-172 and LC-172/VP is associated with a quantitative reduction in expression of topoisomerase II alpha of the parental type.
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PMID:Reduced expression of DNA topoisomerase II confers resistance to etoposide (VP-16) in small cell lung cancer cell lines established from a refractory tumor of a patient and by in vitro selection. 889 98

Many antineoplastic drugs and cytotoxic irradiation induce apoptosis in cancer cells. ICE and ICE-like proteases play important roles in drug-induced apoptosis of cancer cells. We evaluated the cellular factors affecting susceptibility to apoptosis using gene-transfected cells. Introduction of bcl 2 gene into human small cell lung cancer cells conferred resistance to mitomycin C and irinotecan. DNA fragmentation was reduced in these cells. These results indicate apoptosis is one of the mechanisms of cell death caused by some antineoplastic drugs. Investigations are ongoing to elucidate the contribution of the Bcl 2 family proteins to antineoplastic drug induced apoptosis. Wild type p53-transfected cancer cells were sensitive to anticancer drugs. On the other hand, p53-depleted cells were reported to be more sensitive to taxanes than p53-proficient cells. Introduction of Rb gene and p16-gene enhanced cytotoxicity of taxanes and topoisomerase I inhibitors, respectively. In clinical studies, patients of non small cell lung cancer with high expression of Bcl-2 were reported to show longer survival than patients with lower expression. However, this result may be confusing because Bcl-2 reduced the efficacy of antineoplastic drugs. Further evaluation is required to determine the cellular proteins serving as markers for treatment efficacy or prognosis.
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PMID:[Apoptosis and chemosensitivity]. 903 Feb 34

Topotecan (Hycamtin; SmithKline Beecham Pharmaceuticals, Philadelphia, PA), a camptothecin analog, is a novel and specific inhibitor of the nuclear enzyme topoisomerase I. In preclinical studies, topotecan demonstrated significant in vitro activity in a variety of solid tumor explants derived from colorectal, breast, ovarian, renal cell, non-small cell lung cancer, and gastrointestinal sources. Notable activity was also demonstrated in vivo in a wide range of animal tumor models. A large number of phase I studies with topotecan have been conducted since 1992 in both adults and children with a broad range of refractory malignancies and as many as 14 different dosing schedules. Complete, partial, or minor responses were demonstrated in patients with recurrent or refractory neuroblastoma, non-small cell lung cancer, small cell lung cancer, ovarian cancer, breast cancer, colon cancer, esophageal cancer, renal cell carcinoma, and squamous cell carcinoma. The antitumor activity of topotecan in these phase I evaluations was associated more often with frequent or continuous dosing schedules compared with less frequent or short exposure schedules. Maximum tolerated doses were predominantly dependent on the dosing schedule used. Myelosuppression was the major dose-limiting toxicity across all schedules, and nonhematologic toxicities were generally mild. Data from phase I studies have provided valuable information about antitumor responses, maximum tolerated doses, and dose-limiting toxicities associated with different dosing schedules. Based on this information, there was substantial enthusiasm for further evaluating topotecan in a wide range of cancer patients in phase II studies.
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PMID:Review of phase I clinical studies with topotecan. 942 56

Lung cancer continues to be the leading cause of cancer-related death in both men and women. According to the American Cancer Society, 160,400 people are predicted to die from this disease in 1997. Approximately 20% to 25% of lung cancer cases are classified as small cell lung cancer (SCLC). Although initial response rates to chemotherapy and radiation therapy are high among SCLC patients, nearly all these patients will eventually relapse and require additional treatment. The search for better treatments in relapsed SCLC is thus a high priority. In particular, it is hoped that the availability of new non-cross-resistant chemotherapeutic agents such as topotecan (Hycamtin; SmithKline Beecham Pharmaceuticals, Philadelphia, PA), a topoisomerase I inhibitor, will expand the treatment options. Because results from preclinical studies and phase I trials suggested that topotecan has activity in SCLC, the efficacy of this agent is currently being assessed in phase II and III clinical trials. Results from these trials, summarized here, suggest that topotecan may be a valuable alternative in the treatment of SCLC.
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PMID:Topotecan in small cell lung cancer. 942 58

Preclinical schedule dependency suggests that prolonged maintenance of low plasma levels of topotecan, a specific inhibitor of the nuclear enzyme topoisomerase I, results in optimal antitumor activity. The pharmacokinetics and pharmacodynamics of topotecan, administered as single agent in second-line therapy as a continuous low-dose infusion for 21 days, were evaluated in nine patients with small cell lung cancer (SCLC). Topotecan was administered i.v. as a 21 day continuous infusion every 28 days via an ambulatory pump. Dosages ranged from 0.4 to 0.6 mg/m2/day. Plasma levels of topotecan, the sum of topotecan, and its hydroxy acid congener and the N-desmethyl metabolite were determined at 1, 7, 14 and 21 days during infusion, using a validated high-performance liquid chromatography method with fluorescence detection. Myelosuppression was the most important toxicity. All patients experienced anemia, being severe (grade 3/4) in 55% of all courses. Other adverse effects were relatively mild and reversible, and included nausea, vomiting, diarrhea and fatigue. Three patients achieved a partial response. Mean steady-state concentrations of topotecan (C(ss)) in the first course were 0.46+/-0.17 and 0.47+/-0.19 ng/ml after doses of 0.4 and 0.5 mg/m2/day, respectively. Steady-state levels of the total of topotecan and hydroxy acid (C(ss,tot)) were 1.28+/-0.25 (range 0.93-1.58) and 1.57+/-0.19 (range 1.43-1.70) ng/ml at doses of 0.4 and 0.5 mg/m2/day, respectively. The percentage of the administered topotecan dose excreted in the urine within 24 h was 40+/-14 and 1.2+/-1.0% for total topotecan and N-desmethyltopotecan, respectively. During the second course, C(ss,tot) was significantly higher (p=0.032, paired t-test), which suggests altered topotecan disposition. A sigmoidal relationship was found between C(ss,tot) and the percent decrease in platelets (r=0.76, p=0.018). We conclude that topotecan administered as a 21 day continuous low-dose infusion has activity as single-agent, second-line therapy in patients with SCLC. There was considerable interpatient and intrapatient variability in systemic exposure to topotecan. Differences in organ function might contribute to this variation. Serum aspartate aminotransferase and albumin levels were predictive of topotecan pharmacokinetics.
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PMID:Continuous infusion of low-dose topotecan: pharmacokinetics and pharmacodynamics during a phase II study in patients with small cell lung cancer. 966 May 38

Topotecan, a water-soluble analogue of camptothecin, is a newly available cytotoxic agent which acts as an inhibitor of topoisomerase I, an enzyme necessary for DNA replication. Topotecan is a semisynthetic product derived from camptothecin, which was discovered during a National Cancer Institute cytotoxic drug screening program almost 30 years ago. It acts by forming a stable covalent complex with the DNA/topoisomerase I aggregate, the so-called 'cleavable complex'. This process leads to breaks in the DNA strand resulting in apoptosis and cell death. Topotecan possesses a serum half-life of approximately 3 h, a high volume of distribution with high tissue uptake and a low protein binding. The chemical structure is based on a lactone ring. Topotecan undergoes reversible hydrolysis from its biologically active lactone form to the open ring inactive carboxylate form. It is also able to penetrate the intact blood-brain barrier. Since most of the agent is excreted by the kidneys, dose adjustment is necessary when renal function is impaired. In contrast, pharmacokinetic behavior is unchanged in patients with limited hepatic function. The principal toxicity of topotecan when administered at standard doses is neutropenia, but thrombocytopenia and anemia occur as well, while the nonhematological toxicities are usually mild. Alopecia is frequently observed and some patients may suffer from pronounced fatigue. Most clinical data available are based on the following schedule: 1.5 mg/m2 topotecan given as a 30-min infusion, days 1-5. There are currently only minimal data available regarding a dose-antitumor activity relationship. Other topotecan administration schedules are currently being investigated. Preclinical data suggest that continuous-infusion schedules may be a better application form in terms of both, toxicity and antitumor activity. However, clinical trials could not confirm these results to date. Results of phase II studies suggest considerable antitumor activity of single agent topotecan in small cell lung cancer and ovarian cancer patients. A randomized phase III trial of topotecan versus paclitaxel in ovarian cancer patients pretreated with cisplatin/cyclophosphamide has demonstrated that topotecan is as effective as paclitaxel in the second-line treatment of these patients. Activity of topotecan was also observed in non-small-cell lung cancer, refractory leukemias/myelodysplastic syndromes and in childhood sarcomas. Due to its unique mechanism of action and lack of cross-resistance, cisplatin, etoposide, cytarabine and paclitaxel are potential interacting partners for combination chemotherapy regimens. However, the best combination regimen as well as the optimal combination schedule have yet to be conclusively determined. The potential of topotecan in a variety of solid tumors, as well as its use in combination regimens for ovarian and small cell lung cancer is currently being investigated.
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PMID:Topotecan - A novel topoisomerase I inhibitor: pharmacology and clinical experience. 988 71

Irinotecan (CPT11), a topoisomerase I inhibitor, is a new cytotoxic agent with a broad spectrum of clinical activity. Two main schedules have been studied and produce similar activity and side-effects: the "european" one--350 mg/m2 every 21 days-, and the "japanese-north american" one where CPT11 is given at a weekly dose of 100-120 mg/m2 for 4 consecutive weeks followed by a 2 week rest period. Activity was initially characterized in advanced colorectal cancers; response rates, disease free-survival and overall survival were 11%, 7-10 months and 8-11 months in patients failing fluoropyrimidine based chemotherapy--statistically improved as compared to best supportive care and infusional fluorouracil-, and 20-30% in patients not previously treated. An interesting activity with response rates of 20-22% (increased to 65% in combination with CDDP) has been shown in relapsed cervix carcinomas; in gastric carcinomas response rates of 20% have been shown, reaching 48% in combination with CDDP. Response rates of 20-22%, increased to 40-60% when irinotecan was associated to CDDP have been reported in non small cell lung cancer and esophagal carcinomas. Further studies are needed for other GI tract cancers, ovarian and head and neck carcinomas while minimal or no clinically meaningful activity has been reported in advanced breast cancer, and haematological malignancies. Irinotecan can be combined to fluoropyrimidines, raltitrexed, cisplatin, carboplatin and oxaliplatin, to gemcitabine, etoposide, vinorelbine and taxanes with flexible schedules (weekly, every 2 weeks, every 21 days. Most of these combinations have an additive or supra additive activity. Its mechanism of action, the spectrum of activity and the acceptable risk-benefit ratio point to irinorecan as a major advance in the field of cytotoxic anticancer therapy.
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PMID:[Clinical activity spectrum of irinotecan]. 993 80

The positive impact on survival of traditional chemotherapeutic agents has renewed interest in developing newer cytotoxic agents and orally active compounds with improved therapeutic indices. In addition, new insights into the pathways of human tumorigenesis have led to novel approaches aimed at specific mechanism-based targets. The taxane class, of which paclitaxel was the first member, has the unique ability to promote and stabilize microtubule function directly, thereby inhibiting mitotic progression and inducing apoptotic cell death. Paclitaxel provides treatment benefit in a broad range of solid tumors including breast, ovarian, and lung cancer. The success with paclitaxel stimulated interest in the microtubule as a new therapeutic target. Taxane analogues with improved preclinical efficacy have been identified and are entering clinical trials. The enthusiasm for oral anticancer agents and the therapeutic importance of platinum compounds has led to the development of JM216 (satraplatin), a novel platinum IV coordination complex with oral activity in cisplatin-resistant cell lines, which is now in phase III trials in prostate cancer. Another compound in late development is DPPE, a chemopotentiator that enhances the in vivo antitumor effects of cytotoxic agents such as doxorubicin, cyclophosphamide, and cisplatin. Agents that inhibit topoisomerase I and II have also been of interest. TAS-103 is a dual topoisomerase I and II inhibitor with preclinical efficacy in a broad spectrum of tumors and in multidrug-resistant tumor cell lines. Vaccination strategies represent a rational therapeutic approach in the minimal residual disease or high-risk adjuvant therapy setting. The GMK and MGV vaccines utilizing ganglioside antigens overexpressed on human tumors such as melanoma and small cell lung cancer appear to induce antibody production reliably at tolerable doses and are under further clinical investigation. Inhibition of matrix metalloproteinases (MMPs) is another attractive target for intervention in several aspects of tumor progression. Local production of MMPs with subsequent degradation of the extracellular matrix is implicated in supporting tumor growth, invasion, and angiogenesis. The development of orally active, nontoxic MMP inhibitors is critical since these compounds will likely require chronic administration in conjunction with other therapies. Oncogenes and tumor suppressor genes are appealing targets for therapy since they are thought to be responsible for a significant number of cancers. Mutations in the Ras oncogene occur with great frequency in a number of human cancers including lung, pancreas, and colon cancer. Clinical development of potent and selective inhibitors of farnesyltransferase, the Ras-processing enzyme, is ongoing. These compounds uncouple Ras activity, affect tumor growth, and have demonstrated significant antitumor activity against experimental models of human cancer. The exciting compounds and novel therapeutic approaches currently under investigation by Bristol-Myers Squibb Pharmaceutical Research Institute offer great potential as effective cancer chemotherapy agents for the near future.
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PMID:Promising new developments in cancer chemotherapy. 1035 61

We established a drug sensitivity panel consisting of 24 human lung cancer cell lines. Using this panel, we evaluated 26 anti-cancer agents: three alkylators, three platinum compounds, four antimetabolites, one topoisomerase I inhibitor, five topoisomerase II inhibitors, seven antimitotic agents and three tyrosine kinase inhibitors. This panel showed the following: a) Drug sensitivity patterns reflected their clinically-established patterns of action. For example, doxorubicin and etoposide were shown to be active against small cell lung cancer cell lines and mitomycin-C and 5-fluorouracil were active against non-small cell lung cancer cell lines, in agreement with clinical data. b) Correlation analysis of the mean graphs derived from the logarithm of IC50 values of the drugs gave insight into the mechanism of each drug's action. Thus, two drug combinations with reverse or no correlation, such as the combination of cisplatin and vinorelbine, might be good candidates for the ideal two drug combination in the treatment of lung cancer, as is being confirmed in clinical trials. c) Using cluster analysis of the cell lines in the panel with their drug sensitivity patterns, we could classify the cell lines into four groups depending on the drug sensitivity similarity. This classification will be useful to elucidate the cellular mechanism of action and drug resistance. Thus, our drug sensitivity panel will be helpful to explore new drugs or to develop a new combination of anti-cancer agents for the treatment of lung cancer.
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PMID:Establishment of a drug sensitivity panel using human lung cancer cell lines. 1035 21

This issue of The Oncologist provides the reader with two useful reviews of the new chemotherapeutic agent topotecan, one of a class of topoisomerase I inhibitors that is being studied and incorporated into the treatment of various malignancies. Topotecan was approved for the treatment of refractory ovarian cancer in 1996, and has shown promising activity against a variety of solid tumors, as well as hematologic malignancies. One paper discusses clinical guidelines for managing topotecan-related hematologic toxicities, and centers on data derived from ovarian cancer studies. The other focuses on the role of topotecan in the treatment of small cell lung cancer (SCLC), where it has consistently shown encouraging results and for which definitive trials are now being conducted. As front-line therapy for ovarian cancer and small cell lung cancer is dominated by platinum-based regimens, the dosing guidelines and management issues discussed are pertinent for both tumor types.
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PMID:Topotecan: Incorporating It Into the Treatment of Solid Tumors. 1038 78

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