Phase II Study of Intravenous Idarubicin in Unfavorable Non-Hodgkin's Lymphoma

Case, Delvyn C., Gerber, Mirjam C., Gams, Richard A., Crawford, Jeffrey, Votaw, May L., Higano, Celestia S., Pruitt, Brian T., Gould, James

01 January 1993

Idarubicin, a new analogue of daunorubicin, was administered intravenously at a dose of 15 mg/m2 to 31 patients with previously treated patients with unfavorable non-Hodgkin's lymphoma. Clinical characteristics included median age 69 years, performance status 1, and prior chemotherapeutic regimens 1. Twenty of the patients were relapsing after prior therapy and 11 were refractory; 29 had received prior anthracycline or anthracenedione. Responses were observed in 43% of patient (3 CR and 10 PR) with a median duration of 10 + months (2-29+ months). Idarubicin was well tolerated with non-hematologic toxicities (nausea/vomiting, mucositis, and anorexia) seen in <50% of patients. Median hematologic values during the first cycle for this dosage included WBC 1300/mm3 platelets 129,000/mm3, and hemoglobin 10.9 mg/dl. With dose escalation, hematologic toxicity was dose-limiting. Symptomatic cardiac toxicity was observed in one patient who had received maximum dose doxorubicin and radiotherapy. Median values for the cardiac ejection fraction during the full course of therapy for the entire group of patients were 0.62 (initial) and 0.60 (final). Idarubicin in intravenous form is an active drug in previously treated patients with unfavorable non-Hodgkin's lymphoma. Further studies employing idarubicin in non-Hodgkin's lymphoma should be considered. Cardiac function should be followed in trials utilizing anthracycline-type chemotherapeutic agents.

chemotherapy

clinical trials

idarubicin

Non-Hodgkin's lymphoma

phase II studies

Synthesis And Characterization Of Fatty Acid Based Hyperbranched Polymers For Anti-cancer Drug Delivery

Guc, Esra

01 June 2008

Conventional methods of chemotherapy requires novel therapy systems due to serious side effects and inefficiency of drug administration. In recent years many studies are carried out to improve drug delivery systems. Polymers are one of the most important elements for drug delivery research due to their versatility. By the discovery of dendritic polymers, drug delivery studies gained a new vision. Highly branched monodisperse structure, multiple sites of attachment, well-defined size and controllable physical and chemical properties make them efficient drug delivery systems. In this research hyperbranched dendritic polymers were sythesized and characterized for hydrophobic drug delivery. Dipentaerythritol which was used as core molecule, esterified with dimethylol propionic acid. Ricinoleic acid was esterified with the end groups of dimethylol propionic acid and hyperbranched resin (HBR) was formed. By considering the properties of HBR, hydrophobic tamoxifen and idarubicin were used for drug delivery study. The most efficient loading was determined as 73% for tamoxifen and 74% for idarubicin. Drug-HBR interactions and changes in properties of HBR were determined by FTIR, zeta potential and particle size measurements. FTIR results indicated that idarubicin chemically interacted with HBR while tamoxifen physically loaded to HBR. Drug delivery profile of HBR was studied in the absence and presence of lipase from Pseudomonas sp. and sodium dodecyl sulfate (SDS). Results revelaed that lipase and SDS increased the release rate of tamoxifen while idarubicin release rate was not affected. The effect of lipase was also tested for the degradation of HBR and it was indicated that lipase sustain a faster degradation. Finally toxicity of HBR and drug loaded HBR on MCF-7 breast cancer cell line was determined with XTT proliferation assay. Empty HBR did not cause significant toxicity on MCF-7 cells while drug loaded HBR was more toxic than free drug. By this study the efficiency of novel synthesized hyperbranched polymer in drug delivery was shown.

QH Life 501-531

The accumulation of mutant p53 in human cancer cells / Die Akkumulation von mutiertem p53 in humanen Krebszellen

Bug, Monika

09 November 2010

No description available.

570 Biowissenschaften

Biologie

mutiertes p53

Chemotherapeutika

Anthrazykline

Topoisomerase II Inhibitoren

Doxorubicin

Idarubicin

WRAP53

mutant p53

chemotherapeutics

anthracyclines

topoisomerase II inhibitor

doxorubicin

idarubicin

WRAP53

42.00

WA 000: Biologie

Enzyme-catalyzed Reductive Activation Of Anticancer Drugs Idarubicin And Mitomycin C

Celik, Haydar

01 January 2008

Idarubicin (IDA) and mitomycin C (MC) are clinically effective quinone-containing anticancer agents used in the treatment of several human cancers. Quinone-containing anticancer drugs have the potential to undergo bioreduction by oxidoreductases to reactive species, and thereby exert their cytotoxic effects. In the present study, we investigated, for the first time, the potential of IDA, in comparison to MC, to undergo reductive activation by NADPH-cytochrome P450 reductase (P450R), NADH-cytochrome b5 reductase (b5R) and P450R-cytochrome P4502B4 (CYP2B4) system by performing both in vitro plasmid DNA damage experiments and enzyme assays. In addition, we examined the potential protective effects of some antioxidants against DNA-damaging effects of IDA and MC resulting from their reductive activation. To achieve these goals, we obtained P450R from sheep lung, beef liver and PB-treated rabbit liver microsomes, b5R from beef liver microsomes and CYP2B4 from PB-treated rabbit liver microsomes in highly purified forms. The plasmid DNA damage experiments demonstrated that P450R is capable of effectively reducing IDA to DNA-damaging species. The effective protections provided by antioxidant enzymes, SOD and catalase, as well as scavengers of hydroxyl radical, DMSO and thiourea, revealed that the mechanism of DNA damage by IDA involves the generation of ROS by redox cycling of IDA with P450R under aerobic conditions. The extent of DNA damages by both IDA and MC were found to increase with increasing concentrations of the drug or the enzyme as well as with increasing incubation time. IDA was found to have a greater ability to induce DNA damage at high drug concentrations than MC. The plasmid DNA experiments using b5R, on the other hand, showed that, unlike P450R, b5R was not able to reduce IDA to DNA-damaging reactive species. It was also found that in the presence of b5R and cofactor NADH, MC barely induced DNA strand breaks. All the purified P450Rs reduced IDA at about two-fold higher rate than that of MC as shown by the measurement of drug-induced cofactor consumption. This indicates that IDA may be a more potent cytotoxic drug than MC in terms of the generation of reactive metabolites. The results obtained from enzyme assays confirmed the finding obtained from plasmid DNA experiments that while MC is a very poor substrate for b5R, IDA is not a suitable substrate for this enzyme unlike P450R. The reconstitution experiments carried out under both aerobic and anaerobic conditions using various amounts of CYP2B4, P450R and lipid DLPC revealed that reconstituted CYP2B4 produced about 1.5-fold and 1.4-fold rate enhancements in IDA and MC reduction catalyzed by P450R alone, respectively. The present results also showed that among the tested dietary antioxidants, quercetin, rutin, naringenin, resveratrol and trolox, only quercetin was found to be highly potent in preventing DNA damage by IDA. These results may have some practical implications concerning the potential use of P450R as therapeutic agent on their own in cancer treatment strategies. Selective targeting of tumor cells with purified P450R by newly developed delivery systems such as using polymers, liposomes or antibodies may produce greater reductive activation of bioreductive drugs in tumor cells. Consequently, this strategy has a high potential to increase the efficacy and selectivity of cancer chemotherapy.

QD Biochemistry 415-436