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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Microphysiometry in the evaluation of cytotoxic drugs with special emphasis on the novel cyanoguanidine CHS 828

Ekelund, Sara January 2001 (has links)
<p>This thesis describes the use of a new technology, the Cytosensor<sup>®</sup> microphysiometer, in the in vitro evaluation of cytotoxic drugs, using the lymphoma cell line U-937 GTB and primary cultures of tumour cells from patients as model systems. The method was specifically applied to study the metabolic effects of the novel cyanoguanidine N-(6-(4-chlorophenoxy)hexyl)-N’-cyano-N’’-4-pyridylguanidine, CHS 828, currently in phase I/II clinical trials. </p><p>The Cytosensor<sup>®</sup> measures metabolic effects as changes in the rate of extracellular acidification of cells exposed to a drug by perfusion. A number of standard cytotoxic drugs were found to produce typical and reproducible acidification response patterns during observation times up to 20 h. There seemed to be a relationship between a decrease in acidification and cytotoxicity, measured in the fluorometric microculture cytotoxicity assay (FMCA), after 20-24 h of continuous drug exposure.</p><p>In U-937 cells, CHS 828 induced a cytotoxic effect characterised by a steep concentration-response relationship followed by a plateau. After 24 h of incubation the DNA and protein synthesis were turned off. CHS 828 was found to produce a rapid and prolonged increase in extracellular acidification and lactate production similar to that of the structurally related mitochondrial inhibitor m-iodobenzylguanidine (MIBG). The CHS 828 induced acidification was observed in cell lines as well as in cells from various tumour types from patients and probably originates from increased glycolytic flux. The effects may be secondary to block of oxidative phosphorylation in the mitochondria, but the relevance of the early acidification is not clear. CHS 828 seemed to induce a late, at approximately 15 h, inhibition of the glycolysis followed by loss of ATP and subsequent cell death. After exposure to MIBG the loss of ATP and cell death occurred earlier and in parallel. The effects of CHS 828 were not found to resemble those of the structurally related polyamine biosynthesis inhibitor methylglyoxal-bis(guanyl-hydrazone) (MGBG). Thus, CHS 828 may represent a new and, thus, interesting mode of cytotoxic action worthwhile for further development.</p><p>In combinatory studies, a synergistic interaction was demonstrated between CHS 828 and the non-toxic drug amiloride. Additive-to-synergistic effects were also seen between CHS 828 and the bioreductive cytotoxic drug mitomycin C. In U-937 cells as well as in tumour cells from patients, CHS 828 demonstrated synergistic interactions in combination with melphalan and etoposide. </p><p>It is concluded that measurement in the Cytosensor<sup>®</sup> microphysiometer of early cellular metabolic changes is a feasible and potentially valuable complement to more conventional methods used in the evaluation of anticancer agents. </p>
2

Microphysiometry in the evaluation of cytotoxic drugs with special emphasis on the novel cyanoguanidine CHS 828

Ekelund, Sara January 2001 (has links)
This thesis describes the use of a new technology, the Cytosensor® microphysiometer, in the in vitro evaluation of cytotoxic drugs, using the lymphoma cell line U-937 GTB and primary cultures of tumour cells from patients as model systems. The method was specifically applied to study the metabolic effects of the novel cyanoguanidine N-(6-(4-chlorophenoxy)hexyl)-N’-cyano-N’’-4-pyridylguanidine, CHS 828, currently in phase I/II clinical trials. The Cytosensor® measures metabolic effects as changes in the rate of extracellular acidification of cells exposed to a drug by perfusion. A number of standard cytotoxic drugs were found to produce typical and reproducible acidification response patterns during observation times up to 20 h. There seemed to be a relationship between a decrease in acidification and cytotoxicity, measured in the fluorometric microculture cytotoxicity assay (FMCA), after 20-24 h of continuous drug exposure. In U-937 cells, CHS 828 induced a cytotoxic effect characterised by a steep concentration-response relationship followed by a plateau. After 24 h of incubation the DNA and protein synthesis were turned off. CHS 828 was found to produce a rapid and prolonged increase in extracellular acidification and lactate production similar to that of the structurally related mitochondrial inhibitor m-iodobenzylguanidine (MIBG). The CHS 828 induced acidification was observed in cell lines as well as in cells from various tumour types from patients and probably originates from increased glycolytic flux. The effects may be secondary to block of oxidative phosphorylation in the mitochondria, but the relevance of the early acidification is not clear. CHS 828 seemed to induce a late, at approximately 15 h, inhibition of the glycolysis followed by loss of ATP and subsequent cell death. After exposure to MIBG the loss of ATP and cell death occurred earlier and in parallel. The effects of CHS 828 were not found to resemble those of the structurally related polyamine biosynthesis inhibitor methylglyoxal-bis(guanyl-hydrazone) (MGBG). Thus, CHS 828 may represent a new and, thus, interesting mode of cytotoxic action worthwhile for further development. In combinatory studies, a synergistic interaction was demonstrated between CHS 828 and the non-toxic drug amiloride. Additive-to-synergistic effects were also seen between CHS 828 and the bioreductive cytotoxic drug mitomycin C. In U-937 cells as well as in tumour cells from patients, CHS 828 demonstrated synergistic interactions in combination with melphalan and etoposide. It is concluded that measurement in the Cytosensor® microphysiometer of early cellular metabolic changes is a feasible and potentially valuable complement to more conventional methods used in the evaluation of anticancer agents.

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