Sensor/effector drug design with potential relevance to cancer

Sensor/effector drug design with potential relevance to cancer

Many cancer cells exhibit a disturbed intracellular redox balance, making them distinctively different from their 'healthy' counterparts. Some tumors, such as solid lung carcinoma, are hypoxic, and its cells are therefore more reducing than normal, while others, such as the ones of breast...

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Bibliographic Details
Published in:Current pharmaceutical design Vol. 12; no. 34; p. 4479
Main Authors: Fry, Fiona H, Jacob, Claus
Format: Journal Article
Language:English
Published: United Arab Emirates 01-12-2006
Subjects:
Animals
Antineoplastic Agents - metabolism
Antineoplastic Agents - pharmacology
Antineoplastic Agents - therapeutic use
Antioxidants - metabolism
Catalysis
Cell Proliferation - drug effects
Drug Design
Humans
Neoplasms - drug therapy
Neoplasms - metabolism
Neoplasms - pathology
Oxidants - metabolism
Oxidants - pharmacology
Oxidation-Reduction
Oxidative Stress - drug effects
Photochemotherapy
Prodrugs - metabolism
Prodrugs - pharmacology
Prodrugs - therapeutic use
Reactive Oxygen Species - metabolism
Sulfides - metabolism
Sulfides - pharmacology
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Summary:Many cancer cells exhibit a disturbed intracellular redox balance, making them distinctively different from their 'healthy' counterparts. Some tumors, such as solid lung carcinoma, are hypoxic, and its cells are therefore more reducing than normal, while others, such as the ones of breast and prostate cancer, proliferate under oxidative stress (OS). These biochemical differences between normal and tumor tissue are significant, and can be used to design effective, yet selective redox drugs. The resulting drug design can follow different avenues. The bioreductive approach is perhaps the most advanced, and uses changes in intracellular redox enzyme concentrations to activate otherwise inactive pro-drug molecules inside cancer cells by a reductive step, often followed by further chemical transformations, such as hydrolysis. Related anti-cancer compounds, such as varacin, employ an intricate combination of reduction and oxidation processes to develop their therapeutic potential inside cells. Another, just emerging approach considers the use of pro-oxidants and catalysts, taking advantage of the inherent efficiency and selectivity associated with OS-induced cell death. Even more complex tactics, such as chelator-assisted photodynamic therapy, exploit the intracellular metal homeostasis to target cancer cells. Together, all of these avenues try to endow molecules with a combination of sensor and effector properties, which might allow them to single out and selectively kill cancer cells without the need for cell-selective drug delivery systems. In the long term, such agents could be associated with high efficiency, good selectivity and dramatically reduced drug side effects.
ISSN:1873-4286
DOI:10.2174/138161206779010512