Antonino Suarato scite author profile

The band assignment of the circular dichroism (CD) spectra of anthracyclines can provide us with the tools to study the interaction of these molecules with biomolecules, such as DNA and membranes, and also with metal ions. This paper reports the CD spectra of 17 anthracycline derivatives and the tentative assignment of the bands to specific electronic transitions. The deprotonation of some anthracyclines, such as doxorubicin, daunorubicin, and idarubicin, have been also studied in order to characterize the electronic transitions involved in the acid-base process. Our evidence suggests the following assignment. The position of the band assigned to pi-->pi transition, polarized along the short axis of the molecule ( approximately 290 nm), does not depend on the hydroxyl group at C(11) (presence and/or ionization state), whereas the position of the band assigned to the pi-->pi transition ( approximately 480 nm), polarized along the long axis, is strongly dependent on it. Concerning the n-->pi transitions, the bands at approximately 320 and approximately 350 nm have a strong contribution of the n-->pi C(12)=O transition and the n-->pi C(5)=O transition, respectively.

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Recent Anticancer Cytotoxic Agents

Cozzi¹,

Mongelli²,

Suarato

2004

CMCACA

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In spite of the impressive progress in diagnosis, surgery and therapy that occurred since the Sixties, the overall cancer mortality is still high and the medical need is largely unmet. A number of innovative strategies, aimed to target malignant abnormalities of tumor cells are in development and begin to give important results. In alternative, angiogenesis inhibition has been addressed with the aim to limit the tumor ability to grow and metastasize. However, it will likely take some years to fully define the therapeutic role of different innovative drugs. Therefore, cytotoxic drugs will continue to represent a chief part of the therapy in the forthcoming years, possibly in combination with innovative agents addressing molecular targets. Most important traditional chemotherapeutic drugs or investigational anticancer agents were derived from natural sources also through synthetic structural modifications. In the Nineties, taxanes and camptothecins represented important success stories of this approach, while among DNA interacting agents anthracyclines continued to represent a structural platform for discovering new drugs and DNA minor groove binders represented a new field of investigation. Combinatorial chemistry combined with high-throughput screening programs are an important source of totally synthetic new agents, however, it should not be disregarded the fact that nature already performed combinatorial chemistry and leads selection through the ages. New natural or semisynthetic agents acting as tubulin stabilizers or DNA interactive agents of various mechanisms of action are presently investigated and will probably continue to give important contribution to cancer therapy in the near future. In this review, the medicinal chemistry and the development status of these anticancer cytotoxic agents are focused and discussed.

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Novel anthracycline analogs

Grandi¹,

Pezzoni²,

Ballinari³

et al. 1990

Cancer Treatment Reviews

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