Preparation of N-Sulfonyl- and N-Carbonyl-11-Azaartemisinins with Greatly Enhanced Thermal Stabilities: in vitro Antimalarial Activities

Preparation of N-Sulfonyl- and N-Carbonyl-11-Azaartemisinins with Greatly Enhanced Thermal Stabilities: in vitro Antimalarial Activities

As the clinically used artemisinins do not withstand the thermal stress testing required to evaluate shelf life for storage in tropical countries where malaria is prevalent, there is a need to develop thermally more robust artemisinin derivatives. Herein we describe the attachment of electron‐withdr...

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Published in:ChemMedChem Vol. 2; no. 10; pp. 1464 - 1479
Main Authors: Haynes, Richard K., Wong, Ho-Ning, Lee, Kin-Wo, Lung, Chung-Man, Shek, Lai Yung, Williams, Ian D., Croft, Simon L., Vivas, Livia, Rattray, Lauren, Stewart, Lindsay, Wong, Vincent K. W., Ko, Ben C. B.
Format: Journal Article
Language:English
Published: Weinheim WILEY-VCH Verlag 08-10-2007
WILEY‐VCH Verlag
Subjects:
antimalarials
Antimalarials - chemical synthesis
Antimalarials - chemistry
Antimalarials - pharmacology
artemisinins
Artemisinins - chemical synthesis
Artemisinins - chemistry
Artemisinins - pharmacology
azaartemisinins
Drug Stability
Drug Storage
homolysis
Hot Temperature
Plasmodium falciparum
Solubility
thermal stability
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Summary:As the clinically used artemisinins do not withstand the thermal stress testing required to evaluate shelf life for storage in tropical countries where malaria is prevalent, there is a need to develop thermally more robust artemisinin derivatives. Herein we describe the attachment of electron‐withdrawing arene‐ and alkanesulfonyl and ‐carbonyl groups to the nitrogen atom of the readily accessible Ziffer 11‐azaartemisinin to provide the corresponding N‐sulfonyl‐ and ‐carbonylazaartemisinins. Two acylurea analogues were also prepared by treatment of the 11‐azaartemisinin with arylisocyanates. Several of the N‐sulfonylazaartemisinins have melting points above 200 °C and possess substantially greater thermal stabilities than the artemisinins in current clinical use, with the antimalarial activities of several of the arylsulfonyl derivatives being similar to that of artesunate against the drug‐sensitive 3D7 clone of the NF54 isolate and the multidrug‐resistant K1 strain of P. falciparum. The compounds possess relatively low cytotoxicities. The carbonyl derivatives are less crystalline than the N‐sulfonyl derivatives, but are generally more active as antimalarials. The N‐nitroarylcarbonyl and arylurea derivatives possess sub‐ng ml−1 activities. Although several of the azaartemisinins possess log P values below 3.5, the compounds have poor aqueous solubility (<1 mg L−1 at pH 7). The greatly enhanced thermal stability of our artemisinins suggests that strategic incorporation of electron‐withdrawing polar groups into both new artemisinin derivatives and totally synthetic trioxanes or trioxolanes may assist in the generation of practical new antimalarial drugs which will be stable to storage conditions in the field, while retaining favorable physicochemical properties. As a counter to the thermal lability of artemisinins in clinical use, we attached N‐sulfonyl and N‐carbonyl groups to the Ziffer 11‐azaartemisinin to provide new derivatives, some of which possess substantially greater thermal stabilities than current artemisinins, whilst retaining good antimalarial activity against the malaria parasite.
Bibliography:Open Laboratory of Chemical Biology of the Institute of Molecular Technology for Drug Discovery and Synthesis
ark:/67375/WNG-H544GFNR-5
Bayer AG Zentralforschung
ArticleID:CMDC200700065
istex:7E092B5AE928381CD949140F3B943F660CC8FD5E
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:1860-7179
1860-7187
DOI:10.1002/cmdc.200700065