Natalie L. Searle scite author profile

The potent antimalarial activity of chloroquine against chloroquine-sensitive strains can be attributed, in part, to its high accumulation in the acidic environment of the heme-rich parasite food vacuole. A key component of this intraparasitic chloroquine accumulation mechanism is a weak base "ion-trapping" effect whereupon the basic drug is concentrated in the acidic food vacuole in its membrane-impermeable diprotonated form. By the incorporation of amino functionality into target artemisinin analogues, we hoped to prepare a new series of analogues that, by virtue of increased accumulation into the ferrous-rich vacuole, would display enhanced antimalarial potency. The initial part of the project focused on the preparation of piperazine-linked analogues (series 1 (7-16)). Antimalarial evaluation of these derivatives demonstrated potent activity versus both chloroquine-sensitive and chloroquine-resistant parasites. On the basis of these observations, we then set about preparing a series of C-10 carba-linked amino derivatives. Optimization of the key synthetic step using a newly developed coupling protocol provided a key intermediate, allyldeoxoartemisinin (17) in 90% yield. Further elaboration, in three steps, provided nine target C-10 carba analogues (series 2 (21-29)) in good overall yields. Antimalarial assessment demonstrated that these compounds were 4-fold more potent than artemisinin and about twice as active as artemether in vitro versus chloroquine-resistant parasites. On the basis of the products obtained from biomimetic Fe(II) degradation of the C-10 carba analogue (23), we propose that these analogues may have a mode of action subtly different from that of the parent drug artemisinin (series 1 (7-16)) and other C-10 ether derivatives such as artemether. Preliminary in vivo testing by the WHO demonstrated that four of these compounds are active orally at doses of less than 10 mg/kg. Since these analogues are available as water-soluble salts and cannot form dihydroartemisinin by P450-catalyzed oxidation, they represent useful leads that might prove to be superior to the currently used derivatives, artemether and artesunate.

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Biomimetic Fe(II)-Mediated Degradation of Arteflene (Ro-42-1611). The First EPR Spin-Trapping Evidence for the Previously Postulated Secondary Carbon-Centered Cyclohexyl Radical

Bishop

Searle

Maggs

et al. 2000

J. Org. Chem.

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The biomimetic iron-mediated degradation of arteflene (Ro-42-1611),an endoperoxide antimalarial: Implications for the mechanism of antimalarial activity

O’Neill

Bishop

Searle

et al. 1997

Tetrahedron Letters

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A carbonyl oxide route to antimalarial yingzhaosu A analogues: Synthesis and antimalarial activity

Neill

Searle

Raynes

et al. 1998

Tetrahedron Letters

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ChemInform Abstract: Biomimetic Fe(II)‐Mediated Degradation of Arteflene (Ro‐42‐1611). The First EPR Spin‐Trapping Evidence for the Previously Postulated Secondary Carbon‐Centered Cyclohexyl Radical.

et al. 2000

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Natalie L. Searle

Mechanism-Based Design of Parasite-Targeted Artemisinin Derivatives: Synthesis and Antimalarial Activity of New Diamine Containing Analogues

Biomimetic Fe(II)-Mediated Degradation of Arteflene (Ro-42-1611). The First EPR Spin-Trapping Evidence for the Previously Postulated Secondary Carbon-Centered Cyclohexyl Radical

The biomimetic iron-mediated degradation of arteflene (Ro-42-1611),an endoperoxide antimalarial: Implications for the mechanism of antimalarial activity

A carbonyl oxide route to antimalarial yingzhaosu A analogues: Synthesis and antimalarial activity

ChemInform Abstract: Biomimetic Fe(II)‐Mediated Degradation of Arteflene (Ro‐42‐1611). The First EPR Spin‐Trapping Evidence for the Previously Postulated Secondary Carbon‐Centered Cyclohexyl Radical.

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