Ketyl Radical Enabled Synthesis of Oxetanes

Synthesis Pub Date : 2024-06-17 DOI:10.1055/s-0043-1774907

Michael R. Gatazka, Seren G. Parikh, Katie A. Rykaczewski, Corinna S. Schindler

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Abstract

Oxetanes, 4-membered oxygen-containing heterocycles, were identified to have pharmaceutical applications after the discovery of the chemotherapeutic drug taxol (Paclitaxel) and its analogues. Furthermore, oxetanes have been identified as bioisosteres for several common functional groups and are present in a number of natural products. However, oxetanes are one of the least common oxygen-containing heterocycles in active pharmaceutical ingredients on the market, which can be attributed, in part, due to challenges with their synthesis. Previous strategies rely on nucleophilic substitutions or [2+2]-cycloadditions, but are limited by the stepwise buildup of starting material and limitations in scope resulting from requirements for activated substrates. To address these limitations, we envisioned activating simple carbonyls to their corresponding α-oxy iodides to promote ketyl radical formation. These radicals can then undergo atom-transfer radical addition with alkenes followed by one-pot nucleophilic substitution to produce oxetanes. Herein, we present a proof-of-principle of this strategy in which fluoroalkyl carbonyls are successfully converted into the corresponding fluoroalkyl oxetanes.

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酮基自由基促成氧杂环丁烷的合成

氧杂环是一种 4 元含氧杂环，在发现化疗药物紫杉醇（taxol）及其类似物后，被认为具有制药用途。此外，氧杂环丁烷已被确定为几种常见官能团的生物异构体，并存在于许多天然产品中。然而，在市场上的活性药物成分中，氧杂环丁烷是最不常见的含氧杂环之一，部分原因是其合成面临挑战。以前的策略依赖于亲核取代或 [2+2]- 环加成，但受限于起始材料的逐步积累，以及对活化底物要求的范围限制。为了解决这些限制，我们设想将简单的羰基活化为相应的 α-oxy 碘化物，以促进酮基的形成。然后，这些自由基可与烯烃进行原子转移自由基加成，再通过单锅亲核取代反应生成氧杂环丁烷。在此，我们介绍了这一策略的原理验证，其中氟烷基羰基被成功转化为相应的氟烷基氧杂环丁烷。

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Synthesis

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