A Molecular Modeling Study into Brønsted and Lewis Acid Catalyzed Conversion of CBD into Other Cannabinoids

Biologics Pub Date : 2024-03-04 DOI:10.3390/biologics4010006

Wim Buijs

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Abstract

There is a continuous interest in cannabinoids like Δ9-tetrahydrocannabinol (Δ9-THC) and cannabidiol (CBD). Previous experimental research has described the conversion of CBD to either Δ8-THC or Δ9-THC, depending on the acid catalyst applied. The use of para-toluene sulfonic acid (pTSA) has led to the formation of Δ8-THC, while boron trifluoride etherate (BF3·Et2O) has mainly yielded Δ9-THC. The enormous difference in product selectivity between these two catalysts was investigated with Molecular Modeling, applying quantum chemical density functional theory. It was found that pTSA leads to fast isomerization of Δ9-CBD to Δ8-CBD and subsequent ring closure to Δ8-THC. BF3·Et2O catalysis leads to the formation of tertiary carbenium ions in the transition states, which yield Δ9-THC and some iso THC. Under dry conditions in refluxing toluene, it was found that pTSA is predominantly present as a dimer, and only a small fraction is available as monomeric catalyst. Applying the computationally derived activation barriers in transition state theory yielded reaction rates that predicted the amounts of cannabinoids that are in close agreement with the experimental findings from the previous literature.

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布氏酸和路易斯酸催化 CBD 转化为其他大麻素的分子模型研究

人们对Δ9-四氢大麻酚（Δ9-THC）和大麻二酚（CBD）等大麻素一直很感兴趣。先前的实验研究描述了大麻二酚向 Δ8-THC 或 Δ9-THC 的转化过程，具体取决于所使用的酸催化剂。使用对甲苯磺酸（pTSA）可生成 Δ8-THC，而三氟化硼醚酸盐（BF3-Et2O）则主要生成 Δ9-THC。应用量子化学密度泛函理论，通过分子建模研究了这两种催化剂在产物选择性上的巨大差异。研究发现，pTSA 可使 Δ9-CBD 快速异构化为 Δ8-CBD 并随后闭环生成 Δ8-THC。在 BF3-Et2O 催化下，过渡态中会形成三级硒离子，从而生成 Δ9-THC 和一些异 THC。在回流甲苯的干燥条件下，研究发现 pTSA 主要以二聚体形式存在，只有一小部分可以作为单体催化剂。应用计算得出的过渡态理论活化势垒得出的反应速率预测出的大麻素含量与之前文献中的实验结果非常接近。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Biologics

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