Chemical transformation of cannabidiol into psychotropic cannabinoids under acidic reaction conditions: Identification of transformed products by GC-MS.

IF 2.6 3区 农林科学 Q2 FOOD SCIENCE & TECHNOLOGY
Minsun Jeong, Sangin Lee, Chaeyoung Seo, Eunjeong Kwon, Soohyang Rho, Mansoo Cho, Moon Yeon Kim, Wonwoong Lee, Yong Sup Lee, Jongki Hong
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引用次数: 2

Abstract

Recently, cannabidiol (CBD), one of the major components of the Cannabis species, has been a focus in the cannabis industry due to its various pharmacological effects. Interestingly, CBD can be converted into several psychoactive cannabinoids, such as 9-tetrahydrocannabinol (Δ9-THC) and its structural isomers, under acidic reaction conditions. In this study, chemical transformation of CBD in ethanol solution was conducted with variation in pH at 2.0, 3.5, and 5.0 by addition of 0.1 M hydrochloric acid (HCl). These resulting solutions were derivatized with trimethylsilyl (TMS) reagent and analyzed using GC/MS-scan mode. Time profiles of CBD degradation and transformation of products were examined according to variations in pH and temperature. Several transformed products produced after the acidic reaction of CBD were identified by matching retention times and mass spectra to authentic standards. Regarding the identification of products without authentic standards, the EI-mass spectra of such cannabinoid-OTMS derivatives were interpreted according to structural class, suggesting mass fragmentation pathways. From the GC/MS data, Δ9-THC, CBC, and ethoxy-hexahydrocannabinol (HHC) analogs were shown to be major components, and THC isomers (Δ8- and Δ10-THCs) and 9-hydroxy-HHC were observed as minor components. Using time profile data, the acidity of the reaction solution was an important factor in degradation of CBD. Degradation of CBD and formation of THC rarely occurred at pH 5.0, even at 70 °C with a long process time of 24 h. In contrast, degradation of CBD occurred readily at pH 3.5 and 30 °C over a short process time and was further accelerated by lowering pH, increasing temperature, and lengthening the process time. Based on profile data and identified transformed products, formation pathways from the degradation of CBD under acidic reaction conditions are suggested. Among the transformed products, seven components are known to have psychoactive effects. Thus, industrial CBD manufacturing processes in food and cosmetic products should be carefully controlled. These results will provide important guidelines on the control of manufacturing processes, storage, fermentation processes, and new regulation in industrial applications of CBD.

大麻二酚在酸性条件下化学转化为精神类大麻素:转化产物的GC-MS鉴定。
近年来,大麻二酚(cannabidiol, CBD)作为大麻的主要成分之一,因其具有多种药理作用而成为大麻行业研究的热点。有趣的是,在酸性反应条件下,CBD可以转化为几种具有精神活性的大麻素,如9-四氢大麻酚(Δ9-THC)及其结构异构体。在本研究中,通过添加0.1 M的盐酸(HCl),在pH为2.0、3.5和5.0的乙醇溶液中进行CBD的化学转化。用三甲基硅基(TMS)试剂衍生化所得溶液,采用GC/ ms扫描模式进行分析。根据pH和温度的变化,研究了CBD降解和产物转化的时间曲线。通过将保留时间和质谱与正品标准相匹配,鉴定了CBD酸反应后产生的几种转化产物。对于无标准品的鉴别,根据结构类对大麻素- otms衍生物的ei -质谱进行了解释,提示了质量破碎途径。GC/MS数据显示,Δ9-THC、CBC和乙氧基六氢大麻酚(HHC)类似物是主要成分,四氢大麻酚异构体(Δ8-和Δ10-THCs)和9-羟基HHC是次要成分。时间剖面数据表明,反应溶液的酸度是影响CBD降解的重要因素。在pH 5.0条件下,即使在70°C条件下,长时间处理24 h, CBD的降解和THC的形成也很少发生。相比之下,在pH 3.5和30°C条件下,CBD的降解在短时间内很容易发生,并且通过降低pH、升高温度和延长处理时间进一步加速了降解。根据剖面数据和鉴定的转化产物,提出了CBD在酸性条件下降解生成的途径。在转化后的产品中,已知有七种成分具有精神活性。因此,食品和化妆品中的工业CBD制造过程应仔细控制。这些结果将为CBD的生产过程、储存、发酵过程的控制以及工业应用中的新法规提供重要指导。
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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来源期刊
Journal of Food and Drug Analysis
Journal of Food and Drug Analysis 医学-食品科技
CiteScore
6.30
自引率
2.80%
发文量
36
审稿时长
3.8 months
期刊介绍: The journal aims to provide an international platform for scientists, researchers and academicians to promote, share and discuss new findings, current issues, and developments in the different areas of food and drug analysis. The scope of the Journal includes analytical methodologies and biological activities in relation to food, drugs, cosmetics and traditional Chinese medicine, as well as related disciplines of topical interest to public health professionals.
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