Figure 1:<\/strong> Fifty Nanograms per Milliliter of \u03948-THC-COOH and \u03949-THC-COOH Metabolites in Urine with Method Conditions<\/div>
\n![\"\u03948-THC-COOH](\"https:\/\/ez.restek.com\/images\/cgram\/lc_cf0828.png\" "\\"-\\"")
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<\/div>LC_CF0828<\/p>
As the complexity of THC metabolite testing increases, efficient methods are needed to resolve isomeric compounds for accurate reporting. In this work, an approach to test for \u03948-THC and \u03949-THC and metabolites was developed for whole blood and urine matrices.<\/p>\n\n\n\n
The testing of blood and urine for tetrahydrocannabinol (\u03949-THC) consumption has been around for decades. In the body, \u03949-THC is metabolized into 11-nor-9-carboxy-\u03949-THC (\u03949-THC-COOH), which can then be detected in blood and urine. Historically, \u03949-THC and \u03949-THC-COOH were the only two compounds routinely monitored to determine THC use [1]. As more isomers of \u03949-THC become available on the market, testing becomes more complicated, and novel methods are needed to achieve isomeric resolution. One such isomer, \u03948-THC, emerged on the market after the passing of the 2018 Farm Bill, which appeared to legalize the isomer as a hemp-derived product. This compound forms its own metabolite, 11-nor-9-carboxy-\u03948-THC (\u03948-THC-COOH), which must be resolved from \u03949-THC-COOH. The resolution of these two metabolites is key in reporting accurate specimen findings, and poor resolution can result in invalid data, especially when one isomer is present in much greater abundance.<\/p>\n\n\n\n
In addition, clinical and toxicology labs are interested in the ability to test blood samples after an incident to determine if the individual was under the influence of cannabis. However, this information cannot be gained as easily as other types of routine, time-of-incident testing. Once administered, the concentration of \u03949-THC in blood decreases, but metabolism in the body is nonlinear, thus making assumption on time of exposure difficult [1]. Additionally, some studies have detected THC after 33 days of last use in blood and \u03949-THC-COOH up to approximately 30 days of last use in urine of heavy users, indicating that these compounds are not viable candidates for determining if a suspect is currently under the influence when a sample is collected [1,2]. When \u03949-THC is introduced into the body, it is first metabolized by oxidation to 11-hydroxy-\u03949-tetrahydrocannabinol (11-OH-\u03949-THC), which is a short-lived intermediate, before being further metabolized to \u03949-THC-COOH. While the presence of 11-OH-\u03949-THC alone is not enough to definitively determine the exact time of cannabis use\/exposure, by monitoring for this metabolite, labs may still gain insight into whether an individual has recently ingested cannabis.<\/p>\n\n\n\n
In this work, a method was developed to monitor both \u03948-THC and \u03949-THC carboxy metabolites (\u03949-THC-COOH\/\u03948-THC-COOH) in urine. The method was developed to ensure ample resolution between the two isomers is achieved, so the quantitative data is rugged and robust, even when one of the isomers is present in very high concentrations. An additional method was developed for whole blood to monitor both the parent compounds (\u03948-THC\/\u03949-THC); hydroxy metabolites (11-OH-\u03949-THC\/11-OH-\u03948-THC); and carboxy metabolites (\u03949-THC-COOH\/\u03948-THC-COOH).<\/p>\n\n\n\n
The method conditions were as follows for detecting \u03948-THC-COOH and \u03949-THC-COOH in urine.<\/p>\n\n\n
<\/div>LC_CF0828<\/p>