Sunil Badal, Senior Scientist1, Uma Sreenivasan, Head of Reference Materials R&D1
1-Round Rock, USA
Legalization and use of hemp, recreational and medical cannabis is expanding globally. Cannabidiol (CBD) and tetrahydrocannabinol (THC) containing cannabis products are consumed in various forms such as flowers, vape pens, edibles, concentrates, tinctures, beverages, topicals, capsules, etc. These hemp, CBD, and cannabis products need to be tested to ensure accurate labeling of contents and consumer safety. A research study found that only 17% of edible products were accurately labeled when 75 different cannabis-infused edible products were tested.1 Due to the complexity of cannabis product matrices, sample preparation for cannabinoid testing is very challenging. Accurate extraction and analysis procedures are required to ensure proper regulation of these products. In this study, we explored simple and accurate sample preparation methods for the analysis of cannabinoids from several matrices.
This work provides a complete HPLC-PDA (high-performance liquid chromatography - photodiode array) workflow for cannabinoids analysis using:
Cannabinoids are compounds found in the cannabis plant or synthetic compounds that can interact with the endocannabinoid system. There are more than 100 distinct cannabinoids that have been isolated from cannabis. Many of these cannabinoids are isomers or very similar in structures. Delta9-Tetrahydrocannabinol (∆9-THC) is the most notable primary psychoactive compound and cannabidiol (CBD) is another major non-psychoactive constituent in cannabis. Structures of ∆9-THC, CBD, and some other cannabinoids analyzed by the method described here are shown in Figure 1.
Figure 1.Chemical structures of seventeen cannabinoids analyzed in this study.
Two separate HPLC methods are demonstrated in this study. Mobile phase preparation instructions for both methods are listed in Table 1 below.
Calibration solutions for 17 cannabinoid mixtures were prepared from certified reference materials (CRMs) as described in Table 2 below.
Two separate HPLC-PDA methods were tested for the separation of 17 cannabinoids. The Rapid Gradient Acetonitrile Method is based on Ascentis® Express C18 column with acetonitrile as an organic modifier, whereas the Low-Cost Methanol Method is based on Ascentis® Express C8 column with methanol as an organic modifier. Details of all HPLC parameters are summarized in Table 3 and Table 4 below.
The hemp bud sample needs to be ground into small particles to ensure the maximum number of cannabinoids can be extracted. This homogenization step is probably the biggest challenge if proper equipment for homogenization is not available. Low-temperature homogenization such as frozen ball-milling is the preferred method of homogenization without sample degradation. However, a cryo-cup grinder as suggested in this article can be used as an alternative for small-scale experiments. Step-by-step instructions for hemp bud sample preparation are described below:
Figure 2.Sample preparation workflow for hemp bud.
Since hemp oil can readily dissolve in appropriate solvents, hemp oil sample preparation is relatively simple. The hemp oil sample is first agitated in an appropriate volume of isopropanol and then diluted in methanol. Step-by-step instructions are given below:
Note: Different dilution levels might need to be used to quantitate different cannabinoids. If accurate weighing is not possible for a 10 µL hemp oil sample, a larger amount of sample can be used for the analysis, and volumes of solvents need to be increased accordingly. For example, 50 µL of hemp oil can be agitated in 5 mL isopropanol in a 10 mL volumetric flask and then fill up to the mark with methanol followed by appropriate dilution.
Chocolate samples do not dissolve in methanol or acetonitrile (ACN) solvents easily. The sample needs to be dissolved in water to bring it to a solution and then extracted to the organic phase using the extraction step of the QuEChERS technique.2 The salts in the QuEChERS extraction process effectively force the separation of ACN from the aqueous layer. Sugars remain dissolved in the aqueous phase, while some lipids still get retained in the organic phase. If the extract with lipids is injected without further treatment, it will significantly decrease column life. Hence, techniques like winterization needs to be performed to prepare the final extract. Step-by-step instructions to prepare chocolate samples for cannabinoid potency testing are provided below:
Figure 3.Sample preparation workflow for a chocolate sample.
Sample preparation for gummy is similar to chocolate but it does not necessarily require a winterization step as gummy samples do not generally contain lipids. Just like chocolate, gummy samples also do not dissolve in methanol and need to be dissolved in water first, followed by the QuEChERS extraction process. Step-by-step instructions for gummy sample preparation are provided below.
Figure 4.Sample preparation workflow for a gummy sample.
Sample preparation for hard candy is similar to gummy and it also does not require winterization. Candy can be broken into small pieces to accelerate dissolution in water. In addition, a smaller sample size (1-2 g) can be used with dissolution in 15 mL water or whole candy (4-6 g) can be dissolved in 25 mL water for the first step. The remaining steps are the same as gummy sample preparation.
Cannabinoids from a cream sample can be extracted to solvent by vortex and sonication of melted sample dipped in the extraction solvent. Following are the step-by-step instructions for cream sample preparation:
Two separate HPLC-PDA methods are developed for the separation of 17 cannabinoid mixtures. Chromatograms showing the separation of 17 mix cannabinoids with each method are shown in Figure 5 and Figure 6. Note that the elution order is different with each method. With the Rapid Gradient Acetonitrile Method, all 17 analytes elute within 8 minutes whereas the Low-Cost Methanol Method takes 12 minutes. Cost calculations suggest that the Low-Cost Methanol Method can save >$40 per injection compared to the acetonitrile method.3 The remaining data presented here is with the Acetonitrile method however, Methanol Method is presented as an alternative and can be used if impurities are co-eluting with the analyte of interest. Since the elution order is different, impurities overlapping with analytes in one method could separate in another method. This depends on individual experiments.
Figure 5.Chromatogram for 17 mix cannabinoids obtained with Rapid Gradient Acetonitrile Method.
Figure 6.Chromatogram for 17 mix cannabinoids obtained with Low-Cost Methanol Method.
Figure 7.Six-point calibration curves obtained from Rapid Gradient Acetonitrile Method for 17 cannabinoids within range of 0.25-100 µg/mL. Similar calibration curves were obtained with the Methanol Method.
The following formula is used for the cannabinoid concentration calculation:
Where,
Df = Dilution Factor after extraction
Fv = Final Extraction Volume (mL)
To convert mg/g to weight percentage, the result is divided by 1000 and multiplied by 100:
Cannabinoid concentration (%) = (Cannabinoid concentration (mg/g)/1000) * 100
Hemp bud cannabinoid potency needs to be reported on dry sample weight basis. Here, moisture content was determined by Karl Fischer (KF, coulometry) titration and found to be 8.175%. A detailed description of the KF method can be found elsewhere.4 Cannabinoid concentration determined with Rapid Gradient Acetonitrile Method is given below in Figure 8 and Table 5 as an example. Similar results were obtained with Methanol Method as well (not reported here). The final extract obtained from the sample preparation was diluted by 1:10 and 1:100 times. All three dilution levels were used to quantitate cannabinoid concentration. For example, CBGA concentration is determined from a 1:100 dilution level and ∆9-THC is determined from neat extract solution injection. Table 5 shows the cannabinoid potency in as-is (wet) as well as dry weight basis.
Figure 8.Pie chart showing determined cannabinoid concentrations in hemp bud sample using Rapid Gradient Acetonitrile Method.
A hemp oil sample was prepared as explained in the sample preparation section and the stock solution was diluted 1:10 with methanol. Both diluted and undiluted stock solutions were analyzed with HPLC-PDA. The hemp oil sample contained six cannabinoids which included CBDV, CBG, CBD, CBN, ∆9-THC, and CBC. All cannabinoid concentrations fell within the calibration curve with the first undiluted stock solution except for CBD. CBD concentration was within the calibration curve with 1:10 times diluted solution. Quantitation was performed with respective dilution levels and results are listed in Table 6.
The final extract of the gummy sample was diluted 1:20 with methanol. A diluted sample injection was used to quantitate CBD concentration as shown in Table 7 below.
The final extract of the chocolate sample was diluted 1:20 with methanol. Both dilution levels were used to quantitate cannabinoid concentration. Four cannabinoids were detected above LOQ. Results are summarized in Table 8. Low percent RSDs on determined values from different aliquots suggest that the sample preparation method has good repeatability.
The final extract of the candy sample was diluted 1:20 with methanol. A diluted sample injection was used to quantitate CBD concentration as shown in Table 9 below.
Three aliquots of the cream sample were analyzed. The results are listed in Table 10. The average CBD concentration is determined to be 21.973 mg/g with a % RSD of 5.4 (n=3).
Analyte identification in HPLC-UV analysis depends on retention times and can be compromised by co-eluting peaks. To ensure that no impurity is co-eluting with the peak of interest or to avoid misidentification due to the same retention times of foreign analytes, we compared the UV absorption spectra of analytes with those of the standards. This UV absorption spectra analysis minimized the effects of impurities. For example, in the chocolate extract, there was a peak at the retention time of CBDA, but the UV absorption spectra did not match that of the CBDA standard and therefore it was eliminated from reporting as CBDA. In Figure 9, examples of matching and not-matching spectra of standards with suspected peaks are shown. This UV absorption spectra analysis was performed for each sample type to eliminate such misidentifications.
Figure 9.Overlay of UV absorption spectra of suspected CBDA (A) and CBD (B) peaks from chocolate extract with that of standards. A) Shows that suspected CBDA does not have matching spectra with standard, whereas B) shows that suspected CBD has matching spectra with standard (the purple line is not visible due to overlap).
Sample preparations for cannabinoids analysis from several matrices such as hemp bud, hemp oil, gummy, candy, chocolate, and cream were demonstrated. Two HPLC-PDA methods based on Ascentis® Express C18 and C8 columns were used to quantitate cannabinoids; one based on acetonitrile, and another based on methanol as an organic modifier. The Rapid Gradient Acetonitrile Method is faster. On the other hand, the Methanol Method is more cost-efficient per injection compared to the acetonitrile method. A cannabinoid potency determination for hemp buds on a dry sample weight basis was achieved by determining the moisture content with the Karl Fischer (coulometry) titration method. A UV absorption spectra analysis to avoid misidentification or to minimize the effects of co-eluting impurities was also discussed.
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