Minor, Nonterpenoid Volatile Compounds Drive the Aroma Differences of Exotic Cannabis

Sensory Analysis of cannabis Rosin Extracts

The aroma properties of each sample were determined by a sensory panel (see Methods). The tabulated results revealed a wide diversity of aroma characteristics that can be found in Tables S5–S9. The descriptors obtained were also refined and grouped into three classifications: sweet exotic, prototypical, and savory exotic (Table S3). This methodology allows for more general classifications that help establish trends between varieties. Each panelist recorded an exotic score, which we defined as a metric that quantifies the overall sweetness or fruitiness of a given variety, ranging from 0 (not sweet or fruity) to 100 (very sweet or fruity). Figure​Figure33 illustrates the wide spectrum of different aromas that cannabis produces as defined by our sensory panel, with more prototypical aroma descriptors shown toward the middle and more exotic descriptors on the extreme ends. Shown below the aroma spectrum are the densities of reported aroma descriptors (i.e., the total number of instances a descriptor was assigned by the sensory panel) for the top-four and bottom-four ranked varieties by exotic score. A clear difference in sweet and savory descriptor densities is observed, with the four highest-ranked varieties having a much greater density of sweet descriptors, while the lowest four ranked have greater savory descriptor density. These data confirm that the samples analyzed have a wide aromatic diversity that is partitioned as expected when compared with their exotic scores.

The results of the sensory analysis showed clear differences among many varieties. Figure​Figure44a shows the average exotic score of each variety as a function of rank (lowest ranking having the lowest exotic scores and vice versa), with the color of the markers indicating each variety’s highest concentration terpene. D-(+)-limonene-rich varieties are most common in the samples measured and correspond to seven of the highest and six of the lowest exotic scores. Figure​Figure44b shows the sum of the instances of each descriptor classification as a function of the exotic score rank. Pearson correlation coefficients revealed a strong positive correlation between the sweet-exotic descriptor sums and exotic score (r = 0.77), indicating these descriptors trend strongly with increasing exotic scores. On the other hand, descriptors classified as savory-exotic had a moderate negative correlation (r = −0.47), which agrees with lower exotic scores having less sweet or fruity-like descriptors. Lastly, the descriptors within the prototypical descriptor classification showed less correlation (r = −0.39) than the other two. Many of these descriptors are highly representative of the terpene aroma characteristics commonly found in cannabis. For instance, ß-caryophyllene possesses a spicy, peppery aroma whereas D-(+)-limonene is orange and citrus. The descriptor gas, short for gasoline, in the context of cannabis refers to the pungent scent of fresh cannabis that is often synonymous with skunky. This aroma is derived primarily from prenylated VSCs.³² This descriptor was present in the sensory analysis of each sample except Trainwreck, indicating its pervasiveness across the samples measured. We note that the lack of the descriptor gas for Trainwreck, which is terpinolene-rich, is not unexpected as high terpinolene varieties have previously been shown to have lower concentrations of prenylated VSCs (or a complete lack thereof) than other dominant terpenes.³² As both terpenes and prenylated VSCs were identified in all varieties, the low correlation of the prototypical aromas they produce with the exotic score is not unexpected and suggests that they minimally contribute to the exotic notes in certain cannabis varieties.

Figure 4

(a) Exotic scores for each variety are ranked from the highest to the lowest. Marker colors indicate the dominant terpene in each sample. (b) Correlation between aroma classifications shows sweet exotic descriptors correlating positively with increasing exotic score, savory exotic descriptors decreasing with exotic score, and minimal negative correlation between descriptors classified as prototypical and exotic score. (c) Correlation table showing similarities and dissimilarities between sensory descriptors used for each variety.

To understand the similarity of aromas based on sensory data, we calculated the Pearson correlation coefficients of the aroma descriptors for each variety, as shown in the correlation matrix in Figure​Figure44c. This table allows for the inspection of the pairwise relationships between the sensory data of the 31 varieties, with higher values (lighter colors) indicating more similar aromas and lower values (darker colors) indicating less similar aromas (Table with coefficients shown can be found in Figure S1). As the varieties were ordered by the exotic score, greater similarities are expected for those higher on the y-axis than the lower. Indeed, lower-scoring varieties such as GMO, GMO Cookies, and 710 Chem have less correlation than those scoring higher. Concomitantly, for those ranked lowest, we see more similarities, indicating more similar aromas between those samples. These data provide us with the framework to relate the chemical composition of each variety to their aromatic properties.

Chemistry of cannabis Beyond Terpenes

To understand the chemical origins of the sensory analysis, we conducted two-dimensional gas chromatography coupled with mass spectrometry and flame ionization detection (GC × GC–TOF–MS/FID) to determine the volatile fingerprints of each sample. Our analysis found key compounds that contribute toward either sweet-exotic or savory-exotic descriptors as listed above. While a few compounds are omnipresent and found in all varieties, indicating less influence with respect to the unique aromas, many are only found in certain ones. Here, we describe specific classes of unique compounds that have rarely been described previously and their aromatic properties that help generate the diverse aroma of cannabis (Figure​Figure55).

Tropical Volatile Sulfur Compounds (VSCs)

Cannabis produces a family of prenylated volatile sulfur compounds that generate its skunky, gas-like aroma.^32,33 Each of these compounds possesses strong, pungent, sulfuric aromas, with alliaceous notes produced by diprenyl disulfide and diprenyl sulfide and skunk-like notes by prenylthiol, prenylthioacetate, and prenylmethyl sulfide. We discovered that there exists another unique class of VSCs that produce tropical nuances–sulfur containing compounds that produce more citrus, fruity, sulfuric aromas–that includes 3-mercaptohexanol (3MH), 3-mercaptohexyl acetate (3MHA), and 3-mercaptohexyl butyrate (3MHB) (Figure​Figure55). These compounds have extremely potent aromas, comparable in strength to prenylthiol and prenylthioacetate. All three are found in a multitude of tropical fruits such as passionfruit and grapefruit.³⁹ 3MH and 3MHA are also found in certain grapes and hops, which can translate to their presence in both wine and beer.⁴⁰⁻⁴³

We found that cannabis varieties containing these compounds take on a very strong, petroleum- or sulfuric citrus-like aroma, such as Garlic Cocktail #7 and Gorilla Glue. The importance of these compounds in dictating the perceived aroma is exemplified by these two varieties. Sensory analysis revealed similar aroma characteristics for these two varieties (r = 0.85), with citrus and tangerine descriptors used often by the panel. We note that Gorilla Glue has not traditionally been associated with this scent and rather should have a pungent, sulfuric, and spicy aroma. This suggests that the sample procured was labeled incorrectly and most likely is a different variety based on the presence of these compounds and resulting sensory analysis.

Indole Derivatives

Another key class of compounds that we identified was the heterocyclic compounds indole (1H-indole) and skatole (3-methyl-1H-indole). While previously detected in the smoke residue of cannabis, they have not been reported in cannabis inflorescence or extracts.⁴⁴ Indole, the core structure of many biologically important compounds, including tryptophan and melatonin, was identified in many varieties. Although in low concentrations, its ubiquity across samples suggests that this compound most likely contributes to the general, prototypical aroma of cannabis, rather than influencing specific exotic scents. It possesses a floral, mothball-like scent characteristic of many indole-derived compounds.

While indole is common across the samples measured, skatole trends strongly with savory exotic varieties such as GMO, Garlic Cookies, and 710 chem. The aroma of this compound is complex and changes drastically at different concentrations and in the presence of other aroma compounds. It is most well known as a key contributor to the odor of mammalian and bird feces, resulting from the decomposition of tryptophan in the digestive tract.⁴⁵ Nonetheless, it is also used in many fragrance-based applications, as well as can be found in certain food products.⁴⁶ As an isolated compound, it possesses a strong ammoniacal scent, reminiscent of mothballs. This aroma persists in cannabis, as the majority of varieties that had skatole present also had strong savory sensory descriptions. We also note that the two high-ranked varieties Fruity Pebbles and Garlic Cocktail #7 contained skatole (71.4 and 80.1 exotic scores, respectively). The former had sensory notes of chemicals, suggesting that although it may have a sweet scent derived from other flavorants, skatole can still be detectable. The latter had a significant amount of tropical VSCs that dominated the sensory results of this variety, indicating that these compounds can mask the characteristic scent of skatole.

Many of the varieties containing skatole that were described as savory or chemical also have key esters that generate fruity or sweet aromas. This suggests that the aroma potency of skatole, referred to as substantivity or tenaciousness in the perfuming industry, may overpower the aroma produced by esters but not necessarily the potent VSCs, as is the case with Garlic Cocktail #7. Thus, how skatole modulates the overall aroma of a given variety is dependent on the other compounds present and their pungency.

Senecioates: Ubiquitous Esters in Exotic cannabis

One observation we made during cataloging of flavorants was the presence of a family of compounds containing the 3-methyl-2-butenoate (senecioate) group. This is congruent with another recent report of ethyl senecioate in cannabis and its possible link to certain varieties.⁴⁷ The senecioate functional group can be considered an oxidized prenyl group, wherein the C1-positioned carbon contains a carboxyl group. As was noted previously,⁴⁷ this functional group is similar to that of recently discovered prenylated VSCs,³² further showing that cannabis has a propensity to generate secondary metabolites related to this key functional group.

The isopropyl, n-propyl, n-butyl, isoamyl, and n-hexyl analogues were not available commercially and were thus synthesized following a known procedure (see methods). Sensory analysis revealed that each possesses a similar, fruity fusel base note with different nuances. For instance, the isopropyl and n-propyl senecioates were found to be fusel and sweet, whereas the n-butyl and isoamyl senecioates contained notes of banana. The n-hexyl analogue was found to have a green apple top note, which correlates with other compounds containing hexyl chains, such as hexyl acetate. These compounds are found in many varieties ranked highly by their exotic score, such as Starburst 36 #1 and Motornana, with ethyl and isopropyl senecioate typically found in the highest concentrations.

Esters: Flavor of Fruits

Esters are found in nearly every fruit and other plants and contribute strongly to their aromas, flavors, and appeal.³⁹ Likewise, we identified more than 30 esters in cannabis alone. While not traditionally known for sweet or fruity aromas, our sensory panel results show certain varieties can indeed possess a wide range of sweet- or fruit-related aromas. Our data show that cannabis produces a wide range of esters with different aromatic characteristics, even within a single variety. For instance, Banana Scream has over 15 different esters present that we detected, each with different aroma descriptors ranging from fruity, pineapple, or banana. Two compounds of note include ethyl hexanoate and n-propyl hexanoate: The former possesses a fruity, apple-like aroma, and the latter possesses a blackberry, pineapple scent. The concentrations of these compounds correlate with an increasing exotic score, indicating their importance toward producing more sweet or fruity aromas.

On the other hand, n-hexyl n-butyrate and n-hexyl hexanoate were found in all samples, both of which are described in the literature as having green and fruity notes. As these compounds are found in each variety and often in higher concentration than other flavorants, they most likely have less influence on the unique aromatic properties of each specific variety. Interestingly, Gorilla Glue has a significantly higher concentration of n-hexyl n-butyrate than other varieties yet was only modestly ranked by the exotic score (65.1). This further suggests that this compound minimally influences the exotic aroma of cannabis.

Structurally Unique Compounds

Compounds with even more diverse functionalities were identified during our analysis. The compounds methyl, dimethyl, and ethyl anthranilate were detected in many varieties, with the latter two found in more sweet exotic varieties. While methyl anthranilate has been detected in cannabis previously,¹⁸ the dimethyl and ethyl analogues have not. These compounds each produce slightly different grapelike aromas, with methyl anthranilate possessing a strong concord grapelike scent and flavor. It is commonly used as a flavorant in different food and beverage products and is found naturally in many plants and fruits.⁴⁸

Another set of related compounds with unique structural features is phenethyl n-butyrate, isobutyrate, and n-propanoate. These compounds were only identified in a select few high exotic score varieties, including Papaya Peach and Juiceman. These compounds possess mild, sweet, honeylike aromas. The few varieties these compounds were identified in are more recently bred, which may suggest that this class of compounds is only expressed in more modern varieties. As such, they may present a unique chemical fingerprint for identifying genetic divergence in these varieties.

We last highlight 6-amyl-α-pyrone, a lactone with a creamy, coconut aroma. This compound was identified only in high exotic score varieties, indicating its possible implication in these aromas detected by the sensory panel. It has been detected in peaches and is produced by Trichoderma, a fungus commonly found in soil.⁴⁹

Importance of Terpenes and Flavorants in Exotic cannabis

To understand the chemical relationships between varieties, we calculated Pearson correlation coefficients between their volatile chemical fingerprints, as shown in the correlation matrices in Figure​Figure66. These data provide a convenient way to compare the similarity between each variety on a chemical level, where a higher correlation indicates more similar chemical profiles. We did this by measuring the correlation of all analytes in each data set and decomposed into key compound classes, namely, monoterpenes and monoterpenoids, sesquiterpenes and sesquiterpenoids, and flavorants.

Figure 6

(a) Correlation matrix considering all analytes showing no trend between the exotic score and the chemical similarities of varieties. (b) Correlation table of monoterpenes and monoterpenoids. (c) Correlation table of sesquiterpenes and sesquiterpenoids. (d) Correlation table of flavorants. These data reveal that flavorants show divergent chemical compositions that other classes do not.

The resulting correlation matrix measuring all analytes (Figure​Figure66a) is remarkably similar to the monoterpene and monoterpenoids matrix (Figure​Figure66b). Sesquiterpene and sesquiterpenoid correlations are even stronger among all samples (Figure​Figure66c). These data show that there are minimal differences between varieties in these two key classes, even when the aromatic properties are widely divergent. Conversely, the flavorant correlation between varieties is widely disparate (Figure​Figure66d).

These results reveal a few important features. First, monoterpenes and monoterpenoids, which are often found in high concentrations, have strong chemical similarities between varieties despite their widely divergent aromas, suggesting that they are not the origin of the unique scents assigned to each variety. For example, GMO and Grape Pie × Do-Si-Do have the lowest and highest exotic scores, respectively, yet have a similar monoterpene and monoterpenoid profile (r = 0.91). This high chemical similarity but minimal aroma similarity suggest that these compounds do not contribute strongly to the aroma differences of these varieties. Sesquiterpenes and sesquiterpenoids appear even more similar across varieties, with the lowest Pearson coefficient of r = 0.86 found between samples.

Conversely, flavorants have wide ranging correlations depending on the varieties measured. This is especially evident when n-hexyl hexanoate is omitted due to its high concentration across all samples. The correlation coefficients range from near unity positively, as is the case for Papaya Peach and Juice Man (r = 0.99), to minimally correlated, such as between OG and Bacio Gelato (r = −0.16). The average flavorant correlation between samples was only r = 0.37, whereas monoterpene/monoterpenoid and sesquiterpene/sesquiterpenoid correlations were r = 0.65 and r = 0.84, respectively. The weak flavorant relationships between many of these varieties suggest that the aromatic differences perceived during sensory analysis may arise from this class of compounds rather than the dominant terpene classes.

Analytical Standards

Several different reference materials were acquired for the purpose of compound quantitation and confirmation. A 35-compound terpene analytical standard (LGC Standards) was used to quantify the major components in the samples. A custom 17 compound flavorant standard (FLV-1) was supplied from LGC Standards prepared in triacetin that was further diluted in ethanol. Multiple custom flavorant standards were then created in-house using analytical grade standards when available. Standards were purchased from different sources, including Sigma-Aldrich, Vigon International, and Penta International. Prenylthiol (Penta International, 95% in 1% triacetin) was prepared in ethanol. 3-Mercaptohexanol, 3-mercaptohexyl acetate, and 3-mercaptohexyl butyrate (Excellentia, >97%) were prepared in hexanes. Senecioates were synthesized in-house (>97%) and prepared in hexanes. Table S1 shows the complete list of standards used and their calibration statistics. Five or 6-point Calibration curves were used to quantify the compounds. Figures S15–S70 show mass spectra of flavorant analytes in select varieties along with NIST v17 mass spectral database data. Additionally, each analyte reported was structurally validated by confirming similar elution times and mass spectra of standards.

Synthesis of Senecioates

In each esterification, 3-methyl-2-butenoic acid (1 equiv) was dissolved in dichloromethane at room temperature. 4-Dimethylaminopyridine (0.085 equiv) and 4 equiv of a respective alcohol (n-propanol, isopropanol, n-butanol, isoamyl alcohol, or n-hexanol) were then added. The reaction solution was cooled in an ice bath before adding N, N′-dicyclohexylcarbodiimide (1.2 equiv). This addition of the coupling reagent led to a precipitate forming as the reaction progressed. After 24 h, the reaction mixture was filtered and the organic layer was washed with aqueous 0.5 N HCl, saturated sodium bicarbonate, and dried over magnesium sulfate. The organic layer was filtered and concentrated. The crude material was purified by column chromatography using silica gel and eluted with a mixture of 90:10 hexane–diethyl ether. After the purified material was dried under high-vacuum pressure, the senecioates were analyzed by GC, FTIR, ¹H NMR, and ¹³C NMR spectroscopy. Each of the FTIR traces indicated an ester formed by the carbonyl stretch at ∼1700 cm^–1. The ester resonance was also confirmed in the ¹³C NMR spectrum of each target compound at ∼166 ppm. Lastly, the aliphatic chains of the respective alcohols in the esterification coupling were easily identified in both the ¹H and ¹³C spectra. Complete experimental conditions and spectral data can be found in the Supporting Information.

Comprehensive Two-Dimensional Gas Chromatography

GC × GC analysis was performed using the INSIGHT reverse fill flush flow modulator (SepSolve Analytical). This was coupled for data generation to an Agilent 7890B GC equipped with a BPX5 (20 m × 0.18 mm ID × 0.18 μm film thickness) first dimension column and Mega Wax (4.8 m × 0.32 mm ID × 0.15 μm film thickness) second dimension column and BenchTOF Select Time of flight mass spectrometer (Markes International). Time-of-flight mass spectrometry (TOF-MS) was used to identify compounds. Quantification of compounds was performed using a flame ionization detector (FID). Sample introduction was done using direct injection with an Agilent 7693 Injector Tower (G4513A). The needle was washed 3 times with isopropanol and hexanes before and after injection. The injection volume used was 5 μL. The inlet split flow and temperature were 20:1 and 280 °C, respectively. The TOF-MS detector source was held at 280 °C and a transfer line temperature of 260 °C. A solvent delay of 6 min was used and had an acquisition rate of 60 Hz.

The GC × GC column configuration was an apolar to polar setup. The GC oven ramp rates used were as follows: The oven was initially set to 45 °C and held for 3 min. The oven was then ramped at a rate of 3 °C per minute to 98 °C, followed by a 6 °C per minute ramp rate to 140 °C, followed by a 8.5 °C per minute ramp rate to 170 °C followed by a 2 °C per minute ramp rate to 190 °C, followed last by a 15 °C per minute ramp to 260 °C and held for 13 min to remove any remaining compounds from the column. The modulation period set for the flow modulator was 6.0 s. Data were collected, integrated, and analyzed using the ChromSpace software platform (Sepsolve Analytical). Statistical analysis and data transformations were performed using Terplytics. Figures S6–S13 showing GC × GC–FID chromatograms have been realigned to account for void time (2.5 s) in the second dimension. Analyte concentrations can be found in Tables S10–S14. Relative amounts of the volatile fraction for each analyte can be found in Tables S15–S19. Correlation matrices for sensory analysis and chemical analysis with Pearson correlation coefficients can be found in Figures S1–S5.

We thank Abstrax Tech Inc. for financial support.