New Insights into the Chemical Composition of Ayahuasca

Seven ayahuasca samples were donated by ritual participants in Uruguay and labelled by the donor group: Religious (R1–R3), Therapeutic (T1–T2), and Neoshamanic (N1–N2). Samples and reagents included authentic standards of several β-carbolines and synthesised references for tetrahydroharmine and DMT; full synthesis procedures are described for those standards. For solids analysis, 10 mL of each sample was centrifuged (2000 rpm, 20 min), solids were washed with water, dried (vacuum, 40 °C), and ~20 mg dissolved in DMSO-d6 for NMR. Non-alkaloid soluble components were analysed by diluting 1 mL of sample 50-fold with water containing 10% D2O after centrifugation (4500 rpm, 5 min). For alkaloid profiling, aliquots (2.5 mL) of homogenised ayahuasca were basified to pH ~12 with NH4OH and extracted five times with ethyl acetate; combined organic layers were dried and evaporated to give crude extracts for TLC, NMR, and LC–MS/MS analysis. After extraction, a check quantified the fraction of harmine removed from the aqueous solids. NMR experiments (1H, 13C and 2D) were recorded on Bruker instruments at 25 °C. qNMR quantification used the PULCON (PUlse Length-based CONcentration determination) method. For non-alkaloid components, ethyl benzoate in CDCl3 (8.16 mM) served as calibration standard with water suppression, 128 scans, 4 s relaxation delay and a 90° pulse of 9.75 μs; selected anomeric proton signals of sugars were used for quantification. For alkaloid quantification, 86 mM benzoic acid in DMSO-d6 was used as external standard; spectra were recorded with 16 scans, 40–60 s relaxation delays and a 90° pulse of 13 μs. The method validation assessed selectivity/specificity, linearity, accuracy, limits of detection and quantification, precision, and stability; detailed validation results are reported in the Supporting Information. TLC of extracts used silica gel plates with standard visualisation reagents. LC–MS/MS analyses were performed on a Shimadzu LCMS 8040 with a Phenomenex Kinetex EVO C18 column (100 × 4.6 mm, 5 μm), a formic acid/methanol gradient, UV detection and positive-ion full-scan MS over m/z 100–600; MS/MS collision energies were varied between 10 and 35 eV to detect trace alkaloids.

Sample set and treatment: Seven samples were analysed initially, but one Therapeutic sample (T2) yielded no detectable alkaloids on initial TLC and was excluded from further alkaloid quantification. Samples from different ritual settings showed broadly similar chemical profiles in 1H NMR spectra. Non-alkaloid soluble components and solids: 1H NMR of diluted whole samples showed that fructose was the major soluble component in the beverages studied, corroborated by comparison with an authentic fructose spectrum. Glucose was present as a minor component (anomeric protons at 5.22 and 4.63 ppm). Ethanol, lactate and acetate signals were also observed, consistent with possible fermentation products. Using PULCON qNMR, concentrations (expressed as grams per 50 mL of ayahuasca) for fructose across six samples ranged from 3.07 to 33.67 g/50 mL, with marked variability between samples; T1 and R1 showed particularly high fructose content. The authors note that such sugar levels could contribute to gastrointestinal effects reported after ingestion and raise considerations for individuals with hereditary fructose intolerance or fructose malabsorption. Analysis of insoluble material (centrifuged solids) dissolved in DMSO-d6 and examined by 1H NMR revealed that harmine is present in the suspended solids. All tested solids from R1–R3 and N2 contained harmine in varying relative amounts, suggesting that part of harmine remains undissolved and may be lost if solids are removed before analysis. Alkaloid profiling and quantification: Liquid–liquid extraction (basified, five extractions with ethyl acetate) of the whole samples produced crude extracts analysed by TLC, NMR and LC–MS/MS. Major alkaloids identified by NMR across analyzed extracts were DMT, harmine, tetrahydroharmine, harmaline and harmol; trace amounts of bufotenine (5‑hydroxy‑DMT), N‑methyltryptamine, tetrahydronorharmine and harmalol were detected in some samples by LC–MS/MS. No appreciable amounts of non‑tryptamine or non‑β‑carboline adulterants (e.g. moclobemide) were detected in these samples. Quantitative qNMR results for the six analysed samples (three extractions per sample) are reported as mg of alkaloid per gram of ayahuasca (mean and range): DMT 1.13 mg/g (0.532–1.86); harmine 2.83 mg/g (1.34–5.61); tetrahydroharmine 1.48 mg/g (1.03–2.33); harmaline 0.221 mg/g (0.118–0.452); harmol 0.106 mg/g (0.044–0.290). Relative variability (percentual relative standard deviation, RSD) reflects the whole extraction and measurement method. Compared with prior reports, the absolute ranges lie within previously described values, but some samples (therapeutic and neoshamanic) displayed unusually high harmine:tetrahydroharmine ratios (~1.9–3.0). Religious samples had comparable harmine and tetrahydroharmine amounts but higher DMT, yielding lower β‑carbolines:DMT ratios (approximately 1.8–2.7) than therapeutic/neoshamanic samples (approximately 4.8–7.9). A check of the extraction efficiency showed that ethyl acetate extraction removed about 96% of harmine originally present in the solids, indicating the extraction protocol accounts for solid‑associated harmine.

Rodríguez and colleagues interpret their findings as providing new chemical insights into whole ayahuasca samples by demonstrating that substantial quantities of non-alkaloid carbohydrates — chiefly fructose — and suspended solids containing harmine are present and may influence both subjective effects and analytical estimates. The detection of fructose as a major component is novel for ayahuasca studies; the authors suggest sugars originate from glycosides and fructofuranosyl compounds in the botanical ingredients and are liberated by intensive boiling. They further propose that high fructose concentrations could plausibly contribute to gastrointestinal symptoms commonly reported after ingestion (vomiting, nausea, diarrhoea) via osmotic effects or unabsorbed fructose in individuals with fructose malabsorption, in addition to established pharmacological mechanisms involving β‑carbolines and serotonin. Regarding β‑carbolines, the presence of harmine in undissolved solids offers an explanation for variability in reported harmine:tetrahydroharmine ratios: rather than chemical reduction of harmine during decoction, the authors argue that sedimentation or filtration of insoluble harmine leads to its relative loss from the liquid fraction typically analysed. The finding that ethyl acetate extraction recovers most solid-associated harmine supports this interpretation. Differences in alkaloid ratios and β‑carbolines:DMT proportions across samples are attributed to variable plant species and preparation practices in different ritual contexts. The study also reports that the analysed samples did not contain previously reported adulterants such as moclobemide, and that trace alkaloids (e.g. bufotenine) may indicate use of alternative DMT source plants in some preparations. Finally, the validated qNMR PULCON method is presented as a novel, rapid, and non‑destructive approach for simultaneous quantification of the main ayahuasca alkaloids; validation covered standard performance characteristics, with further experimental detail in the Supporting Information. The authors acknowledge variability across samples and note that some methodological specifics and extended validation data are provided in supplementary material. They frame their results as relevant for analytical practice (avoiding underestimation of harmine when solids are removed) and for understanding potential contributors to ayahuasca's effects, while situating findings within the known heterogeneity of traditional preparations.