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NEUROPHARMACOLOGY
Àrea d'Investigació Farmacològica, Institut de Recerca, Hospital de la Santa Creu i Sant Pau; and Departament de Farmacologia i Terapèutica, Universitat Autònoma de Barcelona, Barcelona, Spain
Received February 3, 2003; accepted March 13, 2003.
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Abstract |
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-carboline
alkaloids (harmine, harmaline, and tetrahydroharmine). Eighteen volunteers
with prior experience in the use of psychedelics received single oral doses of
encapsulated freeze-dried ayahuasca (0.6 and 0.85 mg of DMT/kg of body weight)
and placebo. Ayahuasca produced significant subjective effects, peaking
between 1.5 and 2 h, involving perceptual modifications and increases in
ratings of positive mood and activation. Diastolic blood pressure showed a
significant increase at the high dose (9 mm Hg at 75 min), whereas systolic
blood pressure and heart rate were moderately and nonsignificantly increased.
Cmax values for DMT after the low and high ayahuasca doses
were 12.14 ng/ml and 17.44 ng/ml, respectively. Tmax
(median) was observed at 1.5 h after both doses. The Tmax
for DMT coincided with the peak of subjective effects. Drug administration
increased urinary normetanephrine excretion, but, contrary to the typical
MAO-inhibitor effect profile, deaminated monoamine metabolite levels were not
decreased. This and the negligible harmine plasma levels found suggest a
predominantly peripheral (gastrointestinal and liver) site of action for
harmine. MAO inhibition at this level would suffice to prevent first-pass
metabolism of DMT and allow its access to systemic circulation and the central
nervous system.
;
Dobkin de Rios, 1984). This
ancient pattern of use has given way to a more widespread and frequent
consumption by members of a number of modern Brazilian-based syncretic
religious groups, mainly the Santo Daime and the Uniao do Vegetal, which have
incorporated the use of the beverage in their rituals
(Dobkin de Rios, 1996). In
recent years, groups of followers of these Brazilian religions have become
established in the United States and in several European countries, including
Germany, Great Britain, Holland, France, and Spain
(Anonymous, 2000). As a larger
number of people have come into contact with ayahuasca, the tea has begun to
attract the attention of biomedical researchers
(Callaway et al., 1999;
Riba et al., 2001b).
Ayahuasca is obtained by infusing the pounded stems of the malpighiaceous
vine Banisteriopsis caapi either alone or, more frequently, in
combination with the leaves of Psychotria viridis (rubiaceae) in
Brazil, Peru, and Ecuador or Diplopterys cabrerana (malpighiaceae),
used mainly in Ecuador and Colombia
(Schultes and Hofmann, 1980;
McKenna et al., 1984). P.
viridis and D. cabrerana are rich in the psychedelic indole
N,N-dimethyltryptamine (DMT;
Rivier and Lindgren, 1972;
Schultes and Hofmann, 1980),
whereas B. caapi contains substantial amounts of -carboline
alkaloids, mainly harmine and tetrahydroharmine (THH), and to a lesser extent
harmaline and traces of harmol and harmalol
(Rivier and Lindgren, 1972;
McKenna et al., 1984).
DMT is structurally related to the neurotransmitter serotonin and, like
better-characterized psychedelics such as LSD and mescaline, binds to
5-hydroxytryptamine 2A receptors in the central nervous system
(CNS), where it acts as an agonist (Pierce
and Peroutka, 1989; Smith et
al., 1998). Studies in humans have shown that when administered
parenterally, DMT provokes dramatic modifications in perception, the sense of
self and reality that can be very intense but relatively short in duration
(Strassman et al., 1994). The
drug also exerts marked autonomic effects elevating blood pressure, heart
rate, and rectal temperature, and causes mydriasis
(Strassman and Qualls, 1994).
Unlike the vast majority of known psychedelic phenethylamines, tryptamines,
and ergolines, DMT is orally inactive
(Ott, 1999), apparently due to
metabolism by monoamine oxidase (MAO;
Suzuki et al., 1981).
Interestingly, harmine and harmaline, and, to a lesser extent, THH, are potent
MAO inhibitors (Buckholtz and Boggan,
1977; McKenna et al.,
1984). In 1968, Agurell and coworkers (cited in
Ott, 1999, p. 172) postulated
that the interaction between -carbolines and DMT in ayahuasca
"might result in specific pharmacological effects". It is now a
widely accepted hypothesis that following ayahuasca ingestion, MAO inhibition
brought about by harmine, given that it is more potent than THH and is present
in the tea in larger amounts than harmaline
(McKenna et al., 1984),
prevents the enzymatic degradation of DMT, allowing its absorption. It has
also been speculated that -carbolines may contribute to the overall
central effects of ayahuasca by blocking brain MAO and weakly inhibiting
serotonin reuptake, which combined would lead to enhanced neurotransmitter
levels and modulate the effects of DMT
(Callaway et al., 1999).
In the present paper we report a double-blind placebo-controlled crossover
clinical trial conducted with ayahuasca, in which subjective and
cardiovascular effects, and alkaloid pharmacokinetics were assessed in a group
of healthy volunteers experienced in psychedelic drug use. Additionally, urine
monoamine metabolites were studied to measure in vivo the MAO-inhibitory
effects of ayahuasca. In this respect, the neurotransmitters norepinephrine,
epinephrine, and dopamine are physiologically degraded by MAO and
catechol-O-methyltransferase (COMT) to produce deaminated and
methylated metabolites, respectively. Serotonin, on the other hand, is
exclusively metabolized by MAO to produce a deaminated compound. In vivo and
in vitro studies have shown that when MAO is pharmacologically inhibited, the
levels of MAO-dependent deaminated metabolites decrease and those of
COMT-dependent methylated metabolites increase. In humans, MAO inhibitors
decrease, after acute administration, the urinary excretion of
vanillylmandelic acid (VMA), homovanillic acid (HVA), and
5-hydroxyindoleacetic acid (5-HIAA), the deaminated metabolites of
norepinephrine/epinephrine, dopamine, and serotonin, respectively, while
increasing that of metanephrine and normetanephrine, the methylated
metabolites of epinephrine and norepinephrine, respectively
(Pletscher, 1966;
Koulu et al., 1989). Monoamine
metabolites have both a CNS and a non-CNS origin, and their assessment in
urine does not give information regarding the organ in which MAO was
inhibited. Nevertheless, this approach can identify dose-response
relationships after drug administration and allows for the study of the time
course of MAO inhibition.
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Materials and Methods |
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). Exclusion criteria included current or previous history of
psychiatric disorder and/or family history of Axis-I psychiatric disorder in
first degree relatives, alcohol or other substance dependence, and high scores
on trait anxiety (over 1 standard deviation above normative mean).
Participants had a mean age of 25.7 years (range 19–38), mean weight
66.47 kg (range 50.7–79.5), and mean height 175.11 cm (range
158–188). The study was conducted in accordance with the Declarations of
Helsinki and Tokyo concerning experimentation on humans, and was approved by
the hospital's ethics committee and the Spanish Ministry of Health. The
volunteers received detailed information on the nature of ayahuasca, and the
general psychological effects of psychedelics and their possible adverse
effects, as reported in the psychiatric literature. All volunteers gave their
written informed consent to participate.
Drug
To administer ayahuasca in accurate dosings and masked in a double-blind,
double-dummy design, a 9.6-liter batch of Brazilian Daime was subjected to a
freeze-drying process that yielded 611 g of powder, which was subsequently
homogenized and analyzed. The DMT content was determined by HPLC, as described
by Callaway et al. (1996), and
the -carbolines were determined according to a modified version of the
method described therein. One gram of freeze-dried material contained 8.33 mg
of DMT, 14.13 mg of harmine, 0.96 mg of harmaline, and 11.36 mg of THH, which
corresponded to the following alkaloid concentrations in the original tea:
DMT, 0.53 mg/ml; harmine, 0.90 mg/ml; harmaline, 0.06 mg/ml; and THH, 0.72
mg/ml. The ayahuasca doses administered to the volunteers in the present study
were chosen based on tolerability and subjective effect data gathered in a
previous study (Riba et al.,
2001b). The low and the high dose contained, per kilogram of body
weight: 0.6/0.85 mg of DMT, 1.0/1.4 mg of harmine, 0.07/0.09 mg of harmaline,
and 0.82/1.16 mg of THH. The average (range) alkaloid content in milligrams
administered in each dose (low dose/high dose) was: 39.8
(30.4–47.9)/57.4 (43.7–67.7) for DMT, 67.4 (51.6–81.2)/95.8
(74.2–114.8) for harmine, 4.6 (3.5–5.5)/6.5 (5.0–7.8) for
harmaline, and 54.2 (41.5–65.3)/77.0 (59.6–92.3) for THH. The
calculated individual dose for each volunteer was administered by combining 00
gelatin capsules containing different amounts of freeze-dried ayahuasca, i.e.,
0.5 g, 0.25 g, or 0.125 g, and placebo capsules containing 0.75 g of lactose.
Placebo capsules were added when necessary, so that all volunteers took the
same number of capsules on each experimental day. It is interesting to note
that although the amount of DMT administered with the present low dose was
similar to that administered in the only other published study on the human
pharmacology of ayahuasca (Callaway et al.,
1999), the amounts of -carbolines administered in this work
were much lower. This was due to the different alkaloid proportions present in
the tea samples used in each study. Thus, the average amounts (range) in
milligrams administered by Callaway et al.
(1999) were: 35.5
(28.8–43.2) for DMT, 252.3 (204.0–306.0) for harmine, 29.7
(24.0–36.0) for harmaline, and 158.8 (128.4–196.6) for THH.
Study Design
Each volunteer participated in four experimental sessions at least 1 week
apart. Volunteers were informed that on each experimental day they would
randomly receive a single oral dose of encapsulated freeze-dried ayahuasca
(one low and one high dose), a placebo, and a random repetition of one of the
three mentioned treatments. In actual fact, they all received a placebo on the
first experimental day in a single-blind fashion, followed by one of the three
treatments from days 2 to 4 in a double-blind balanced fashion, according to a
randomization table. The first nonrandomized placebo was administered to
familiarize the volunteers with the experimental setting and to minimize the
stress associated with the experimental interventions. Volunteers were
requested to abstain from any medication or illicit drug use 2 weeks before
the beginning of the experimental sessions until the completion of the study.
Volunteers also abstained from alcohol, tobacco, and caffeinated drinks 24 h
before each experimental day. Urinalysis for illicit drug use was performed
for each experimental session. The volunteers were admitted to the research
unit on four separate experimental days. Upon arrival at 8:00 AM under fasting
conditions, a cannula was inserted in the cubital vein of their right arm for
drawing blood samples, and capsules were administered at approximately 10:00
AM with 250 ml of tap water. Throughout the experimental session, the
volunteers remained seated in a comfortable reclining chair in a quiet, dimly
lit room. At 4 h after administration of the capsules, when the most prominent
subjective effects associated with the drug had disappeared, the volunteers
had a meal. The last experimental time point was at 8 h, and volunteers were
discharged approximately 9 h after administration.
Study Methods
Subjective Effect Measures. The subjective effects elicited by
ayahuasca were measured by means of visual analog scales (VAS) and self-report
questionnaires. VAS were 100-mm horizontal lines with the following labels:
"any effect," indicating any effect, either physical or
psychological, that the volunteer attributed to the administered drug;
"good effects," indicating any effect the volunteer valued as
good; "liking," reflecting that the volunteer liked the effects of
the administered substance; "drunken," indicating any dizziness or
lightheadedness; "stimulated," indicating any increases in thought
speed and/or content, or any increases in associations and/or insights;
"visions," indicating modifications in visual perception,
including any variations in object shape, brightness, or color and any
illusion, abstract or elaborate, seen with either eyes closed or open; and
"high," which reflected any positive psychological effect the
volunteer attributed to the drug. Except for the "visions" item,
the other VAS items administered had been used in human studies by other
researchers assessing the subjective effects of a variety of psychoactive
drugs (Farré et al.,
1993,
1998;
Camí et al., 2000). The
volunteers were requested to answer the VAS immediately before administration
(baseline) and at 15, 30, 45, 60, and 75 min, and 1.5, 2, 2.5, 3, 3.5, 4, 6,
and 8 h after administration.
Self-report questionnaires included the Hallucinogen Rating Scale (HRS) and
the Addiction Research Center Inventory (ARCI). The HRS
(Strassman et al., 1994)
measures psychedelic-induced subjective effects and includes six scales:
Somaesthesia, reflecting somatic effects; Affect, sensitive to emotional and
affective responses; Volition, indicating the volunteer's capacity to
willfully interact with his/her "self" and/or the environment;
Cognition, describing modifications in thought processes or content;
Perception, measuring visual, auditory, gustatory, and olfactory experiences;
and, finally, Intensity, which reflects the strength of the overall
experience. In the present study, a Spanish adaptation of the questionnaire
was used (Riba et al., 2001a).
The range of scores for all HRS scales is 0 to 4. The short version of the
ARCI (Martin et al., 1971)
consists of five scales or groups: MBG, morphine-benzedrine group, measuring
euphoria and positive mood; PCAG, pentobarbital-chlorpromazine-alcohol group,
measuring sedation; LSD, lysergic acid diethylamide scale, measuring
somatic-dysphoric effects; BG, the benzedrine group, measuring intellectual
energy and efficiency; and the A scale, an empirically derived scale measuring
amphetamine-like effects. Both the A and BG scales are sensitive to
psychostimulants. The range of scores is 0 to 16 for MBG, –4 to 11 for
PCAG, –4 to 10 for LSD, –4 to 9 for BG, and 0 to 11 for A. The
questionnaire had been translated into Spanish and validated by Lamas et al.
(1994). Volunteers answered
the ARCI immediately before drug administration and 4 h after drug intake,
whereas the HRS was only answered at 4 h postadministration.
Cardiovascular Measures. Systolic and diastolic blood pressure and heart rate were measured with the volunteer seated, immediately before administration (baseline), and at 15, 30, 45, 60, 75, 90, 120, 150, 180, 210, and 240 min after intake using a sphygmomanometer cuff (Dinamap; Critikon, Tampa, FL) placed around the volunteer's left arm. No measurements were made after 240 min, the time point when subjects had their meal and after which they were allowed to move and leave the room.
Urine Samples. Urine was collected in fractions of 0 to 8 h, 8 to 16
h, and 16 to 24 h in plastic containers with 3 ml of 6 N HCl and kept in the
refrigerator during the 0- to 24-h collection period. Volunteers took home the
two plastic containers corresponding to the 8- to 16-h and 16- to 24-h
periods. Volume of each fraction was recorded and pH was adjusted to 2 to 4
with 6 N HCl, and two 50-ml aliquots were frozen at –20°C and stored
at –80°C until analysis. The following monoamine metabolites, VMA,
HVA, 5-HIAA, metanephrine, and normetanephrine were quantified by means of
HPLC with coulometric detection following previously validated procedures
(Soldin and Hill, 1980;
Parker et al., 1986;
Gamache et al., 1993). The
limit of quantification was 3 mg/l for VMA, HVA, and 5-HIAA, 0.05 mg/l for
metanephrine, and 0.10 mg/l for normetanephrine.
Blood Samples. Blood samples (10-ml EDTA tubes) were drawn at
baseline, 30, 60, 90, 120, and 150 min, and 3, 4, 6, 8, and 24 h after
administration for analysis of DMT, harmine, harmaline, and THH concentrations
in plasma and those of the O-demethylated metabolites harmol and
harmalol. Samples were centrifuged at 2000 rpm for 10 min at 4°C and
plasma was immediately frozen at –20°C. The frozen plasma samples
were stored at –80°C until analysis. DMT was quantified by gas
chromatography with nitrogen-phosphorus detection and the -carbolines by
means of HPLC with fluorescence detection following previously reported
methods (Yritia et al., 2002).
The limit of quantification was 1.6 ng/ml for DMT, 0.5 ng/ml for harmine, 0.3
ng/ml for harmaline, 1.0 ng/ml for THH, and 0.3 ng/ml for harmol and harmalol.
The intraday and interday coefficients of variation were lower than 10.9% and
13.4%, respectively, for all determined compounds.
Pharmacokinetic Analysis
After quantification of the different compounds in plasma, the following
pharmacokinetic parameters were calculated using a noncompartmental approach
by means of WinNonlin software (version 3.0; Pharsight, Mountain View, CA):
maximum concentration (Cmax), time taken to reach the
maximum concentration (Tmax), and area under the
concentration-time curve from 0 to 8 h (AUC0–8h), calculated
by means of the trapezoidal rule. AUC was extrapolated to infinity
(AUC0-
) by addition of the residual area
calculated by the last plasma concentration/terminal elimination rate
constant. Terminal half-life
(t
z = ln
2/z) was obtained by linear regression analysis of the
terminal log-linear portion of the plasma-concentration curve. Clearance
(CL/F) was determined as dose/AUC0-. Apparent
volume of distribution (Vz/F) was calculated as
dose/(z · AUC0-). The
AUC0- normalized by dose
(AUC0-/D) was also calculated. All data are
expressed as mean ± S.D. except for Tmax, where
median and range are given.
Statistics
Prior to statistical analysis, ARCI scores were transformed to differences
from preadministration values, and the following parameters were calculated
for VAS items: peak effect (maximum absolute change from baseline values),
time taken to reach the maximum effect (tmax), and the 8-h
area under the curve (AUC0–8h) of effect versus time
calculated by the trapezoidal rule. For cardiovascular variables, peak effect
(maximum absolute change from baseline values) and the 4-h area under the
curve (AUC0–4h) of effect versus time were calculated. The
obtained parameters, transformed ARCI scores, and raw HRS scores were analyzed
by means of a one-way repeated measures ANOVA with drug (placebo, ayahuasca
low dose, ayahuasca high dose) as factor. When a significant effect was
observed, post hoc comparisons were performed using Tukey's multiple
comparisons test. The time course of subjective effects was explored using
repeated measures two-way ANOVAs with drug and time (13 time points) as
factors. When a drug by time interaction was significant, multiple comparisons
were performed at each time point by means of Tukey's test.
Monoamine metabolite levels in urine were analyzed by means of a one-way repeated measures ANOVA with drug (placebo, ayahuasca low dose, ayahuasca high dose) as factor. When a significant effect was observed, post hoc comparisons were performed using Tukey's test. The time course of effects was explored using repeated measures two-way ANOVAs with drug and time (three time points) as factors. Pharmacokinetic parameter comparisons between doses were performed by means of Student's t test, except for Tmax, which was compared by means of a nonparametric Wilcoxon test.
To explore possible differences in the time-to-peak of DMT plasma concentrations and time-to-peak of subjective effects (for each of the administered VAS), nonparametric Wilcoxon tests were performed comparing Tmax for DMT and tmax for each VAS. These tests were performed for data obtained after each of the two administered ayahuasca doses. In all tests performed, differences were considered statistically significant for p values lower than 0.05.
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Results |
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Scorings on all seven VAS items showed significant drug effects (peak values and AUC) and significant drug by time interactions. Initial effects appeared between 30 and 45 min, reflected as rises in the VAS any effect item, and were followed by a prominent increase at around 60 min, as indicated by steep rises in all seven VAS items. In general terms, the maximum scorings were observed between 90 and 120 min after drug administration. A gradual return to baseline levels followed thereafter and was complete at 360 min. Regarding effect magnitude, the largest scores were obtained for the VAS any effect, liking, and high, followed by VAS good effects, visions, and stimulated items. The least modified VAS after ayahuasca administration was the drunken item.
More qualitative information on the nature of the effects brought about by ayahuasca is provided in Table 2, which lists the most frequently reported positive responses to specific items of the HRS questionnaire.
Cardiovascular Effects.Mean values for systolic (SBP) and diastolic blood pressure (DBP) and heart rate (HR) over time are presented in Fig. 3, and results of the statistical analysis performed are shown in Table 1.
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Ayahuasca administration produced only moderate elevations of cardiovascular parameters. Statistically significant changes relative to placebo were only found for DBP, both for peak values and AUC. The largest difference in DBP between the low dose and placebo was 9 mm Hg and occurred at 75 min after dosing. Between the high dose and placebo, differences of 10 and 9 mm Hg were observed at 15 and 75 min, respectively. A maximal increase of 7 mm Hg from baseline values was observed at 60 min for the low dose. After the high dose, a maximal increase of 9 mm Hg was observed at 15 min. For SBP, the largest differences with placebo were observed at 75 min and corresponded to 4 and 6 mm Hg increases for the low and high dose, respectively. Similarly, the maximal increase in SBP relative to baseline values was observed at 75 min and corresponded to 6 and 8 mm Hg for the low and high dose, respectively. Finally, HR showed the largest differences with placebo at 60 min and corresponded to 5 and 4 beats/min increases for the low and the high ayahuasca doses, respectively. The maximal increase from baseline values observed for HR was 4 beats/min and occurred at 60 min after administration of both the low and high ayahuasca doses.
Only two volunteers showed SBP values equal to or above 140 mm Hg at any time point: volunteer 1 at 75 and 90 min (140 mm Hg) after receiving the low dose, and at 60 (146 mm Hg) and 75 min (140 mm Hg) after receiving the high dose; and volunteer 6 as early as 15 min after administration of the high ayahuasca dose (146 mm Hg). Two volunteers showed DBP above 90 mm Hg: volunteer 1 at 30 min (93 mm Hg) after the low dose, and at 15 min (96 mm Hg) after the high dose; and volunteer 15 at 120 and 150 min (95 and 92 mm Hg, respectively) after administration of the high dose. Regarding HR, volunteer 1 also showed values above 100 beats/min (101 beats/min) at 60 min after the high dose.
Urine Monoamine Metabolites. Urine samples were successfully collected for 15 of the 18 volunteers enrolled in the study, and results are given for this subgroup only. Statistical analyses showed a significant effect of drug only for normetanephrine. No significant drug by time interaction was found for any of the metabolites studied. In view of this, the total monoamine metabolite amounts excreted during the 0- to 24-h period after placebo and the two ayahuasca doses are presented in Table 3. As shown therein, rather than the expected decreases in deaminated metabolites (VMA, HVA, 5-HIAA), drug administration increased the excretion of these compounds nonsignificantly. Similarly, levels of the O-methylated metabolites metanephrine and normetanephrine increased with dose, although only the latter showed statistically significant differences with placebo.
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Pharmacokinetics. The time course of plasma concentrations and the calculated pharmacokinetic parameters for DMT, harmaline, THH, harmol, and harmalol are shown in Fig. 4 and Table 4. The graphs correspond to 15 of the total 18 participants enrolled in the study. To avoid the miscalculation of pharmacokinetic parameters, data from three volunteers were excluded from the analysis due to vomiting occurring after administration of the low dose (volunteer 6) and the high dose (volunteers 4 and 18). An additional subject (volunteer 12) was excluded from the calculation of harmalol parameters. Plasma levels for this volunteer after the high dose showed a plateau between 6 and 24 h, precluding parameter assessment.
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As shown in Table 4, Cmax and AUC values increased with dose for all measured compounds. DMT showed a Tmax of 1.5 h (median) after both the low and high doses. Nevertheless, the upper end of the range of Tmax values increased with dose, and the Wilcoxon test indicated a statistically significant difference between doses. A larger Tmax after the high ayahuasca dose is evident also in the DMT concentration-time curve included in Fig. 4. Both harmaline and THH plasma concentrations peaked later than DMT, and their Tmax values were larger after the high relative to the low ayahuasca dose. An unexpected finding was the absence of measurable harmine plasma levels except for a few time points in 4 of 18 volunteers, precluding the calculation of pharmacokinetic parameters for this alkaloid.
Interestingly, all volunteers showed measurable levels of harmol, the O-demethylated analog of harmine. Plasma concentrations showed dose-dependent increases and peaked at 1.5 and 2 h after the low and high doses, respectively. Harmalol, the O-demethylated analog of harmaline, could also be quantified. Maximum concentrations were attained later than for harmaline, with Tmax observed at 2.5 and 2.75 h after the low and high dose, respectively.
The AUC normalized by dose was calculated for each parent alkaloid, and these values were compared between doses by means of a paired Student's t test. A statistically significant difference was found for DMT, suggesting a possible nonproportional increase of plasma levels between doses. In line with this possibility, mean Vz/F and CL/F values calculated for DMT decreased with dose. These decreases were statistically significant for Vz/F and showed a tendency for CL/F (t(14) = 1.94, p = 0.073).
In support of a parallel evolution of DMT plasma levels and subjective effects, no significant differences were found between DMT Tmax values and any of the seven VAS tmax values at any of the two administered ayahuasca doses.
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),
cocaine (Farré et al.,
1993), and the sedative flunitrazepam
(Farré et al., 1998).
The VAS-stimulated item reflects more specifically the effects of
psychostimulants such as amphetamine and MDMA
(Camí et al., 2000).
Increases in VAS-drunken, which was the least modified VAS item by ayahuasca,
have been observed mainly after sedatives, such as flunitrazepam
(Farré et al., 1998),
and alcohol (Farré et al.,
1993), but also after 125 mg of MDMA
(Camí et al., 2000).
Regarding the HRS, our findings are in line with results by other researchers
who have demonstrated statistically significant increases in all HRS scales
after the administration of various psychedelics, such as i.v. DMT and oral
psilocybin (Strassman et al.,
1994; Gouzoulis-Mayfrank et
al., 1999). However, ayahuasca differed from these drugs in the
time course of effects. The overall duration was longer than that of i.v. DMT,
but shorter than that of mescaline or LSD
(Strassman, 1994). Finally,
regarding the ARCI questionnaire, increases in the ARCI-A, ARCI-BG, and
ARCI-MBG scales are a common feature of psychostimulants
(Martin et al., 1971;
Lamas et al., 1994). However,
in contrast, with drugs like amphetamine, methamphetamine, ephedrine, and
methylphenidate (Martin et al.,
1971), ayahuasca did not induce significant increases in the
ARCI-BG scale, a measure of subjectively perceived improvement in intellectual
efficiency. The coexistence of drug-induced stimulation with a wide range of
modifications in the sensorium places ayahuasca among the psychedelics, a drug
class which shares arousing properties with psychostimulants
(Brawley and Duffield,
1972).
The present results on the subjective effects induced by ayahuasca in a
clinical research setting replicate those obtained in a preliminary study
involving a smaller sample of volunteers with prior experience with ayahuasca,
and with a single-blind nonrandomized design
(Riba et al., 2001b). In the
previous study, statistically significant increases were observed in all HRS
items, except volition, and in the ARCIMBG, ARCI-LSD, and ARCI-A scales. In
the present study, however, scores on these measures at the 0.6 and 0.85 mg of
DMT/kg doses tended to be lower than those obtained after 0.5 and 0.75 mg of
DMT/kg doses, respectively. Several factors such as sample size, study design,
and prior exposure to ayahuasca could account for these differences. Scores on
the HRS items at the present low dose were also lower than those reported by
Grob et al. (1996), except for
the somaesthesia and perception items, after the administration of an
equivalent ayahuasca dose, in terms of DMT content, to a group of experienced
long-term ritual users. Nevertheless, scores on all HRS items after the
present high dose were higher than those reported by these researchers.
Compared with i.v. DMT as described by Strassman et al.
(1994), ayahuasca evokes
effects of milder intensity, which show a slower onset and a longer overall
duration. Scorings on the six HRS scales after the present high dose fell
between those reported after 0.1 and 0.2 mg/kg i.v. DMT.
In our previous study on ayahuasca
(Riba et al., 2001b), we
failed to observe statistically significant modifications of cardiovascular
parameters in a five-subject sample. In the present work, only modifications
in DBP reached statistical significance. Increases in DBP, SBP, and HR were
milder than those reported for other more prototypical sympathomimetics, such
as amphetamine or MDMA, at doses showing psychotropic properties
(Mas et al., 1999;
de la Torre et al., 2000). DBP
increases from baseline values after both ayahuasca doses were somewhat lower
than the elevations from baseline values reported by Callaway et al.
(1999) after an ayahuasca dose
containing 0.48 mg of DMT/kg but larger amounts of -carbolines.
The time course of DMT plasma concentrations closely paralleled that of
subjective effects. The steep rise in DMT plasma levels observed at 1 h
coincided with an analogous rise in VAS scores, and peak DMT concentrations
and peak effects were obtained between 1.5 and 2 h. In the present study,
quantifiable plasma levels were observed for DMT and THH.
Tmax values for DMT and THH were similar to those reported
by Callaway et al. (1999).
However, Cmax values for DMT and THH in the present study
were lower than expected, even after taking into account the smaller amounts
administered in the case of THH. This could be due to a lower alkaloid
bioavailability from the lyophilizate compared with the aqueous solution
administered by Callaway et al.
(1999). The calculated
Vz/F values are similar in both studies, but Callaway et
al. (1999) reported higher
t1/2 and lower CL/F values. In the case of DMT, these
differences may be associated with the lower levels of harmala alkaloids
present in our ayahuasca and the consequent lower degree of MAO inhibition. In
addition to these interstudy differences, it is interesting to note that the
normalized AUC calculated for DMT in the present study showed a statistically
significant increase between the low and the high ayahuasca doses. This is
suggestive of a nonlinear increment of DMT levels following the administration
of increasing doses of ayahuasca. Considering that both
Vz/F and CL/F decreased in a similar proportion between
doses, these data could be interpreted as indicating a greater DMT
bioavailability following the high dose, probably related to the higher
amounts of harmala alkaloids ingested, leading to more effective MAO
inhibition.
Another relevant difference from the study by Callaway et al.
(1999) is the lack of
measurable concentrations of harmine in plasma and the presence of significant
levels of harmol and harmalol. Differences in ayahuasca harmine content alone
cannot entirely explain the absence of this alkaloid in plasma, considering
that THH was present in the lyophilizate in amounts similar to those of
harmine and was later measurable in plasma. Thus, harmine was either not
absorbed in the gastrointestinal tract or was extensively degraded by
first-pass metabolism before reaching systemic circulation. The presence of
harmol in plasma would support the second hypothesis. Harmol glucuronide and
harmol sulfate have been described as the main urine metabolites of harmine
following its i.v. administration in humans
(Slotkin et al., 1970). A very
recent study has found cytochrome P450 to catalyze the
O-demethylation of harmine and harmaline, and has identified CYP2D6
and CYP1A1 as the major isoenzymes involved in the process
(Yu et al., 2003).
Nevertheless, we cannot conclude that harmine was completely metabolized to
render harmol, because very small amounts of harmol and harmalol have been
detected in B. caapi and ayahuasca
(Rivier and Lindgren, 1972;
McKenna et al., 1984). Thus,
it cannot be entirely ruled out that at least part of the amounts found in
plasma could have been ingested with the tea.
The low plasma levels found for harmine in the present study could explain
the absence of a clear-cut MAO inhibitor effect on the urinary excretion of
monoamine metabolites. The acute administration of a MAO-A inhibitor induces a
decrease in the levels of oxidized deaminated monoamine metabolites and an
increase in the levels of COMT-dependent methylated compounds
(Pletscher, 1966;
Koulu et al., 1989). Whereas
in the present study normetanephrine, a methylated breakdown product of
norepinephrine, showed statistically significant increases after dosing with
ayahuasca, the levels of the deaminated metabolites measured, i.e., VMA, HVA,
and 5-HIAA, did not show decreases but, rather, were nonsignificantly
increased. It is thus unclear whether the observed neurotransmitter metabolite
profile was secondary to MAO inhibition. An alternative explanation would be
an increase in norepinephrine release induced by DMT, which would fit well the
observed sympathomimetic properties of this compound. However, this assumption
is not supported by the limited available evidence from related compounds.
Results obtained in two studies involving LSD administration to humans found
no drug effects on monoamine metabolite excretion
(Hollister and Moore, 1967;
Messiha and Grof, 1973), and
to our knowledge, no data are available on the effects of parenteral DMT on
these measures. In any case, MAO inhibition by ayahuasca alkaloids effectively
facilitated the access of DMT to systemic circulation but may have been
insufficiently potent or insufficiently prolonged to modify the profile of
deaminated monoamine metabolites in the 8-h urine collection periods used.
To conclude, the present findings indicate that following ayahuasca administration to humans, measurable DMT plasma levels are obtained together with distinct psychedelic effects. Psychoactivity is attained with negligible levels of circulating harmine. These results and the lack of a clear-cut systemic MAO inhibitor effect are suggestive of a harmine-DMT interaction predominantly taking place in the gastrointestinal tract and possibly in the liver. Harmine effects at a peripheral level would appear to suffice to prevent first-pass metabolism of DMT and allow its access to the CNS in amounts able to evoke psychotropic effects.
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Acknowledgements |
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Footnotes |
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ABBREVIATIONS: DMT, N,N-dimethyltryptamine; THH, tetrahydroharmine; LSD, D-lysergic acid diethylamide; CNS, central nervous system; MAO, monoamine oxidase; COMT, catechol-O-methyltransferase; VMA, vanillylmandelic acid; HVA, homovanillic acid; 5-HIAA, 5-hydroxyindoleacetic acid; MDMA, methylenedioxymethamphetamine; HPLC, high-performance liquid chromatography; VAS, visual analog scale(s); HRS, Hallucinogen Rating Scale; ARCI, Addiction Research Center Inventory; MBG, morphine-benzedrine group; PCAG, pentobarbital-chlorpromazine-alcohol group; BG, benzedrine group; AUC, area under the concentration-time curve; CL/F, total plasma clearance; Vz/F, apparent volume of distribution; ANOVA, analysis of variance; SBP, systolic blood pressure; DBP, diastolic blood pressure; HR, heart rate.
Address correspondence to: Manel J. Barbanoj, Àrea d'Investigació Farmacològica, Institut de Recerca, Hospital de la Santa Creu i Sant Pau., St. Antoni Maria Claret, 167, Barcelona 08025, Spain. E-mail: mbarbanoj{at}hsp.santpau.es
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