Effects of Δ9-tetrahydrocannabinol in individuals with a familial vulnerability to alcoholism.

BACKGROUND AND AIMS: A family history (FH) of alcoholism accounts for approximately 50% of the risk of developing alcohol problems. Several lines of preclinical evidence suggest that brain cannabinoid receptor (CB1R) function may mediate the effects of alcohol and risk for developing alcoholism including the observations that reduced CB1R function decreases alcohol-related behaviors and enhanced CB1R function increases them. In this first human study, we probed CB1R function in individuals vulnerable to alcoholism with the exogenous cannabinoid Δ(9)-tetrahydrocannabinol (Δ(9)-THC). DESIGN, SETTING, AND PARTICIPANTS: Healthy volunteers (n = 30) participated in a three test day study during which they received 0.018 and 0.036 mg/kg of Δ(9)-THC, or placebo intravenously in a randomized, counterbalanced order under double-blind conditions. MEASUREMENTS: Primary outcome measures were subjective "high," perceptual alterations, and memory impairment. Secondary outcome measures consisted of stimulatory and depressant subjective effects, attention, spatial memory, executive function, Δ(9)-THC and 11-hydroxy-THC blood levels, and other subjective effects. FH was calculated using the Family Pattern Density method and was used as a continuous variable. FINDINGS: Greater FH was correlated with greater "high" and perceptual alterations induced by Δ(9)-THC. This enhanced sensitivity with increasing FH was specific to Δ(9)-THC's rewarding effects and persisted even when FH was calculated using an alternate method. CONCLUSIONS: Enhanced sensitivity to the rewarding effects of Δ(9)-THC in high-FH volunteers suggests that alterations in CB1R function might contribute to alcohol misuse vulnerability.

Acute effects of THC on time perception in frequent and infrequent cannabis users.

RATIONALE: Cannabinoids have been shown to alter time perception, but existing literature has several limitations. Few studies have included both time estimation and production tasks, few control for subvocal counting, most had small sample sizes, some did not record subjects' cannabis use, many tested only one dose, and used either oral or inhaled administration of Δ9-tetrahydrocannabinol (THC), leading to variable pharmacokinetics, and some used whole-plant cannabis containing cannabinoids other than THC. Our study attempted to address these limitations. OBJECTIVES: This study aims to characterize the acute effects of THC and frequent cannabis use on seconds-range time perception. THC was hypothesized to produce transient, dose-related time overestimation and underproduction. Frequent cannabis smokers were hypothesized to show blunted responses to these alterations. METHODS: IV THC was administered at doses from 0.015 to 0.05 mg/kg to 44 subjects who participated in several double-blind, randomized, counterbalanced, crossover, placebo-controlled studies. Visual time estimation and production tasks in the seconds range were presented to subjects three times on each test day. RESULTS: All doses induced time overestimation and underproduction. Chronic cannabis use had no effect on baseline time perception. While infrequent/nonsmokers showed temporal overestimation at medium and high doses and temporal underproduction at all doses, frequent cannabis users showed no differences. THC effects on time perception were not dose related. CONCLUSIONS: A psychoactive dose of THC increases internal clock speed as indicated by time overestimation and underproduction. This effect is not dose related and is blunted in chronic cannabis smokers who did not otherwise have altered baseline time perception.

Dose-related behavioral, subjective, endocrine, and psychophysiological effects of the κ opioid agonist Salvinorin A in humans.

BACKGROUND: Salvia divinorum (Salvia) is an increasingly popular recreational drug amongst adolescents and young adults. Its primary active ingredient, Salvinorin A (SA)-a highly selective agonist at the κ opiate receptor-is believed to be one of the most potent naturally occurring hallucinogens. However, there is little experimental data on the effects of SA in humans. METHODS: In a 3-day, double-blind, randomized, crossover, counterbalanced study, the behavioral, subjective, cognitive, psychophysiological, and endocrine effects of 0 mg, 8 mg, and 12 mg of inhaled SA were characterized in 10 healthy individuals who had previously used Salvia. RESULTS: SA produced psychotomimetic effects and perceptual alterations, including dissociative and somaesthetic effects, increased plasma cortisol and prolactin, and reduced resting electroencephalogram spectral power. The SA administration was associated with a rapid increase of its levels in the blood. SA did not produce euphoria, cognitive deficits, or changes in vital signs. The effects were transient and not dose-related. SA administration was very well-tolerated without acute or delayed adverse effects. CONCLUSIONS: SA produced a wide range of transient effects in healthy subjects. The perceptual altering effects and lack of euphoric effects would explain its intermittent use pattern. Such a profile would also suggest a low addictive potential similar to other hallucinogens and consistent with κ opiate receptor agonism. Further work is warranted to carefully characterize a full spectrum of its effects in humans, to elucidate the underlying mechanisms involved, and to explore the basis for individual variability in its effects.

The safety of studies with intravenous Δ9-tetrahydrocannabinol in humans, with case histories.

RATIONALE: Delta-9-tetrahydrocannabinol (THC) is one of the few cannabinoid receptor ligands that can be used to probe the cannabinoid system in humans. Despite increasing interest in the cannabinoid receptor system, use of intravenous THC as a research tool has been limited by concerns about its abuse liability and psychoactive effects. OBJECTIVES: This study aims to evaluate the safety of all intravenous THC studies conducted at this center for the past 13 years. METHODS: Included were 11 studies with 266 subjects (14 schizophrenia patients and 252 healthy subjects, of whom 76 were frequent cannabis users), 351 active THC infusions, and 226 placebo infusions. Subjects were monitored for subjective and physical adverse events and followed up to 12 months beyond study participation. RESULTS: There was one serious and 70 minor adverse events in 9.7% of subjects and 7.4% of infusions, with 8.5% occurring after the end of the test day. Nausea and dizziness were the most frequent side effects. Adverse events were more likely to be associated with faster infusion rates (2-5 min) and higher doses (>2.1 mg/70 kg). Of 149 subjects on whom long-term follow-up data were gathered, 94% reported either no change or a reduction in their desire to use cannabis in the post-study period, 18% stated that their cannabis use decreased, and 3% stated that it increased in the post-study period. CONCLUSIONS: With careful subject selection and screening, risk to subjects is relatively low. Safeguards are generally sufficient and effective, reducing both the duration and severity of adverse events.

Dose-related modulation of event-related potentials to novel and target stimuli by intravenous Δ9-THC in humans.

Cannabinoids induce a host of perceptual alterations and cognitive deficits in humans. However, the neural correlates of these deficits have remained elusive. The current study examined the acute, dose-related effects of delta-9-tetrahydrocannabinol (Δ9-THC) on psychophysiological indices of information processing in humans. Healthy subjects (n=26) completed three test days during which they received intravenous Δ9-THC (placebo, 0.015 and 0.03 mg/kg) in a within-subject, double-blind, randomized, cross-over, and counterbalanced design. Psychophysiological data (electroencephalography) were collected before and after drug administration while subjects engaged in an event-related potential (ERP) task known to be a valid index of attention and cognition (a three-stimulus auditory 'oddball' P300 task). Δ9-THC dose-dependently reduced the amplitude of both the target P300b and the novelty P300a. Δ9-THC did not have any effect on the latency of either the P300a or P300b, or on early sensory-evoked ERP components preceding the P300 (the N100). Concomitantly, Δ9-THC induced psychotomimetic effects, perceptual alterations, and subjective 'high' in a dose-dependent manner. Δ9-THC -induced reductions in P3b amplitude correlated with Δ9-THC-induced perceptual alterations. Lastly, exploratory analyses examining cannabis use status showed that whereas recent cannabis users had blunted behavioral effects to Δ(9)-THC, there were no dose-related effects of Δ9-THC on P300a/b amplitude between cannabis-free and recent cannabis users. Overall, these data suggest that at doses that produce behavioral and subjective effects consistent with the known properties of cannabis, Δ9-THC reduced P300a and P300b amplitudes without altering the latency of these ERPs. Cannabinoid agonists may therefore disrupt cortical processes responsible for context updating and the automatic orientation of attention, while leaving processing speed and earlier sensory ERP components intact. Collectively, the findings suggest that CB1R systems modulate top-down and bottom-up processing.