View clinical trials related to Marijuana Abuse.
Filter by:ADHD is the most frequent neuro-developmental disorder in childhood and often continues into adolescence and adulthood. Indicated drug treatments for ADHD fall into 2 categories: stimulants (such as methylphenidate and amphetamines) and non-stimulants (such as atomoxetine, guanfacine and clonidine) but some persons cannot tolerate their secondary effects or find them non-effective. In the last decade, medical cannabis products have been researched as possible treatment for neurological and mental diseases such as: Post trauma disorder (PTD), autism (ASD), epilepsy, fibromyalgia (FM) and more. Data on the effects of cannabidiol rich cannabis extract use for ADHD seems promising but is still limited. The aim of this study is to investigate if oral cannabinoids given to adults with ADHD affect the symptoms of the disorder. The main objectives of the study are: 1) to characterize the effects of treatment with cannabis oil on symptoms of ADHD; 2) to compare safety and efficacy of cannabis oil products with different CBD,Cannabidivarin (CBDV), cannabigerol (CBG) and THC ratio; 3) and to measure endocannabinoids, THC and CBD and metabolites levels in the blood of the participants. In this study, participants diagnosed with ADHD will be treated with canabidiol-rich cannabis oil and will follow up weekly during approx.1 month (the study period). Blood tests will be performed before and after treatment. Blood tests include blood count, blood chemistry, hormones profile, phyto- and endo- cannabinoids and their metabolites. Test of Variables of Attention test (TOVA) will be administrated before and after treatment
The overall objective of this proposed project is to prospectively evaluate the epigenetic and developmental effects of paternal cannabis and other drug use in offspring.
Background: Tetrahydrocannabinol (THC) is a partial CB1/CB2 agonist and causes its pharmacological effects by binding to cannabinoid receptors. CB1 receptors are predominantly located in the brain (highest densities at hippocampus, cerebellum and the striatum) and at low levels in the brainstem. CB2 receptors are predominantly in the spleen and in hematopoietic cells. THC is highly lipophilic and is readily absorbed and distributed to the brain and other organs. Most of the neuropsychological studies carried out so far show that the mainly affected neurocognitive functions in cannabis users are: memory, attention, psychomotor capacity, speed of information processing and alterations of executive functions (resistance to interference, planning capacity, decision-making, verbal fluency and working memory). These effects are dose-dependent. Hypothesis: Functional CB1 receptor activation by the THC contained in the cannabis flos will induce dose-dependent effects on EEG, physiological functions and behavior: 1. EEG alterations. 2. Increase in cannabis subjective effects. 3. Increase in heart rate. 4. Increase in psychopathology scale Psychotomimetic State Inventory (PSI) score. 5. Increase in plasma cortisol concentrations. Objectives: Main pharmacodynamic objective: To assess the effects of Cannabis flos on electroencephalography (EEG) in healthy recreational cannabis users. Secondary pharmacodynamic objectives: (i) To assess the effects of Cannabis flos on: cannabis subjective effects, heart rate and psychopathology scale; (ii) To establish the pharmacokinetic/pharmacodynamic relationships between THC plasma concentrations and pharmacodynamic endpoints. Safety and tolerability objectives: To assess the safety and tolerability of THC in these subjects. Methods: Phase I, prospective, monocentric, double-blind, randomized, placebo-controlled, parallel group study to assess the THC effects on EEG neural oscillations in 16 healthy subjects with recreational cannabis use.
Cannabis use disorders are common among young adults in psychiatric treatment. Unfortunately, cannabis use can result in deleterious consequences for those in treatment, including developing more severe psychopathology and poorer treatment outcomes. Brief, electronic interventions for cannabis use have been developed for young adults. An example of a frequently used brief electronic intervention for cannabis users is e-Toke. e-Toke can be completed on a computer, tablet or phone, and has been shown to improve motivation to engage in substance use treatment among college students. However, e-Toke is less useful in decreasing the actual frequency of cannabis use. Additionally, e-toke is not tailored to young adults in psychiatric treatment. In this study, the investigators will develop and test a text messaging intervention that can be easily added to the popular computerized intervention e-Toke. The research staff hope the intervention will improve motivation to decrease cannabis use, and decrease the frequency of cannabis use, among young adults in psychiatric outpatient treatment. The text messages will be developed by, and tailored to, young adults in psychiatric treatment and texts will address motivations and barriers to reducing cannabis use in the context of psychiatric disorders. If the text message intervention is found to be an effective addition to e-Toke, this approach can be tested in a larger study, and then disseminated to other young adults in psychiatric treatment.
Biomarkers of recent drug use and intoxication have societal relevance, in that they are used by law enforcement and other agencies to detect drug impairment. For instance, a breathalyzer can quickly and accurately detect blood alcohol content (BAC) to indicate if a person is under the influence of alcohol; however, there is currently no similar way to quickly detect if a person is under the influence of cannabis. In light of increasing cannabis use, it is important to define a quantitative, objective method of determining recent use and intoxication. The link between changes in eye characteristics (e.g. movement, pupil dilation) and cannabis use is documented (Peragallo et al. 2013), but insufficiently characterized. Certain outcomes of eye behavior are known to be affected by recent cannabis use (e.g. the eyes' ability to converge on a target; Stapleton et al 1986), while findings are mixed regarding other outcomes (e.g. the eyes' ability to smoothly follow a target; Fant et al. 1998). Thus, the goal of this study is to identify a characteristic pattern of eye behavior, defined by performance on a battery of four eye tasks, as a function of recent cannabis use (7% vs. 0% THC). Using 30 healthy cannabis users (15 men, 15 women), this study will be one of the first to assess changes in eye behavior as a function of recent cannabis use within a quantified virtual reality (VR) environment. This study will examine the effect of smoked cannabis (7% vs. 0% THC) on individual eye movements, with the goal of defining the utility of the eyes as potential objective indicators of cannabis use and intoxication. Four eye tests (nystagmus, smooth pursuit, convergence, and pupillary light response; outlined below), which previous literature has defined as effective in detecting recent drug use (including opioids and alcohol; Murillo et al. 2004), have been compiled into a 5-minute task battery using a VR headset environment equipped with high frequency infrared eye trackers (the HTC Vive with Pupil Labs Tracking). This 5-minute VR battery of four eye tests will be administered prior to cannabis consumption as a baseline, and then at 0, 15, 30, 45, 60, 75, 90, 105, 120, and 165 min after cannabis, with the goal of comparing baseline values to the ten post-cannabis timepoints to detect changes in eye behavior as a function of cannabis intoxication. The study will also utilize a battery of subjective-effects and mood visual analogue scales (0-100 mm; e.g. 'Good Drug Effect') prior to the eye test battery at each timepoint, allowing us to correlate each outcome of the eye tasks to subjectively reported cannabis impairment and mood. In addition to measuring eye behavior as a function of cannabis use, the training session of this study will be used to also collect exploratory data on the relationship between pupil dilation and experimental pain. Using Quantitative Sensory Testing (Medoc TSA-II NeuroSensory Analyzer), thermal pain threshold and tolerance will be induced using a cold stimulus (4.0°C; induced with a 30 x 30 mm Peltier thermode, which is 1.5" square metal applicator that is connected to the TSA-II NeuroSensory Analyzer device and software, and produces an ongoing cold sensation applied to the lower palm of the participant's non-dominant hand). Participants will indicate first feelings of pain (pain threshold), and when the pain becomes too much to bear (pain tolerance) by pressing a button on a controller connected to the TSA-II. Throughout exposure to the cold stimulus, changes in pupil size to the patient's subjectively reported pain latencies will be recorded.
The purpose of this study is to determine if an eye tracking impairment sensor can detect cannabis-induced impairment after using cannabis.The overall objective is to correlate measures collected from the eye tracking sensor with measures related to cannabis impairment (e.g., plasma THC levels, self-reported cannabis subjective effects, cognitive effects).
In this innovative approach seeking effective therapeutic strategies, the investigators are proposing to test the effectiveness of medical cannabis oil as an adjunct to palliative Radiation Therapy (RT) and Best Supportive Care to alleviate cancer pain that was only partially relieved with conventional medications. Furthermore, the investigators will assess the effect of medical cannabis oil on health-related quality of life and symptoms that are frequently associated with metastatic cancers including fatigue, anxiety, depression, insomnia and decreased appetite. The safety profile of medical cannabis oil with respect to prolonged use of more than two weeks of administration, concomitant medication use and palliative RT will also be examined.
The primary purpose of this study is to investigate the effect of lorcaserin on reductions in cannabis use and multiple constructs of impulsivity in outpatient treatment-seeking individuals with cannabis use disorder (CUD). Additionally, the investigators will make use of the technological application of ecological momentary assessments (EMA), to collect real-time data at key time intervals during the study on participants' use of cannabis and other substances in addition to measuring impulsive traits through self-initiated, fixed and random phone prompts. This will be a 13-week randomized, double-blind, placebo-controlled trial, with week 1 focused on baseline assessments of impulsivity (through EMA in vivo and at study visits), weeks 2- 3 of medication lead-in, and week 4 targeting a reduced cannabis use/quit day through week 13. The primary aims are to (1) Examine the effect of lorcaserin compared to placebo, on reductions in cannabis use among treatment-seeking outpatients with CUD, (2) Examine the effect of lorcaserin compared to placebo on behavioral and self-report measures of impulsivity among individuals with CUD during the medication lead-in phase (weeks 2-3). The secondary aim is to examine whether reductions in impulsivity (during weeks 2-3) mediates the effect of lorcaserin on cannabis use (during weeks 8-13), if the primary hypotheses are supported. Finally, the investigators will explore the effect of lorcaserin compared to placebo on (1) drop-out rates, (2) time to discontinuation from study, (3) treatment adherence, and (4) nicotine use.
Abuse of psychoactive substances is a behavior belonging to the field of risk behaviors that begins and takes place during adolescence. These risk behaviors are a major public health problem in France and worldwide. Cannabis is the first illicit drug consumed by adolescents in France. His experimentation progresses rapidly between 11 and 17 years. The relationship between cannabis use and mental health has been shown by several studies. In particular Attention Deficit Hyperactivity Disorder (ADHD), characterized by attention deficit, impulsivity and disabling motor hyperactivity and beginning before 12 years of age (DSM-5), is a major risk factor for the consumption of cannabis. ADHD is a common condition (9% of children and 5% of adults), but often undiagnosed or untreated. It has been shown that the treatment of ADHD in childhood protects the consumption of psychoactive products during adolescence or adulthood. However, to our knowledge there is no study showing that treatment with methylphenidate in an ADHD patient - not treated - but already a cannabis user, was a positive prognostic factor in the decrease in cannabis use.
Despite the prevalence of cannabis use among the PTSD population and self-reports that it is used to help cope with PTSD symptoms, the direct effects of cannabis on PTSD symptomology are unknown. The purpose of this placebo-controlled, within-subject study is to assess the effects of smoked cannabis and orally administered nabilone, a synthetic analog of THC, the primary psychoactive component of cannabis on multiple dimensions of PTSD symptomatology in cannabis smokers with PTSD.