Cannabidiol (CBD)

Mechanisms of Action

Cannabidiol (CBD) has promise for many medical applications although they are not yet well defined nor are the mechanisms by which it works well understood.

 

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Cannabidiol (CBD)

 

 

The medical information on this site is provided as a resource for information only, and is not to be used or relied upon for any diagnostic or treatment purposes and is not intended to create any patient-physician relationship.  Readers are advised to seek professional guidance regarding the diagnosis and treatment of their medical concerns.

 

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Brief Overview

CBD: Mechanisms of Action by Diagnosis:

CBD: Mechanisms of Action by System:

 

 

CBD: Mechanisms of Action

 

 

Brief Overview

Due to its complex pharmacological profile, the actual mechanisms by which CBD provides its effects remain incompletely understood. Studies have revealed significant roles of various molecular targets in different studies, including 5HT1a, CB1, CB2, TRPV1, GlyRs, adenosine A1 and TRPA1. These targets are often not replicated in different studies. Finally, consideration should be given to possible drug–drug interactions due to a significant proportion of CBD’s interaction with cytochrome P450 enzymes (See:CBD Drug Interactions).

CBD has complex actions with various receptors in the nervous system. It may act as an agonist or antagonist or act as an alloweric modulater of certain receptors. An allosteric modulator is an agent that modulates, or changes, the shape of a receptor. A “negative” modulator changes the shape in such a way as to weaken or reduce the ability of the receptor to interact with another molecule, whereas a “positive” modulator changes the shape in such a way as to enhance the ability of the receptor to interact with another molecule.

Furthermore, CBD interacts with various systems that influence it therapeutic benefits, including enzymes and receptors in the endocannabinoid system, opioid receptors, and adenosine receptors.

 

Endocannabinoid System

CBD may act as an indirect agonist of cannabinoid receptors through increased endocannabinoid tone, most likely through FABP transporter inhibition, but it may directly antagonize the CB1 receptor. CBD activity for the CB2 receptor is also very complex, including both partial agonism and negative allosteric modulation. Partial agonism is dependent on receptor expression, density, and tonic activity of the system and therefore it may vary in different tissues and under different conditions, further suggesting a state-dependent requirement. Many of these targets include ion channels, such as TRPV1 and TRPA1 receptors or α3 GlyRs, adding to the complexity. See belowThe Endocannabinoid System.

Opioid Receptors

CBD is proposed to influence the opioid system of receptors via different mechanisms, directly and indirectly. These mechanisms appear to contribute at least in part to its analgesic benefits. See below,Interaction with Opioid Receptors.

 

Adenosine Receptors

The role of adenosine receptors in the anti-inflammatory and anti-nociceptive effects of CBD is of interest since CBD is a potent inhibitor of adenosine reuptake; therefore, adenosine receptors might be an important mode of CBD’s activity. There may be other molecular targets of CBD involved in pain transmission, including dopamine D2 receptors and GPR receptors. See below,Adenosine Receptors

 

CBD: Mechanisms of Action by Diagnosis

 

Pain

CBD appears to have analgesic benefits as demonstrated in various animal,  preclinical and clinical studies. Evidence shows that CBD has analgesic benefits for inflammatory and neuropathic pain but the explanation of how is not yet clear. It may in part be attributed to the anxiolytic properties of CBD which may influence the impact of pain. CBD may be effective for analgesia in treatment of various diseases, reducing hyperalgesia and mechanical and thermal allodynia via various routes of administration. When co-administered with ∆9-THC, CBD may reduce the effective dose and diminish negative side effects of ∆9-THC. However, some studies contradict this and indicate no modulation of ∆9-THC’s effects by CBD.

 

The exact mechanism of action of cannabidiol is unknown and has been controversial. However, it does not appear to involve direct effects at cannabinoid receptors as it has no significant affinity for these receptors. It may have indirect effects on these receptors since CBD appears to exert anti-inflammatory activity by increasing concentrations of the endocannabinoid anandamide, which can then stimulate cannabinoid receptors.

CBD has been associated with activity at a wide range of non-CB receptors, including serotonin 1A receptor (5-HT1A), TRPV1, and PPARγ receptors that are known to have roles in pain and inflammation. Preclinical studies suggest that CBD produces anti-inflammatory effects that reduce the painful symptoms of joint damage.

 

Endocannabinoid System

CBD’s interaction with the endocannabinoid system (ECS) regarding its benefit for pain has focused on its activity with the CB1 and CB2 receptors. CBD may be an inverse agonist at the CB2 receptor, which may also contribute to its anti- inflammatory effects or it may directly antagonize the CB1 receptor. CBD activity at the CB2 receptor is also very complex, including both partial agonism and negative allosteric modulation. 

CBD has been shown to inhibit fatty acid amide hydrolase (FAAH),  the enzyme that breaks down the endocannabinoid AEA (anandamide) which in turn stimulates the local release of endorphins. This activity enhances and prolongs analgesia.

CBD may also act as an antagonist of GPR55, the third known endocannabinoid receptor.

 

 

 Interaction with Opioid Receptors

CBD is an allosteric modulator of the mu- and delta-opioid receptors and has been noted to potentially enhance the analgesic effects of both endogenous and exogenous opioids.  An allosteric modulator is an agent that modulates, or changes, the shape of a receptor. A “negative” modulator changes the shape in such a way as to weaken or reduce the ability of the receptor to interact with another molecule, whereas a “positive” modulator changes the shape in such a way as to enhance the ability of the receptor to interact with another molecule.

 

TRPV1 Agonism

CBD also behaves as an agonist of the TRPV1 (transient potential vanilloid receptor, type 1), the receptor associated with the analgesic benefit of capsaicin in neuropathic pain, suggesting another mechanism for its action against nerve pain. It may also act as a TRPV2 agonist to mediate CGRP release from dorsal root ganglion neurons contributing to analgesia.

 

Cyclooxygenase and Lipoxygenase Inhibition

CBD has powerful analgesic and anti-inflammatory effects mediated by both cyclooxygenase and lipoxygenase inhibition. Its anti-inflammatory effect is several hundred times more potent than aspirin, although to date, there have been no clinical studies evaluating pure CBD in headache or chronic pain disorders.

 

Glycine Receptors

CBD acts as a positive allosteric modulator at α1 and α1β glycine receptors ,that are thought to play a role in chronic pain after inflammation or nerve injury since glycine acts as an inhibitory postsynaptic neurotransmitter in the dorsal horn of the spinal cord.

 

 

Inflammation

CBD appears safe for long-term treatment without significant side effects or tolerance development. Prolonged anti-inflammatory effects may have  direct influence on a cause of pain and therefore may provide persisting analgesic benefit. Acute CBD treatment may not be sufficient to combat the cause of the pain and therefore may only provide benefit for up to several hours. 

CBD inhibits recruitment of inflammation-inducing mast cells and macrophages in the intestine, reducing intestinal damage principally mediated by peroxisome proliferator activated receptor-γ (PPAR-γ) receptor pathway.

 

 

Anxiety

Clinical studies have revealed definitive anxiolytic effects of CBD. CBD reverses anxiety brought on by THC and by a public-speaking simulation in patients with social phobia. Neuroimaging studies also show that CBD decreases activation of brain regions associated with anxiety, fear, and emotional processing, including the amygdala and the anterior and posterior cingulate cortex.

While the mechanism by which CBD may reduce anxiety is not clear, there is strong evidence that the serotonergic system is involved in the anxiolytic action of CBD. 5-HT1A is a member of the family of 5-HT receptors, which are activated by the neurotransmitter serotonin. Found in both the central and peripheral nervous systems, 5-HT receptors trigger various intracellular cascades of chemical messages to produce either an excitatory or inhibitory response, depending on the chemical context of the message. 

At high concentrations, CBD directly activates the 5-HT1A (hydroxytryptamine) serotonin receptor, which confers an anti-anxiety effect. This G-coupled protein receptor is implicated in a range of biological and neurological processes, including  anxiety, addiction, appetite, sleep, pain perception, nausea and vomiting.

The serotonergic system in the brain is the site of action of the prominent classes of anxiolytic medications, the Selective Serotonin Reuptake Inhibitors (SSRIs – Prozac, Paxil, Zoloft, Celexa etc.) and the Serotonin Norepinephrine Reuptake Inhibitors (SNRIs – Cymbalta and Effexor). It is likely that CBD also acts on the endocannabinoid system by direct or indirect stimulation of cannabinoid receptors in ways that effect emotion and emotional memory.

CBD interacts with GABA-A receptor in a way that enhances the receptor’s binding affinity for its principal endogenous agonist, gamma-Aminobutyric acid  (GABA), which is the main inhibitory neurotransmitter in the central nervous system. The sedating effects of Valium, Xanax and other benzodiazepines are mediated by GABA receptor transmission. CBD reduces anxiety by changing the shape of the GABA-A receptor in a way that amplifies the natural calming effect of GABA.

 

Inflammatory Bowel Disease

CBD reduces intestinal inflammation through control of neuroimmune cells, suggesting that CBD may be a promising drug for the therapy of inflammatory bowel disease, especially Crohn’s disease. In a retrospective observational study of 30 patients with Crohn’s disease treated with Δ9-THC and CBD there was a significant reduction in disease activity.

CBD modulates inflammatory agents IL-12 and IL-10 and reduces activity of TNF-α, another inflammatory agent. CBD also inhibits recruitment of inflammation-inducing mast cells and macrophages in the intestine, reducing intestinal damage principally mediated by peroxisome proliferator activated receptor-γ (PPAR-γ) receptor pathway.

CBD has a generalized suppressive effect on T- cell functional activities in the gut an example of the immunomodulatory action of CBD.

 

 

 

Neurodegenerative Diseases

CBD has a role in inflammatory neurodegenerative diseases. CBD strongly inhibits the production of inflammatory cytokines, including IL-1β, IL-6, and interferon-β (IFN-β), in microglial cells. Microglia act as primary responding cells for infection and injury, but prolonged or excessive activation may result in pathological forms of inflammations that contribute to the progression of neurodegenerative disease including Parkinson’s and Alzheimer’s diseases, multiple sclerosis and HIV-associated dementia and brain trauma-related chronic traumatic encephelopathy. In this case the effects are not mediated via CB1 or CB2 receptors.

CBD is also thought to be neuroprotective by reducing oxidative stress, mitochondrial dysfunction and inflammatory changes. One mechanism of the neuroprotection provided by CBD is the up-regulation of the mRNA levels for Cu–Zn superoxide dismutase, resulting in increased activity of an important enzyme in endogenous defenses against oxidative stress and mitochondrial dysfunction.

 

 

Reward Deficiency Syndrome – Addiction

As an allosteric modulator of the dopamine D2 receptor, an essential element in the reward system of the brain, evidence suggests CBD offers benefit in addiction treatment. In preclinical studies, CBD reduces drug-motivated behavior, suppresses withdrawal symptoms and limits cravings.

 

Opioid Addiction

The majority of the addiction treatment effects of CBD have been investigated in the context of opiate drugs. CBD  normalizes opioid-induced impairments in the reward center (the nucleus accumbens – NAc), including AMPA and CB1 receptor levels. In a human clinical study it was demonstrated that CBD does not alter the subjective effects of fentanyl but reduces heroin cue-induced drug craving and anxiety. These results suggest that CBD reduces opioid-paired cue reactivity but has little effect on the acute reinforcing properties of opioids.

However, other research shows that the reward-facilitating effects of morphine are decreased by CBD, and these effects are associated with the 5-HT1A receptor.  CBD is an agonist of the 5-HT1A receptor and evidence suggests that 5-HT1A agonists reduce baseline serotonin and dopamine release in the NAc, suggesting a mechanism whereby CBD may reduce the acute reinforcing effects of morphine. The 5-HT1A receptor is also localized in dopamine terminal regions elsewhere in the brain reward circuitry such as the prefrontal cortex, amygdala, and hippocampus as well as the NAc.

 

Nicotine Addiction

Preliminary findings indicate that CBD reduces cigarette smoking in smokers trying to quit. Although the mechanism for this effect has not been definitely identified, CBD may modulate nicotine reward through its ability to increase endocannabinoid levels by inhibiting FAAH, the enzyme that breaks down the endogenous endoccannabinoids. It has been demonstrated that inhibiting FAAH blocks nicotine seeking and nicotine-induced dopamine release in the Nucleus Accumbens reward center. It also reduces anxiety during nicotine withdrawal in animals.

 

Psychostimulant Addiction

In contrast to its effects on opioid-motivated behaviors, CBD has less  impact on psychostimulant reward and reinforcement. Administration of CBD fails to reduce cocaine-mediated decreases in self-stimulation thresholds or disrupt cocaine- and amphetamine-conditioned place preference. 

 

 

Neurobiology of CBD

CBD has been described as a CB1 receptor (CB1R) negative allosteric modulator; CB2 receptor (CB2R) antagonist; GPR18, GPR55, and 5HT3A antagonist; 5HT1A, 5HT2A, adenosine 1A, and PPARγ partial agonist; and an allosteric modulator of the μ- and δ-opioid receptors.

In a 2020 study, CBD displayed low affinity at both CB1R and CB2R and displayed minimal activity at both receptors.

 

CBD: Mechanisms of Action by System

The Endocannabinoid System

As part of the endocannabinoid system, there are two main cannabinoid (CB) receptors, CB1 which is primarily located in the central nervous system with small amounts found in peripheral tissues and CB2 receptors, which are found mostly outside the central nervous system,  with only low amounts in the central nervous system. CB2 receptors are primarily found on cells and organs associated with the immune system and in the gastrointestinal tract. See: Endocannabinoid System

 

CBD has much lower affinity for CB1 or CB2 receptors compared with THC. It acts as an antagonist of CB1 and CB2 agonists including THC. At low concentrations, CBD’S antagonism of CB1 explains its benefit in reducing THC side effects such as anxiety, tachycardia, and sedation. CBD appears to reduce some of these negative side effects of THC when the CBD:THC ratio is at least 8:1, but CBD may exacerbate some of the THC side effects when the CBD:THC ratio is lower, around 2:1. CBD also acts an inverse agonist at the CB2 receptor, which may contribute to its anti-inflammatory effects.

 

CB1 Receptor

Whereas THC acts primarily  on the CB1 receptor, CBD modulates but does not seem to act directly at CB1 receptors but instead acts as a non-competitive negative allosteric modulator of CB1 (see above). While CBD does not directly trigger the CB1 receptor, it may influence CB1 receptor transmission by other indirect methods.

 

FAAH Inhibition

CBD increases levels of the endogenous cannabinoid, anandamide (AEA), by blocking anandamide reuptake by inhibiting its transporters and by inhibiting its breakdown by fatty acid amide hydrolase (FAAH), the hydrolytic enzyme of AEA that breaks AEA down.

Apart from its known effects on the endocannabinoid system system, CBD exhibits pharmacological activity across a range of other receptors as noted above.  Another benefit provided by CBD is the up-regulation of the mRNA levels for Cu–Zn superoxide dismutase, an important enzyme in endogenous defenses against oxidative stress. In addition, CBD inhibits adenosine uptake.

 

 

 

Adenosine Receptors

The role of adenosine receptors in the anti-inflammatory and anti-nociceptive effects of CBD is of interest since CBD is a potent inhibitor of adenosine reuptake; therefore, adenosine receptors might be an important mode of CBD’s activity. There may be other molecular targets of CBD involved in pain transmission, including dopamine D2 receptors and GPR receptors.

CBD not only affects the central nervous system, but also the cardiovascular system. Adenosine receptors have been implicated in regulating coronary blood flow and oxygen consumption by cardiac muscle and they are also present in the brain. CBD inhibits the subsequent ventricular tachycardia following coronary artery occlusion in rats, demonstrating that CBD may have anti-arrhythmic effects, possibly mediated by the adenosine A1 receptor. In addition to effects on the A1 receptor, A2 receptor-mediated effects of CBD have also been reported  to mediate anti-inflammatory effects of CBD.  Studies have suggested that neuroprotective effects of CBD are mediated via adenosine A2 receptor modulation although this has also been contested and a clear link between the reported neuroprotective effects of CBD and adenosine A2 receptors has not yet been confirmed.

 

 

 

Peroxisome Proliferator-activated Receptors

The peroxisome proliferator-activated receptor (PPAR) γ, otherwise known as the glitazone receptor, is thought to be responsible for lipid storage and glucose metabolism, and some anticancer effects of CBD are thought to by mediated through interaction with PPARγ. CBD has also been shown to inhibit tumor cell viability. These effects on tumor cells are not believed to be due to CBD action on CB1, CB2, or TRPV1 receptors.

 

 

 

Resources:

National Academy of Sciences

The Health Effects of Cannabis and Cannabinoids: The Current State of Evidence and Recommendations for Research

 

These lay-person websites appear to be good resources for exploring medical marijuana:

  1. www.GreenCamp.com
  2. www.Healer.com
  3. www.MedicalJane.com
  4. www.ProjectCBD.org

 

 

References:

Epidiolex (cannabidiol)

  1. FDA approves CBD drug – Epidiolex – The Washington Post

 

Marinol (dronabinol)

  1. Marinol – dronabinol

 

Cannabidiol (CBD)- Overviews

  1. CANNABIDIOL (CBD) Pre-Review Report WHO 2017
  2. Cannabidiol – State of the art and new challenges for therapeutic applications. – 2017 PubMed – NCBI

 

CBD – Anxiety

  1. Overlapping Mechanisms of Stress-Induced Relapse to Opioid Use Disorder and Chronic Pain – Clinical Implications – 2016
  2. Cannabidiol Modulates Fear Memory Formation Through Interactions with Serotonergic Transmission in the Mesolimbic System – 2016
  3. Cannabidiol regulation of emotion and emotional memory processing: relevance for treating anxiety-related and substance abuse disorders. – PubMed – NCBI
  4. Review of the neurological benefits of phytocannabinoids – 2018
  5. Plastic and Neuroprotective Mechanisms Involved in the Therapeutic Effects of Cannabidiol in Psychiatric Disorders – 2017
  6. Neural basis of anxiolytic effects of cannabidiol (CBD) in generalized social anxiety disorder: a preliminary report. – PubMed – NCBI
  7. Evidences for the Anti-panic Actions of Cannabidiol – 2017
  8. Cannabidiol, a Cannabis sativa constituent, as an anxiolytic drug – 2012
  9. Cannabidiol Reduces the Anxiety Induced by Simulated Public Speaking in Treatment-Naïve Social Phobia Patients – 2011

 

CBD – Interaction with THC

  1. Cannabidiol: a promising drug for neurodegenerative disorders? – PubMed – NCBI
  2. Oral Cannabidiol does not Alter the Subjective, Reinforcing or Cardiovascular Effects of Smoked Cannabis – 2015
  3. Taming THC – potential cannabis synergy and phytocannabinoid-terpenoid entourage effects – 2011
  4. A tale of two cannabinoids: the therapeutic rationale for combining tetrahydrocannabinol and cannabidiol. – PubMed – NCBI

 

CBD – Pain

  1. The non-psychoactive cannabis constituent cannabidiol is an orally effective therapeutic agent in rat chronic inflammatory and neuropathic pain. – PubMed – NCBI 2007
  2. Molecular Targets of Cannabidiol in Neurological Disorders – 2015
  3. Cannabidiol Modulates Fear Memory Formation Through Interactions with Serotonergic Transmission in the Mesolimbic System – 2016
  4. Cannabidiol enhances morphine antinociception, diminishes NMDA-mediated seizures and reduces stroke damage via the sigma 1 receptor – 2018
  5. Cannabidiol modulates serotonergic transmission and reverses both allodynia and anxiety-like behavior in a model of neuropathic pain. – PubMed – NCBI – 2018
  6. Cannabidiol for Pain Treatment – Focus on Pharmacology and Mechanism of Action – 2020
  7. Topical cannabidiol is well tolerated in individuals with a history of elite physical performance and chronic lower extremity pain – 2023

 

CBD – Pharmacodynamics

  1. Beyond the CB1 Receptor – Is Cannabidiol the Answer for Disorders of Motivation? – 2016
  2. Molecular Targets of Cannabidiol in Neurological Disorders – 2015
  3. In vitro and in vivo pharmacological activity of minor cannabinoids isolated from Cannabis sativa – 2020

 

CBD – Pharmacokinetics

  1. Human Cannabinoid Pharmacokinetics – 2007
  2. A tale of two cannabinoids: the therapeutic rationale for combining tetrahydrocannabinol and cannabidiol. – PubMed – NCBI
  3. Human Metabolites of Cannabidiol – A Review on Their Formation, Biological Activity, and Relevance in Therapy 2016
  4.  A Comprehensive Review on Pharmacotherapeutics of Herbal Bioenhancers – 2012
  5. The effects of black pepper on the intestinal absorption and hepatic metabolism of drugs. – PubMed – NCBI – 2011
  6. Piperine-pro-nanolipospheres as a novel oral delivery system of cannabinoids: Pharmacokinetic evaluation in healthy volunteers in comparison to buc… – PubMed – NCBI – 2017
  7. A Systematic Review on the Pharmacokinetics of Cannabidiol in Humans
  8. Human Pharmacokinetic Parameters of Orally Administered Δ 9-Tetrahydrocannabinol Capsules Are Altered by Fed Versus Fasted Conditions and Sex Differences – PubMed

 

CBD – Metabolites

  1. Human Metabolites of Cannabidiol – A Review on Their Formation, Biological Activity, and Relevance in Therapy – 2016

 

CBD – Drug Interactions

  1. Cannabidiol, a Major Phytocannabinoid, As a Potent Atypical Inhibitor for CYP2D6 – 2011
  2. The Effect of CYP2D6 Drug-Drug Interactions on Hydrocodone Effectiveness – 2014 
  3. Characterization of P-glycoprotein Inhibition by Major Cannabinoids from Marijuana – 2006
  4. Beyond the CB1 Receptor – Is Cannabidiol the Answer for Disorders of Motivation? – 2016
  5. Pharmacokinetic Drug Interactions with Tobacco, Cannabinoids and Smoking Cessation Products. – PubMed – NCBI – 2016
  6. The pharmacokinetics and the pharmacodynamics of cannabinoids. – PubMed – NCBI – 2018
  7. Drug-drug interactions as a result of co-administering Δ9-THC and CBD with other psychotropic agents. – PubMed – NCBI – 2018
  8. Medicinal Cannabis—Potential Drug Interactions – 2019

 

Medical Marijuana – Opioids

  1. Use-of-Prescription-Pain-Medications-Among-Medical-Cannabis-Patients
  2. It is premature to expand access to medicinal cannabis in hopes of solving the US opioid crisis – 2018
  3. Patterns of medicinal cannabis use, strain analysis, and substitution effect among patients with migraine, headache, arthritis, and chronic pain in a medicinal cannabis cohort – 2018
  4. Patterns and correlates of medical cannabis use for pain among patients prescribed long-term opioid therapy. – PubMed – NCBI
  5. Associations between medical cannabis and prescription opioid use in chronic pain patients – A preliminary cohort study – 2017
  6. The prevalence and significance of cannabis use in patients prescribed chronic opioid therapy: a review of the extant literature. – PubMed – NCBI
  7. The use of cannabis in response to the opioid crisis: A review of the literature. – PubMed – NCBI
  8. Medical Cannabis Laws and Opioid Analgesic Overdose Mortality in the United States, 1999–2010 – 2014
  9. Rationale for cannabis-based interventions in the opioid overdose crisis – 2017
  10. Cannabis and the Opioid Crisis – 2018
  11. Impact of co-administration of oxycodone and smoked cannabis on analgesia and abuse liability. – PubMed – NCBI
  12. Cannabinoid–Opioid Interaction in Chronic Pain
  13. Synergistic interactions between cannabinoid and opioid analgesics. – PubMed – NCBI
  14. FDA approves CBD drug – Epidiolex – The Washington Post
  15. Opioid transport by ATP-binding cassette transporters at the blood-brain barrier: implications for neuropsychopharmacology. – PubMed – NCBI – 2011
  16. Opioids and the Blood-Brain Barrier – A Dynamic Interaction with Consequences on Drug Disposition in Brain – 2017
  17. The pharmacokinetics and the pharmacodynamics of cannabinoids. – PubMed – NCBI – 2018
  18. Cannabinoids and Cytochrome P450 Interactions. – PubMed – NCBI – 2016
  19. Pharmacogenetics of Cannabinoids – 2017 Enhanced Brain Disposition and Effects of Δ9-Tetrahydrocannabinol in P-Glycoprotein and Breast Cancer Resistance Protein Knockout Mice. 2012
  20. Pharmacogenomics of methadone maintenance treatment. – PubMed – NCBI
  21. Relationship between ABCB1 polymorphisms and serum methadone concentration in patients undergoing methadone maintenance therapy (MMT). – PubMed – NCBI- 2016
  22. Impact of ABCB1 and CYP2B6 Genetic Polymorphisms on Methadone Metabolism, Dose and Treatment Response in Patients with Opioid Addiction – A Systematic Review and Meta-Analysis – 2014
  23. ABCB1 haplotype and OPRM1 118A > G genotype interaction in methadone maintenance treatment pharmacogenetics – 2012
  24. The opioid epidemic – a central role for the blood brain barrier in opioid analgesia and abuse – 2017
  25. Morphine and the blood-brain barrier – diffusion, uptake, or efflux? – 2017
  26. Cyclosporine-inhibitable Blood-Brain Barrier Drug Transport Influences Clinical Morphine Pharmacodynamics – 2013
  27. Methadone Treatment for Pain States – 2005
  28. Cyclosporine-inhibitable Cerebral Drug Transport Does not Influence Clinical Methadone Pharmacodynamics – 2014
  29. Targeting blood–brain barrier changes during inflammatory pain – an opportunity for optimizing CNS drug delivery – 2011
  30. Targeting Transporters – Promoting Blood-Brain Barrier Repair in Response to Oxidative Stress Injury – 2015
  31. Cannabidiol enhances morphine antinociception, diminishes NMDA-mediated seizures and reduces stroke damage via the sigma 1 receptor – 2018

Medical Marijuana –Misc

  1. A tale of two cannabinoids: the therapeutic rationale for combining tetrahydrocannabinol and cannabidiol. – PubMed – NCBI
  2. Cannabis and cannabis extracts – greater than the sum of their parts? – 2001
  3. Medical cannabis and mental health: A guided systematic review. 2016 – PubMed – NCBI
  4. Epidemiological characteristics, safety and efficacy of medical cannabis in the elderly. – PubMed – NCBI
  5. Cannabis-conclusions – 2017 National Academy of Sciences
  6. Cannabis-chapter-highlights – 2017 National Academy of Sciences
  7. Cannabis-report-highlights – 2017 National Academy of Sciences
  8. Clinical Endocannabinoid Deficiency (CECD): Can this Concept Explain Therapeutic Bene ts of Cannabis in Migraine, Fibromyalgia, Irritable Bowel Syndrome and other Treatment-Resistant Conditions?-2004
  9. Marijuana use and the risk of lung and upper aerodigestive tract cancers: results of a population-based case-control study. – PubMed – NCBI
  10. Cannabis use and cognitive function: 8-year trajectory in a young adult cohort. – PubMed – NCBI
  11. Cannabinoids for Medical Use: A Systematic Review and Meta-analysis. – PubMed – NCBI
  12. Cannabinoids and Cytochrome P450 Interactions. – PubMed – NCBI Pharmacogenetics of Cannabinoids – 2018
  13. Systematic review of systematic reviews for medical cannabinoids – 2018
  14. Adverse effects of medical cannabinoids – a systematic review – 2008
  15. Cannabimimetic effects modulated by cholinergic compounds. – PubMed – NCBI
  16. Antagonism of marihuana effects by indomethacin in humans. – PubMed – NCBI
  17. Pharmacokinetics and pharmacodynamics of cannabinoids. – PubMed – NCBI
  18. Clinical Pharmacodynamics of Cannabinoids – 2004
  19. Affinity and Efficacy Studies of Tetrahydrocannabinolic Acid A at Cannabinoid Receptor Types One and Two. – 2017
  20. Quality Control of Traditional Cannabis Tinctures – Pattern, Markers, and Stability – 2016
  21. Exogenous cannabinoids as substrates, inhibitors, and inducers of human drug metabolizing enzymes: a systematic review. – PubMed – NCBI
  22. Pharmacology of Cannabinoids
  23. Current-status-and-future-of-cannabis-research-Clin-Researcher-2015
  24. Medical Marijuana for Treatment of Chronic Pain and Other Medical and Psychiatric Problems – A Clinical Review – 2015

 

Medical Marijuana – Product Evaluation

  1. The Cannabinoid Content of Legal Cannabis in Washington State Varies Systematically Across Testing Facilities and Popular Consumer Products – 2018
  2. Quality Control of Traditional Cannabis Tinctures – Pattern, Markers, and Stability – 2016

Emphasis on Education

 

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