Tag Archives: antiemetic

Psychoactive cannabinoids reduce gastrointestinal propulsion and motility in rodents.

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“Marijuana has been reported to be an effective antinauseant and antiemetic in patients receiving cancer chemotherapy.

Whether this is due to psychological changes, central antiemetic properties and/or direct effects on gastrointestinal (GI) function is not known. The purpose of these investigations was to determine whether the major constituents of marijuana and the synthetic cannabinoid nabilone have any effects on GI function which can be detected in rodent models of GI transit and motility. Intravenous delta 9-tetrahydrocannabinol (delta 9-THC) slowed the rate of gastric emptying and small intestinal transit in mice and in rats. Delta 9,11-THC, cannabinol and nabilone given i.v. also inhibited small intestinal transit in mice, but were less effective in reducing gastric emptying. Cannabidiol given i.v. had no effect on gastric emptying or intestinal transit. Those cannabinoids which inhibited GI transit did so at doses equal to, or lower, than those reported to produce central nervous system activity. In rats, delta 9-THC produced greater inhibition of gastric emptying and small intestinal transit than large bowel transit, indicating a selectivity for the more proximal sections of the gut. In addition, i.v. delta 9-THC decreased the frequency of both gastric and intestinal contractions without altering intraluminal pressure. Such changes probably reflect a decrease in propulsive activity, without change in basal tone.

These data indicate that delta 9-THC, delta 9,11-THC, cannabinol and nabilone (but not cannabidiol) exert an inhibitory effect on GI transit and motility in rats.”

http://www.ncbi.nlm.nih.gov/pubmed/2542532

[From cannabis to selective CB2R agonists: molecules with numerous therapeutical virtues].

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“Originally used in Asia for the treatment of pain, spasms, nausea and insomnia, marijuana is the most consumed psychotropic drug worldwide. The interest of medical cannabis has been reconsidered recently, leading to many scientific researches and commercialization of these drugs.

Natural and synthetic cannabinoids display beneficial antiemetic, anti-inflammatory and analgesic effects in numerous diseases, however accompanied with undesirable effects due to the CB1 receptor. Present researches focus on the design of therapeutical molecules targeting the CB2 receptors, and thus avoiding central side effects and therefore psychotropic effects caused by the CB1 receptor.”

http://www.ncbi.nlm.nih.gov/pubmed/23732102

Cannabidiol Relieves Psychosis in Schizophrenia, Why is it Illegal?

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“A molecule in cannabis (CBD) has shown to relieve anxiety and symptoms of psychosis in people diagnosed with schizophrenia, though many patients are denied or discouraged from this medicine with fewer side effects than pharmaceutical products because the DEA has deemed the cannabis plant to be “illegal”. The U.S. government needs to answer “why?” this medicine warrents time in prison when nobody is being harmed.

 Investigators concluded, “Our results provide evidence that the non-cannabimimetic constituent of marijuana, cannabidiol, exerts clinically relevant antipsychotic effects that are associated with marked tolerability and safety, when compared with current medications. … The results … potentially represent a completely new mechanism in the treatment of schizophrenia.”

 “Studies have suggested a wide range of possible therapeutic effects of cannabidiol on several conditions, including Parkinson’s disease, Alzheimer’s disease, cerebral ischemia, diabetes, rheumatoid arthritis, other inflammatory diseases, nausea and cancer,” Zuardi writes. Let’s look at a few of these in detail, shall we?

1. Antiepileptic action
“In 1973, a Brazilian group reported that CBD was active in … blocking convulsions produced in experimental animals.”

2. Sedative action
“In humans with insomnia, high doses of CBD increased sleep duration compared to placebo.”

3. Anxiolytic action
“CBD induce[s] a clear anxiolytic effect and a pattern of cerebral activity compatible with an anxiolytic activity.”

4. Antipsychcotic action
“[C]linical studies suggest that CBD is an effective, safe and well-tolerated alternative treatment for schizophrenic patients.”

5. Antidystonic action
“CBD … had antidystonic effects in humans when administered along with standard medication to five patients with dystonia, in an open study.”

6. Antioxidative action
“[I]t was demonstrated that CBD can reduce hydroperoxide-induced oxidative damage as well as or better than other antioxidants. CBD was more protective against glutamate neurotoxicity than either ascorbate or a-tocopherol, indicating that this drug is a potent antioxidant.”

7. Neuroprotective action
“A marked reduction in the cell survival was observed following exposure of cultured rat pheochromocytoma PC12 cells to beta-A peptide. Treatment of the cells with CBD prior to beta-A exposure significantly elevated the cell survival.”

8. Antiinflammatory action
“CBD, administered i.p. or orally, has blocked the progression of arthritis.”

9. Cardioprotective action
“CBD induces a substantial cardioprotective effect.”

10. Action on diabetes
“CBD treatment of NOD (non-obese diabetic) mice before the development of the disease reduced its incidence from 86% in the non-treated control mice to 30% in CBD-treated mice. … It was also observed that administration of CBD to 11-14 week old female NOD mice, which were either in a latent diabetes stage or had initial symptoms of diabetes, ameliorated the manifestations of the disease.”

11. Antiemetic action
“The expression of this conditioned retching reaction was completely suppressed by CBD and delta9-THC, but not by ondansetron, [an] antagonist that interferes with acute vomiting.”

12. Anticancer action
“A study of the effect of different cannabinoids on eight tumor cell lines, in vitro, has clearly indicated that, of the five natural compounds tested, CBD was the most potent inhibitor of cancer cell growth.”

In sum, the past 45 years of scientific study on CBD has revealed the compound to be non-toxic, non-psychoactive, and to possess a multitude of therapeutic properties. Yet, to this day it remains illegal to possess or use (and nearly impossible to study in US clinical trials) simply because it is associated with marijuana.

What possible advancements in medical treatment may have been achieved over the past decades had US government officials chosen to advance — rather than inhibit — clinical research into CBD (which, under federal law, remains a Schedule I drug defined as having “no currently accepted medical use”)? Perhaps it’s time someone asks John Walters or the DEA?” 

Read more: http://rinf.com/alt-news/latest-news/cannabidiol-relieves-psychosis-in-schizophrenia-why-is-it-illegal/17827/

Pharmacological exploitation of the endocannabinoid system: new perspectives for the treatment of depression and anxiety disorders?

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 “Animal experiments suggest that drugs promoting endocannabinoid action may represent a novel strategy for the treatment of depression and anxiety disorders.

Because of its analgesic, antiemetic and tranquilizing effects, the herb Cannabis sativa has been used for medical purposes for centuries. In addition, preparations of cannabis, such as marijuana, hashish or skunk, have a long history as drugs of abuse.1 Typical effects of cannabis abuse are amnesia, sedation and a feeling of well-being described as “bliss”.2 In the middle of the last century, Raphael Mechoulam and colleagues identified Δ9-tetrahydrocannabinol (Δ9-THC) as the main psychoactive ingredient of this herb. Today, it is known that Cannabis sativa contains more than 60 substances, such as cannabidiol, cannabinol and cannabicromene, which are referred to as phytocannabinoids.3 Their lipid nature posed a significant obstacle to chemical experiments, which might explain why the discovery of phytocannabinoids occurred late compared to other natural compounds (e.g. morphine was isolated from opium in the XIX century). The molecular structure rendered it likely that Δ9-THC exerts its effects primarily by changing physico-chemical characteristics of cell membranes. Therefore it came as a surprise that specific binding sites could be identified within the mammalian brain,4 followed by isolation and characterization of endogenous binding substances, named endocannabinoids.5 The development of novel pharmacological compounds targeting receptors or ligand synthesis and degradation revealed a number of complex brain functions, which are tightly controlled by the endocannabinoid system. The aim of the present review is to briefly introduce this system and its pharmacology, to discuss its involvement in psychopathology and to illustrate its therapeutic potential.

 Conclusion

 Malfunctions in the endocannabinoid system may promote the development and maintenance of psychiatric disorders such as depression, phobias and panic disorder. Thus, CB1 agonists or inhibitors of anandamide hydrolysis are expected to exert antidepressant and anxiolytic effects. Future studies should consider 1) the development of CB1 antagonists that cannot readily cross the blood-brain barrier, 2) shifts in the balance of CB1 vs. TRPV1 signalling, 3) the allosteric site of CB1 receptor and 4) the potential involvement of CB2 receptor in mood regulation. Striking similarities in (endo)cannabinoid action in animals and men render it likely that the new pharmacological principle outlined in the present article may find their way into clinical practice.”

http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1516-44462010000500004&lng=en&nrm=iso&tlng=en

Inhibition of endocannabinoid catabolic enzymes elicits anxiolytic-like effects in the marble burying assay

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“Cannabinoids have long been shown to have a range of potential therapeutic effects, including antiemetic actions, analgesia, and anxiolysis. These data indicate that elevation of AEA or 2-AG reduces marble burying behavior and suggest that their catabolic enzymes represent potential targets for the development of new classes of pharmacotherapeutics to treat anxiety-related disorders.

Marijuana is commonly smoked to reduce feelings of stress and anxiety… much interest has been generated by the discovery of the endogenous cannabinoid (i.e. endocannabinoid; eCB) system as a source of targets for the development of new therapeutic treatments of a range of ailments including anxiety and depression…”

http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3034086/

Endocannabinoids and Liver Disease. I. Endocannabinoids and their receptors in the liver

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  “The medicinal properties of cannabis (Cannabis sativa, marijuana) have been known for millennia, as shown by reports from China and India underscoring its analgesic, antiemetic, and appetite-stimulating properties. During the 19th century, the prescription of cannabis gained popularity for a variety of conditions ranging from epilepsy to rheumatism and abdominal symptoms. Concerns about abuse led to discontinuation of therapeutic use in the 1940s. The characterization of marijuana-derived bioactive molecules began during the early 20th century with the identification of several hydrophobic compounds and culminated in 1964 with the isolation of Δ9-tetrahydrocannabinol (THC), the main psychoactive constituent of the plant. Subsequent studies identified over 60 other phytocannabinoids and allowed the synthesis of active analogs with varying potencies. This step was critical in the identification of the endocannabinoid system, comprising specific cannabinoid binding sites (CB1 and CB2), their endogenous ligands (endocannabinoids), and synthetic and degradative pathways.”

“Cannabinoid receptors (CB1 and CB2) and their endogenous ligands (endocannabinoids) have recently emerged as novel mediators of liver diseases. Endogenous activation of CB1 receptors promotes nonalcoholic fatty liver disease (NAFLD) and progression of liver fibrosis associated with chronic liver injury; in addition, CB1 receptors contribute to the pathogenesis of portal hypertension and cirrhotic cardiomyopathy. CB2 receptor-dependent effects are also increasingly characterized, including antifibrogenic effects and regulation of liver inflammation during ischemia-reperfusion and NAFLD. It is likely that the next few years will allow us to delineate whether molecules targeting CB1 and CB2 receptors are useful therapeutic agents for the treatment of chronic liver diseases.”

http://ajpgi.physiology.org/content/294/1/G9.long

Evaluation of oral cannabinoid-containing medications for the management of interferon and ribavirin-induced anorexia, nausea and weight loss in patients treated for chronic hepatitis C virus

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  “The systemic and cognitive side effects of hepatitis C virus (HCV) therapy may be incapacitating, necessitating dose reductions or abandonment of therapy. Oral cannabinoid-containing medications (OCs) ameliorate chemotherapy-induced nausea and vomiting, as well as AIDS wasting syndrome. The efficacy of OCs in managing HCV treatment-related side effects is unknown.”

 

“Although formal studies are lacking, there is anecdotal evidence that cannabis may be beneficial by alleviating common side effects associated with interferon-ribavirin, including anorexia, nausea, weight loss and insomnia. Despite the potential benefits of cannabis, concerns related to the long-term medical complications of inhaled cannabis use and the inability to legally obtain this product limit the use of it as a therapeutic intervention.”

“Oral cannabinoid-containing medications (OCs) have multiple potential therapeutic uses due to their analgesic, antiemetic, anticonvulsant, bronchodilatory and anti-inflammatory effects. They have been shown in clinical trials to ameliorate chemotherapy-induced nausea, to benefit those with AIDS wasting syndrome and to reduce spasticity in multiple sclerosis patients.”

“CONCLUSIONS:

The present retrospective cohort analysis found that OC use is often effective in managing HCV treatment-related symptoms that contribute to weight loss, and may stabilize weight decline once initiated.”

http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2662895/

Therapeutic Potential of Monoacylglycerol Lipase Inhibitors.

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Abstract

 “Marijuana and aspirin have been used for millennia to treat a wide range of maladies including pain and inflammation. Both cannabinoids, like marijuana, that exert anti-inflammatory action through stimulating cannabinoid receptors, and cyclooxygenase (COX) inhibitors, like aspirin, that suppress pro-inflammatory eicosanoid production have shown benefitial outcomes in mouse models of neurodegenerative diseases and cancer. Both cannabinoids and COX inhibitors, however, have untoward effects that discourage their chronic usage, including cognitive deficits and gastrointestinal toxicity, respectively. Recent studies have uncovered that the serine hydrolase monoacylglycerol lipase (MAGL) links the endocannabinoid and eicosanoid systems together through hydrolysis of the endocannabinoid 2-arachidonoylglycerol (2-AG) to provide the major arachidonic acid (AA) precursor pools for pro-inflammatory eicosanoid synthesis in specific tissues. Studies in recent years have shown that MAGL inhibitors elicit anti-nociceptive, anxiolytic, and anti-emetic responses and attenuate precipitated withdrawal symptoms in addiction paradigms through enhancing endocannabinoid signaling. MAGL inhibitors have also been shown to exert anti-inflammatory action in the brain and protect against neurodegeneration through lowering eicosanoid production. In cancer, MAGL inhibitors have been shown to have anti-cancer properties not only through modulating the endocannabinoid-eicosanoid network, but also by controlling fatty acid release for the synthesis of protumorigenic signaling lipids. Thus, MAGL serves as a critical node in simultaneously coordinating multiple lipid signaling pathways in both physiological and disease contexts. This review will discuss the diverse (patho)physiological roles of MAGL and the therapeutic potential of MAGL inhibitors in treating a vast array of complex human diseases.”

http://www.ncbi.nlm.nih.gov/pubmed/23142242

Fungal biotransformation of cannabinoids: potential for new effective drugs.

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Abstract

“Phytocannabinoids from the plant Cannabis sativa induce a variety of physiological and pharmacological responses in living systems, including anti-inflammatory, antinociceptive, anti-ulcer and antitumor activities. The discovery of the cannabinoid receptors CB1 and CB2 led to the development of agonists and antagonists of these receptors for the treatment of a variety of diseases. Nabilone, a synthetic derivative of Delta9-tetrahydrocannabinol (Delta9-THC), which is the main natural psychotropic constituent of C sativa, was approved by the US FDA for the treatment of nausea and as an anti-emetic for patients undergoing chemotherapy. Delta9-THC and related cannabinoids are involved in a variety of signal transduction pathways; thus, reducing or removing the psychotropic effects of these compounds would enhance their therapeutic spectra. Compound synthesis and qualitative SAR studies are time-consuming activities; however, microbes are effectively the most inventive synthetic chemists because of their metabolic plasticity. This review discusses the potential of C sativa mycoflora, which is pathogenic as well as endophytic, to remove the psychotropic effects of Delta9-THC and related cannabinoids, and describes the development of a model system for the rapid and cost-effective commercial production of cannabinoids through fermentation pathways.”

http://www.ncbi.nlm.nih.gov/pubmed/19333876

A molecular basis of the therapeutic and psychoactive properties of cannabis (delta9-tetrahydrocannabinol).

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Abstract

“All of the therapeutic properties of marihuana (analgesic, antiemetic, appetite stimulant, antiglaucoma) have been duplicated by the tetrahydrocannabinol (THC) molecule or its synthetic derivatives. Today, the molecular mechanisms of action of these compounds have led to a general understanding of the pharmacological effects of marihuana and of its therapeutic properties. These mechanisms involve the specific binding of THC to the 7-transmembrane (7TM) domain G protein-linked receptor, a molecular switch which regulates signal transduction in the cell membrane. The natural ligand of the 7TM receptor is an eicosanoid, arachidonylethanolamide (AEA), generated in the membrane and derived from arachidonic acid. THC acts as a substitute ligand to the 7TM receptor site of AEA. THC would deregulate the physiological function of the 7TM receptor and of its ligand AEA. As a result, the therapeutic effects of the drug may not be separated from its adverse psychoactive and cardiovascular effects. The binding of THC to the 7TM receptor site of AEA induces allosteric changes in the receptor sites of neurotransmitter and opiates resulting in variable interactions and pharmacological responses. The pharmacokinetics of THC with its prolonged storage in fat and its slow release result in variable and delayed pharmacological response, which precludes precise dosing to achieve timely therapeutic effects. The experimental use of THC and of its synthetic analogues, agonists, and antagonists has provided novel information in the nature of molecular signaling in the cell membrane. As a result, the relationships between allosteric receptor responsiveness, molecular configuration of proteins, and physiological regulation of cellular and organ function may be further investigated.”

http://www.ncbi.nlm.nih.gov/pubmed/12188105