Tag Archives: Cannabinoids

The cannabinoid 2 receptor agonist β-caryophyllene modulates the inflammatory reaction induced by Mycobacterium bovis BCG by inhibiting neutrophil migration.

Posted on by

“β-Caryophyllene (BCP) is a sesquiterpene that binds to the cannabinoid 2 (CB2) receptor and exerts anti-inflammatory effects. In this study, we investigated the anti-inflammatory effect of BCP and another CB2 agonist, GP1a in inflammatory experimental model induced by Mycobacterium bovis (BCG).

These results suggest that the CB2 receptor may represent a new target for modulating the inflammatory reaction induced by mycobacteria.”

http://www.ncbi.nlm.nih.gov/pubmed/27379721

“β-caryophyllene (BCP) is a common constitute of the essential oils of numerous spice, food plants and major component in Cannabis.”  http://www.ncbi.nlm.nih.gov/pubmed/23138934

Microglia activation states and cannabinoid system: Therapeutic implications.

Posted on by

“Microglial cells are recognized as the brain’s intrinsic immune cells, mediating actions that range from the protection against harmful conditions that modify CNS homeostasis, to the control of proliferation and differentiation of neurons and their synaptic pruning. To perform these functions, microglia adopts different activation states, the so-called phenotypes that depending on the local environment involve them in neuroinflammation, tissue repair and even the resolution of the inflammatory process.

There is accumulating evidence indicating that cannabinoids (CBs) might serve as a promising tool to modify the outcome of inflammation, especially by influencing microglial activity.

Microglia has a functional endocannabinoid (eCB) signaling system, composed of cannabinoid receptors and the complete machinery for the synthesis and degradation of eCBs.

The expression of cannabinoid receptors – mainly CB2 – and the production of eCBs have been related to the activation profile of these cells and therefore, the microglial phenotype, emerging as one of the mechanisms by which microglia becomes alternatively activated.

Here, we will discuss recent studies that provide new insights into the role of CBs and their endogenous counterparts in defining the profile of microglia activation.

These actions make CBs a promising therapeutic tool to avoid the detrimental effects of inflammation and possibly paving the way to target microglia in order to generate a reparative milieu in neurodegenerative diseases.”

http://www.ncbi.nlm.nih.gov/pubmed/27373505

Researcher explores effects of cannabinoids on blood pressure

Posted on by

Andrei Derbenev, associate professor of physiology, Tulane School of Medicine

“Hypertension — or high blood pressure — is a long-term, high-risk condition for millions of people worldwide.

At the moment, synthetic beta-blockers are one of the most common drugs prescribed to treat hypertension.

But what if a natural drug, marijuana, which has been known for 5,000 years, could be used in the treatment of high blood pressure?

Andrei Derbenev, associate professor of physiology in the Tulane University School of Medicine, recently received a four-year, $1.5 million research grant from the National Institutes of Health to study how cannabinoids — the compounds of cannabis (another name for marijuana) — affect a brain stem area involved in blood pressure control.

His research may have important clinical applications for the treatment of hypertension.

He is identifying the cells in the sympathetic nervous system linked to the kidneys, a key organ in hypertension. (The sympathetic nervous system is the part of the autonomic nervous system that stimulates the body’s “fight or flight” response. Overactivity of the sympathetic nervous system is a cause of high blood pressure.)

He and his research team are studying the effect of exogenous cannabinoids — from the marijuana plant — and endogenous cannabinoids —those naturally produced within the body.

Cannabis “has lots of different chemicals inside. Some of them are painkillers. Some of them, we don’t know what they are doing.”

People ask Derbenev all the time: Is marijuana good? Is it bad? But the debate, he says, should be, instead, “Which works? Which does not work?”

About a decade ago, Derbenev led a study about the effect of cannabinoids on the parasympathetic nervous system, the part of the autonomic nervous system that stimulates the body to “rest and digest.” In that investigation, his team showed the mechanism by which cannabis can reduce digestive spasms and thus decrease vomiting. It’s a finding of great interest to cancer patients experiencing nausea while undergoing chemotherapy.”

https://news.tulane.edu/news/researcher-explores-effects-cannabinoids-blood-pressure

Endocannabionoid System in Neurological Disorders.

Posted on by

“Several studies support the evidence that the endocannabinoid system and cannabimimetic drugs might have therapeutic potential in numerous pathologies. These pathologies range from neurological disorders, atherosclerosis, stroke, cancer to obesity/metabolic syndrome and others.

In this paper we review the endocannabinoid system signaling and its alteration in neurodegenerative disorders like multiple sclerosis, Alzheimer’s disease, Parkinson’s disease and Huntington’s disease and discuss the main findings about the use of cannabinoids in the therapy of these pathologies.

Despite different etiologies, neurodegenerative disorders exhibit similar mechanisms like neuro-inflammation, excitotoxicity, deregulation of intercellular communication, mitochondrial dysfunction and disruption of brain tissue homeostasis.

Current treatments ameliorate the symptoms but are not curative.

Interfering with the endocannabinoid signaling might be a valid therapeutic option in neuro-degeneration.

To this aim, pharmacological intervention to modulate the endocannabinoid system and the use of natural and synthetic cannabimimetic drugs have been assessed. CB1 and CB2 receptor signaling contributes to the control of Ca2+ homeostasis, trophic support, mitochondrial activity, and inflammatory conditions.

Several studies and patents suggest that the endocannabinoid system has neuro-protective properties and might be a target in neurodegenerative diseases.”

http://www.ncbi.nlm.nih.gov/pubmed/27364363

Marijuana fights Alzheimer’s disease, Salk Institute scientists discover

Posted on by

Cannabinoids remove plaque-forming Alzheimer's proteins from brain cells

“Salk Institute scientists have discovered that a main compound found in marijuana can fight a toxic protein associated with Alzheimer’s disease. According to the scientists, at this time, there are no drugs that significantly inhibit cell death associated with Alzheimer’s disease (AD), Parkinson’s or Huntington’s diseases. However, the most recent data about Alzheimer’s and marijuana suggests that there is a therapeutic potential of cannabinoids (the chemical compounds secreted by cannabis flowers) for the treatment of AD. Cannabinoids are able to remove plaque-forming Alzheimer’s proteins from brain cells, reports the Medical Express on June 29.”  http://www.examiner.com/article/marijuana-fights-alzheimer-s-disease-salk-institute-scientists-discover

“Cannabinoids remove plaque-forming Alzheimer’s proteins from brain cells”  http://medicalxpress.com/news/2016-06-cannabinoids-plaque-forming-alzheimer-proteins-brain.html

“Cannabinoids remove toxic proteins associated with Alzheimer’s disease from the brain” http://www.irishexaminer.com/examviral/science-world/cannabinoids-remove-toxic-proteins-associated-with-alzheimers-disease-from-the-brain-407788.html

“Marijuana Compound Helps Remove Alzheimer’s Disease Protein From Brain” -brain.” http://www.scienceworldreport.com/articles/42990/20160630/marijuana-compound-helps-remove-alzheimers-disease-protein-from-brain.htm

“Marijuana compound removes toxic Alzheimer’s protein from the brain”  http://www.sciencealert.com/marijuana-compound-removes-toxic-alzheimer-s-protein-from-the-brain

“Cannabinoids remove plaque-forming Alzheimer’s proteins from brain cells”  https://www.sciencedaily.com/releases/2016/06/160629095609.htm

“Cannabinoids Remove Plaque-forming Alzheimer’s Proteins from Brain Cells”  https://www.laboratoryequipment.com/news/2016/06/cannabinoids-remove-plaque-forming-alzheimers-proteins-brain-cells

“MARIJUANA COMPOUND REMOVES ALZHEIMER’S PLAQUE FROM BRAIN CELLS, STUDY FINDS” http://www.popsci.com/marijuana-compound-removes-alzheimers-plaque-from-brain-cells-study

“Cannabinoids remove plaque-forming Alzheimer’s proteins from brain cells. Preliminary lab studies at the Salk Institute find THC reduces beta amyloid proteins in human neurons.” http://www.salk.edu/news-release/cannabinoids-remove-plaque-forming-alzheimers-proteins-from-brain-cells/

 

Amyloid proteotoxicity initiates an inflammatory response blocked by cannabinoids

Posted on by

“The beta amyloid (Aβ) and other aggregating proteins in the brain increase with age and are frequently found within neurons. The mechanistic relationship between intracellular amyloid, aging and neurodegeneration is not, however, well understood.

We use a proteotoxicity model based upon the inducible expression of Aβ in a human central nervous system nerve cell line to characterize a distinct form of nerve cell death caused by intracellular Aβ.

It is shown that intracellular Aβ initiates a toxic inflammatory response leading to the cell’s demise. Aβ induces the expression of multiple proinflammatory genes and an increase in both arachidonic acid and eicosanoids, including prostaglandins that are neuroprotective and leukotrienes that potentiate death.

Cannabinoids such as tetrahydrocannabinol stimulate the removal of intraneuronal Aβ, block the inflammatory response, and are protective.

Altogether these data show that there is a complex and likely autocatalytic inflammatory response within nerve cells caused by the accumulation of intracellular Aβ, and that this early form of proteotoxicity can be blocked by the activation of cannabinoid receptors.”

http://www.nature.com/articles/npjamd201612

“Cannabinoids remove plaque-forming Alzheimer’s proteins from brain cells. Preliminary lab studies at the Salk Institute find THC reduces beta amyloid proteins in human neurons.” http://www.salk.edu/news-release/cannabinoids-remove-plaque-forming-alzheimers-proteins-from-brain-cells/

Expression of the endocannabinoid receptors in human fascial tissue.

Posted on by

“Cannabinoid receptors have been localized in the central and peripheral nervous system as well as on cells of the immune system, but recent studies on animal tissue gave evidence for the presence of cannabinoid receptors in different types of tissues.

Their presence was supposed also in myofascial tissue, suggesting that the endocannabinoid system may help resolve myofascial trigger points and relieve symptoms of fibromyalgia.

However, until now the expression of CB1 (cannabinoid receptor 1) and CB2 (cannabinoid receptor 2) in fasciae has not yet been established.

Small samples of fascia were collected from volunteers patients during orthopedic surgery. For each sample were done a cell isolation, immunohistochemical investigation (CB1 and CB2 antibodies) and real time RT-PCR to detect the expression of CB1 and CB2.

Both cannabinoid receptors are expressed in human fascia and in human fascial fibroblasts culture cells, although to a lesser extent than the control gene. We can assume that the expression of mRNA and protein of CB1 and CB2 receptors in fascial tissue are concentrated into the fibroblasts.

This is the first demonstration that the fibroblasts of the muscular fasciae express CB1 and CB2. The presence of these receptors could help to provide a description of cannabinoid receptors distribution and to better explain the role of fasciae as pain generator and the efficacy of some fascial treatments.

Indeed the endocannabinoid receptors of fascial fibroblasts can contribute to modulate the fascial fibrosis and inflammation.”

http://www.ncbi.nlm.nih.gov/pubmed/27349320

Cannabinoids and Neuro-Inflammation: Regulation of Brain Immune Response.

Posted on by

“Cannabinoid receptors are involved in neurophatogenic mechanisms of inflammatory disorders of the central nervous system and their expression can be modulated during the disease.

Brain inflammatory processes are characterized by infiltration of numerous types of cells, peripheral immune cells, brain resident immune cells, the microglial cells and numerous other neuronal cells. The disruption of the blood brain barrier favours cell infiltration in the central nervous system with consequent neuronal damage, common event in many neuro-inflammatory diseases.

In this review we evidence the role of cannabinoid receptor, their expression at peripheral and central levels in order to better understand their implication in neuro-inflammation.

Cannabinoids affect brain adaptive and immune response, have regulatory action on inflammatory mediators and can exert a role in blood brain barrier damage prevention.

Furthermore, in numerous neurodegenerative diseases with inflammatory component the beneficial effects of cannabinoids have been widely reported, so current knowledge of cannabinoid involvement in these central nervous system disorders are also reviewed.”

http://www.ncbi.nlm.nih.gov/pubmed/27334610

Cannabimimetic Drugs: Recent Patents in Central Nervous System Disorders.

Posted on by

“Agents acting via cannabinoid receptors have been widely developed; starting from the chemical structure of phytocannabinoids isolated from cannabis sativa plant, specific and selective compounds of these receptors have been produced ranging from partial to full agonists and /or antagonists endowed with different potency.

The enhanced interest on developing such classes of drugs is due to the beneficial properties widely reported by both anecdotal reports and scientific studies describing the potential medicinal use of cannabinoids and their derivatives in numerous pathological conditions in both in vitro and in vivo models.

The use of these drugs has been found to be of benefit in a wide number of neurological and neuropsychiatric disorders, and in many other diseases ranging from cancer, atherosclerosis, stroke, hypertension, inflammatory related disorders, and autoimmune diseases, just to mention some.

In particular, being the cannabinoid CB1 receptor a central receptor expressed by neurons of the central nervous system, the attention for the treatment of neurological diseases has been mainly focused on compounds acting via this receptor, however some of these compounds has been showed to act by alternative pathways in some cases unrelated to CB1 receptors.

Nonetheless, endocannabinoids are potent regulators of the synaptic function in the central nervous system and their levels are modulated in neurological diseases.

In this study, we focused on endocannabinoid mechanism of action in neuronal signaling and on cannabimimetic drug potential application in neurological disorders.

Finally, novel patents on cannabis-based drugs with applicability in central nervous system disorders are highlighted, to suggest future potential therapeutic utility of derivatives of this ancient plant.”

http://www.ncbi.nlm.nih.gov/pubmed/27334611

Harnessing the Endocannabinoid 2-Arachidonoylglycerol to Lower Intraocular Pressure in a Murine Model.

Posted on by

“Cannabinoids, such as Δ9-THC, act through an endogenous signaling system in the vertebrate eye that reduces IOP via CB1 receptors.

Endogenous cannabinoid (eCB) ligand, 2-arachidonoyl glycerol (2-AG), likewise activates CB1 and is metabolized by monoacylglycerol lipase (MAGL). We investigated ocular 2-AG and its regulation by MAGL and the therapeutic potential of harnessing eCBs to lower IOP.

Our data confirm a central role for MAGL in metabolism of ocular 2-AG and related lipid species, and that endogenous 2-AG can be harnessed to reduce IOP. The MAGL blocker KML29 has promise as a therapeutic agent, while JZL184 may have difficulty crossing the cornea.

These data, combined with the relative specificity of MAGL for ocular monoacylglycerols and the lack of desensitization in MAGL-/- mice, suggest that the development of an optimized MAGL blocker offers therapeutic potential for treatment of elevated IOP.”

http://www.ncbi.nlm.nih.gov/pubmed/27333182