"The stem cell of cannabis"
Cannabigerolic acid is one of the many phytocannabinoids within the cannabis plant. Many phytocannabinoids have acidic precursors.
To recap really quickly, these acidic precursors
turn into a subsequent cannabinoid through a process known as decarboxylation.
Decarboxylation happens through various forms of heat application and is a fancy science word for when something loses a molecule of carbon dioxide. This heat application can include solar heat or directly applied heat as with cooking or smoking.
But what makes cannabigerolic acid (CBGa) so special? Is it not just another acidic precursor? Aside from being a precursor for cannabigerol, it is also the precursor for a handful of other acidic precursors including THCA, CBDA and CBCA. It is crucial in creating common cannabinoids like CBC and THC. This is why some cannabis enthusiasts refer to it as the “stem cell” of cannabis, given its transformative nature.Cannabigerolic acid is one of the many phytocannabinoids within the cannabis plant. Many phytocannabinoids have acidic precursors.
To recap really quickly, these acidic precursors
turn into a subsequent cannabinoid through a process known as decarboxylation.
Decarboxylation happens through various forms of heat application and is a fancy science word for when something loses a molecule of carbon dioxide. This heat application can include solar heat or directly applied heat as with cooking or smoking.
The Discovery of CBGa
Cannabigerolic acid has been shown to be the first biogenic cannabinoid formed in the plant. Cannabigerol was discovered in 1964 by Gaoni and Mechoulam; Mechoulam is also accredited with being the first to elucidate the correct structure of CBD in 1963, according to “Chemistry and Analysis of Phytocannabinoids and Other Cannabis Constituents” by Rudolf Brenneisen. It was found that CBG does not induce psychotropic effects, unlike THC.
The Biosynthetic Pathway of CBGa
Even though CBGa is primary for the creation of other cannabinoids, its own road to synthesis is longer than you would think. According to an article published in the Frontiers in Plant Science, CBGa is actually formed through about five or six other prior chemical and catalyzing reactions. From there, “Three oxidocyclases will then be responsible for the diversity of cannabinoids: the THCA synthase (THCAS) converts CBGA to THCA, while CBDA synthase (CBDAS) forms CBDA and CBCA synthase (CBCAS) produces CBCA.”
CBGA Itself Has Not Been Heavily Studied for Pharmacological Effects.
CBGA Itself Has Not Been Heavily Studied for Pharmacological Effects.
According to Halent Laboratories, cannabigerolic acid may have analgesic and antibacterial effects. But most studies have a lot more to say about cannabigerol than they do about its acidic precursor, CBGa. For example, cannabigerol’s mode of operation regarding CB receptors has been investigated. It is known that cannabigerol has a higher affinity for CB1 than it does for CB2. But binding to CB1 receptors was only detectable at concentrations above those at which it stimulates binding to the brain membranes.
According to a cannabinoid profile by Medical Jane, “Testing of industrial hemp has found much higher levels of cannabigerol (CBG) than most strains of cannabis. Further studies have shown that this phenomenon may be due to a recessive gene. It is believed that the gene keeps the plant from producing one of the cannabinoid synthases (what converts CBGA to one of the major branches).”
Little Chemistry...
Little Chemistry...
According to an abstract published by the European Bioinformatics Institute, cannabigerolic acid is a “dihydroxybenzoic acid that is olivetolic acid in which the hydrogen at position 3 is substituted by a geranyl group...”
Ok...well, what the heck is that?
In chemistry, the names for things tell us what chemical constituents those things are composed of. In this case, “dihydroxy” means that there are two (di) occurrences of “hydroxide,” which is just oxygen and hydrogen bonded together. This is then linked onto benzoic acid, which by itself is known to be used in many products, especially cosmetics.
Altogether, this dihydroxybenzoic acid is a type of phenolic acid. What is a phenolic acid? Well, according to Ray Sahelian, M.D., “Phenolic acids are plant metabolites widely spread throughout the plant kingdom. Recent interest in phenolic acids stems from their potential protective role, through ingestion of fruits and vegetables, against oxidative damage diseases (coronary heart disease, stroke, and cancers).
Phenolic compounds are essential for the growth and reproduction of plants, and are produced as a response for defending injured plants against pathogens. The importance of antioxidant activities of phenolic compounds and their possible usage in processed foods as a natural antioxidant have reached a new high in recent years.”
The Application of CBGa
Ok...well, what the heck is that?
In chemistry, the names for things tell us what chemical constituents those things are composed of. In this case, “dihydroxy” means that there are two (di) occurrences of “hydroxide,” which is just oxygen and hydrogen bonded together. This is then linked onto benzoic acid, which by itself is known to be used in many products, especially cosmetics.
Altogether, this dihydroxybenzoic acid is a type of phenolic acid. What is a phenolic acid? Well, according to Ray Sahelian, M.D., “Phenolic acids are plant metabolites widely spread throughout the plant kingdom. Recent interest in phenolic acids stems from their potential protective role, through ingestion of fruits and vegetables, against oxidative damage diseases (coronary heart disease, stroke, and cancers).
Phenolic compounds are essential for the growth and reproduction of plants, and are produced as a response for defending injured plants against pathogens. The importance of antioxidant activities of phenolic compounds and their possible usage in processed foods as a natural antioxidant have reached a new high in recent years.”
The Application of CBGa
In the future, as more dispensaries pop up, and more growers produce custom strains of cannabis, cannabigerolic acid might play an increasing role in bio-engineering. If cannabigerolic acid can be manipulated properly, it can influence the yielded content of CBD, THC, CBN or CBC in your cannabis plant. This will become increasingly important when the varying applications of different phytocannabinoids become more known and demand for specific strains increases.
In Conclusion…
In Conclusion…
Much remains to be said about CBGa, but current studies are working to figure out exactly how CBGa influences the production of THCA and CBDA – specifically how it varies and what influences the output. There is a wide area of research dedicated to both THC and CBD.
CBGa will be important as it is the crucial ingredient for having high-CBD in the first place. If it can be manipulated for bioengineering, creating high-CBD products will become even easier.
CBGa will be important as it is the crucial ingredient for having high-CBD in the first place. If it can be manipulated for bioengineering, creating high-CBD products will become even easier.
- CBGA is the precursor to THCA, CBDA, CBCA…and other acid precursors.
- It is the main phytocannabinoid that allows other cannabinoids to chemically exist.
- It is a type of phenolic acid.
- It is synthesized from five other prior chemical reactions.
- It turns into acid synthases via decarboxylization.
- It is a precursor for CBG (cannabigerol), which is the subject of an array of pharmacological studies.
- It was shown to be the first biogenic cannabinoid formed in the plant Cannabis Sativa.
- It requires greater study.
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