Decarboxylation

Decarboxylation

All of the cannabinoids contained in raw cannabis flowers have an extra carboxyl ring or group (COOH) attached to their chain. Decarboxylation is the chemical reaction that removes a carboxyl group and releases carbon dioxide. By removing the carboxyl group, the main cannabinoids of interest, THC and CBD, become “activated” and ready to deliver the desired medicinal properties of cannabis to the final product.

The chemistry is important to understand as CBD and THC are not found in the raw bud. Rather the acidic forms of the cannabinoids, known as CBDA and THCA, exist in the plant. In their natural state, THCA and CBDA have different medical properties.

What are the key elements of decarboxylation? Heat or light. Cannabinoids are converted into their neutral forms upon heating or exposure to light. Depending upon the end product, processors may choose to decarboxylate cannabis plant material before or after the extraction.

Pre-Extraction Decarboxylation

Decarboxylation prior to extraction has several advantages. It is well documented that moisture content in the plant can have a negative impact on extraction yields. Water makes extractions slower and less efficient by interacting with the solvent and affecting flow during the process. Heating the material prior to the extraction removes water from the plant and increases extraction efficiency. Furthermore, neutral THC and CBD are more soluble than the acidic THCA and CBDA, making the extraction with non-polar solvents more effective at capturing cannabinoids and increasing extraction yield.

Pre-Extraction Decarboxylation References

Perrotin-Brunel H., Buijs W., van Spronsen J., van Roosmalen M.J.E., et.al., Decarboxylation of Δ9-tetrahydrocannabinol: Kinetics and molecular Modeling, J. of Molecular Structure, 987 (2011) 67-73.

Post-Extraction Decarboxylation

Decarboxylation post-extraction requires the same precise level of control of time and temperature parameters as for the pre-extraction procedure. Post-extraction decarboxylation has disadvantages as well. Decarboxylation requires control of high temperatures over extended time periods. Degradation of total cannabinoids can occur if material is heated for too long or at too high of a temperature. When performed over too short of a time period at too low of a temperature, precursor cannabinoids will not decarboxylate. The optimum time and temperature parameters for decarboxylation are important. An entire batch of oil will tend to stay at certain temperatures during phase changes. This makes it difficult to get the oil to the required temperature for decarboxylation to occur and control that temperature over long periods of time. An oil with more solvent or terpenes will take a longer amount of time to reach a certain temperature.

Because the composition of the cannabinoids and terpenes can be affected, it is important for the plant materials to be tested before and after the decarboxylation to determine the impact on the properties of the material.

Decarboxylation without destroying valuable cannabinoids and terpenes is a precise process. There have been many studies performed on the impact of decarboxylation both prior- and post- extraction procedures and I highly recommend to read them and determine the optimum method for your operations.

Post-Extraction Decarboxylation References

Wang M., Wang Y-H., Avula B., Radwan M., et.al., Decarboxylation Study of Acidic Cannabinoids: A Novel Approach Using Ultra-High-Performance Supercritical Fluid Chromatography/Photodiode Array-Mass Spectrometry, Cannabis and Cannabinoid Research, Volume1.1, 2016.
Cinzia C., Pacchetti B., Vandelli M.A., Forni F., and Cannazza G., Analysis of cannabinoids commercial hemp seed oil and decarboxylation kinetics studies of cannabidiolic acid (CBDA), J. of Pharmaceutical and Biomedical Analysis, 149 (2018) 532-540.
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