Category: Biotechnology

Biotechnological applications for extracting cannabinoid compounds

 

Previously in my blog, I explained how the biotechnological industry has adapted its expertise to cannabinoid research, development and application. I would like to now dive deeper into how biotechnological devices have shaped cannabinoids, as biotechnology does not just refer to an industry, but also the medical devices, techniques and processes used in pharmaceuticals. These applications are vital for effective research and down-stream production of many drugs now used in modern medicine.

Process of manufacture

In order to develop Epidolex®, a CBD purified drug; scientists have to separate out many compounds found in the plant until they are left with the desired product. This journey of filtration can become very difficult as biological compounds, including cannabinoids, rarely adapt to undesirable environments causing them to denature or become inactive, and hence medically useless most of the time. The processes have to, therefore, be very sensitive, and capable to work exactly inline with the compounds optimum condition including temperate, acidity and conductivity.

Initially, before the compounds can be extracted from the crop, the plant is processed into a liquid form. This can be done by simply ‘blending’ down the solid plant to create a mixture, which is much easier to work with. After achieving this ‘cannabis mixture’, it can be processed through different flirtation techniques, the main three being:

Centrifugation.
Centrifugation involves the separation of compounds based on their size, shape, density and viscosity by spinning down the solution at high speeds. This motion generates a centrifugal force, which causes heavier compounds to subside at the bottom of the centrifugal bowl, whilst smaller, less dense molecules remain on top in solution. This process referred to as preparative centrifugation, is very effective because it tends to remove a large majority of unwanted compounds from the mixture, leaving a less dense liquid solution containing proteins, biomolecules and other smaller compounds. In later processing stages, it can become more difficult to separate smaller compounds. Scientists are therefore able to apply a membrane into the centrifugal bowl, which is capable of capturing certain compounds, whilst other unwanted compounds of similar density pass through. Here, compounds may be separated due to affinity to a particular compound, which is added to the bulk prior to centrifugation.

Centrifuge
Centrifuge – Picture has not been created by the author but taken from an external source.

Chromatography.
Another separation technique abundantly used in downstream pharmaceutical production is chromatography, in particular, High-performance liquid chromatography (HPLC). The theory behind this process is that for example, the solution with the CBD and other bioproducts are mixed with a mobile phase solution, which is then run through a chromatography column that holds a stationary phase. The properties of the stationary phase differ as some will separate molecules depending on molecular mass (size-exclusion chromatography) whilst others on their molecular charges (ion-exchange chromatography). In theory, however, the desired compounds are held up within the stationary phase, whilst the mobile phase passes through the column into waste with some of the unwanted products. At times, unwanted bio-compounds may be bound to the desired compound (CBD) and therefore buffers are run through the column, to slowly remove these unwanted. Lastly, to remove the desired compound from the stationary phase, an elution buffer is run through and what leaves the column is collected as it contains the CBD.

Bioproduct production firms tend to use a Mass-spectroscopy (MS) meter to measure the properties (usually conductivity) of the column outlet to help determine the composition of the existing solution. This combination of MS and chromatography is very desirable in downstream production due to the high specificity it produces, compared to other chromatographic detectors.

chromotography
Chromatography column with Mass Spec – Picture has not been created by the author but taken from an external source.

Filtration and ultra-filtration.
The simplest of these techniques is filtration which involves passing the liquid through a membrane-bound filter. In theory, the solution passes through a membrane, leaving any undesired compounds behind. Ultra-filtration works in the same manner but uses hydrostatic pressure to remove much finer particles from the solution. This device is abundantly used in pharmaceutical production at end stages of product filtration as it removes very small particles, including suspended bacteria, viruses and salts. This helps to ensure the CBD product produced does not hold contaminants that can make the drug harmful.

Ultra-filtration
Ultra-filtration – Picture has not been created by the author but taken from an external source.

So now, (as long as I haven’t lost you) you should have an idea of how biotechnological instruments have been applied to the manufacture of purified CBD. I have only mentioned some of the most commonly used devices, yet there is many more involved in pharmaceutical production. Without them, scientists would struggle to derive molecular compounds so efficiently… it would really be like finding a needle in a haystack… actually, that’s an understatement of the complexity. So regardless of the efforts to develop this process, and therefore Epidolex®, GW Pharmaceuticals struggled for years to gain FDA approval. My next blog will look into the process that Epidolex® had to overcome in order to finally gain this ‘medicinal’ recognition.

The biotech industries interest in Cannabinoids?

From a drug of almost global illegality to a multibillion-dollar industry, cannabis has significantly progressed in the last two decades. This gradual movement caught the interest of many science-based industries to boost this market by tailoring their services towards cannabinoid research and production. One, that became a crucial part of this market was the biotechnology industry which focussed on prospecting the field of cannabinoids in society. Their main areas of interest revolve around the discovery of new health benefits from active bioproducts and, the introduction of improved methods of delivering these compounds into the human system. Consequently, this alliance of industries has led to efforts and advancements in tackling medical disorders, some of which were incurable before.

This blog will, therefore, concentrate on a few biotech companies which have or are believed to cause a great impact on the development of medical cannabinoid products. Many difficult terms will be used too so bear with me, I’ve hyperlinked most of them to help you understand what I’m on about!

biotek

Cannabis takes over the biotech industry

Many companies have seen an opportunity to adapt their research, expertise or patented products in the cannabis market whilst others have invested in researching the plant since their establishment. For example, GW Pharmaceuticals was established in 1998 with the aim to research and develop cannabinoid-derived medication. They focused heavily on clinical trials, drug development and regulatory allowances but for years struggled to commercialise their medication because of the strict law surrounding cannabis. Fortunately, their research and trails were so extensive that they overcame regulatory clearance and became the first in the world to distribute cannabinoid-based medicine.

As mentioned, specialist biotechnology businesses found a profitable opportunity in the cannabis market and tailored their expertise towards its development. 22nd Century Group is one of these companies. The plant biotech firm originally focused on bioengineering of tobacco plants to lower the level of ‘harmful’ compounds like nicotine when smoked. The same problem is present when smoking cannabis as some compounds (e.g. CBD) are more desired in medicine than others (e.g. THC). Therefore, bioengineering of new cannabis strains which contain more of the desired compounds can support cannabinoid production companies like GW Pharmaceuticals. This can be through means of increasing yield and potency of the desired compounds but also improving the flow of the manufacturing process by lowering filtration steps needs to remove unwanted compounds.

Let’s jump back onto the topic of smoking as historically this was, and still is the main method of getting cannabis compounds into the human system. You do not have to be a doctor however to know that smoking in general, is a massive contributor to cardiovascular, pulmonary and cancerous diseases along with other difficulties. It shouldn’t, therefore, be a surprise that some biotechnological companies have recently been researching improved methods through which cannabinoid-derived medication can be consumed and absorbed. Lexaria Biosciences, for example, has developed the DehydraTECH™ technology which can be applied to bio-active compounds (including cannabinoids) which would otherwise be poorly absorbed by our stomachs. This technology is out-licensed to many pharmaceutical companies to improve the drugs taste and increase the rate of absorption, which in turn lowers the required dose needed for desired effects from the drug.

So, to sum things up, the biotech industry already has, and will continue to boost the development of the cannabis industry. They do this by directly impacting the properties of the drug or indirectly by research and making the public and government more aware of the medical benefits and more accepting of what it really is… just a plant with much medicinal potential. To top everything off, the recent involvement of the biotech industry (as well as other industries, e.g. medical, agricultural) in cannabinoids have really brought massive investments into cannabis in general, supplying scientists a whole load of funding to focus research more on the plant’s medical benefits.

biotechnology

In my next blog, I will dive deeper into the analytical techniques hugely used in cannabinoid research, as well as mass manufacture. I will aim to help you all understand the complexity evolving these techniques.. purely because filtration refers to much more than just using a sieve to separate ‘water from sand’ (surely we all did this practical in primary school?). Above that, I’m sure you’ll find it interesting to learn scientists are able to achieve a pure compound from such a complex plant structure!