In a press release published this week, AOAC International announced it has partnered with Signature Science, LLC as the test material provider for the new AOAC Cannabis/Hemp Proficiency Testing program. What makes this proficiency testing (PT) program so unique is that AOAC will be the only PT provider to offer actual cannabis flower as the matrix.
This month, the pilot round with twenty cannabis testing labs begins with hemp-only samples being shipped in early May. The first live round of the PT program is scheduled for November of this year and will offer participating labs the choice of cannabis flower samples or hemp samples.
The program will include one sample for cannabinoid and terpene profiles, moisture and heavy metals, as well as a second sample for pesticide residue testing. According to the press release, mycotoxins will be added to the mix soon.
The new PT program was developed by stakeholders involved with the AOAC Cannabis Analytical Science Program (CASP), including state regulatory labs, industry labs, state and federal agencies and accreditation bodies. Shane Flynn, senior director of AOAC’s PT program, says the program is a result of scientists coming to them with concerns about testing in the cannabis space. “AOAC has a long history of bringing scientists together to address emerging topics, so when stakeholders came to AOAC with their concerns and need for quality proficiency testing in the cannabis industry, AOAC acted,” says Flynn. “Stakeholders noted the analytical differences in testing cannabis versus hemp and had specific concerns around it and asked for a program that would provide actual cannabis samples in addition to hemp. This is truly a program that was created by the stakeholders, for the stakeholders.”
AOAC says they plan on introducing microbiology to the PT program, with microbial contamination tests in both cannabis and hemp samples. They are also considering adding additional matrices, like chocolate and gummies.
Signature Science is an ISO 17043 accredited proficiency test provider that also has a DEA-licensed controlled substances lab, making them an ideal candidate to partner with AOAC for the PT Program. They entered into a 3-year MoU with AOAC for the program. Their team developed and validated methods used to create the samples for the PT program at their DEA-licensed lab in Austin, Texas.
The cannabis industry is growing and evolving at an unprecedented pace and regulators, consumers and businesses continually struggle to keep up.
Cannabis businesses: How do you maintain an edge on the market, avoid costly mistakes?
Case Study: Costly Facility Build Out Oversights
David Vaillencourt will be joining a panel discussion, Integrated Lifecycle of Designing a Cultivation Operation, on December 22 during the Cannabis Quality Virtual Conference. Click here to register. A vertically integrated multi-state operator wants to produce edibles. The state requires adherence to food safety practices (side note – even if the state did not, adherence to food safety practices should be considered as a major facility and operational requirement). They are already successfully producing flower, tinctures and other oil derivatives. Their architect and MEP firm works with them to design a commercial kitchen for the production of safe edibles. The layout is confirmed, the equipment is specified – everything from storage racks, an oven and exhaust hoods, to food-grade tables. The concrete is poured and walls are constructed. The local health authority comes in to inspect the construction progress, who happens to have a background in industrial food-grade facilities (think General Mills). They remind the company that they must have three-compartment sinks with hot running water for effective cleaning and sanitation, known as clean-out-of-place (COP). The result? Partial demolition of the floor to run pipeline, and a retrofit to make room for the larger sinks, including redoing electrical work and a contentious team debate about the size of the existing equipment that was designed to fit ‘just right.’
Unfortunately, this is just one more common story our team recently witnessed. In this article, I outline a few recommendations and a process (Quality by Design) that could have reduced this and many other issues. For some, following the process may just be the difference between being profitable or going out of business in 2021.
The benefits of Quality by Design are tangible and measurable:
Reduce mistakes that lead to costly re-work
Mitigate inefficient operational flow
Reduce the risk of cross-contamination and product mix-ups. It happens all the time without carefully laid out processes.
Eliminate bottlenecks in your production process
Mitigate the risk of a major recall.
The solution is in the process
Regardless of whether you fall in the category of a food producer, manufacturer of infused products (MIP), food producers, re-packager or even a cultivator, consider the following and ask these questions as a team.
For every process, who is performing it? This may be a single individual or the role of specific people as defined in a job description.
Does the individual(s) performing the process have sufficient education and training? Do you have a diverse team that can provide different perspectives? World class operations are not developed in a vacuum, but rather with a team. Encourage healthy discourse and dialogue.
Is the process defined? Perhaps in a standard operating procedure (SOP) or work instruction (WI). This is not the general guidance an equipment vendor provided you with, this is your process.
How well do you know your process? Does your SOP or WI specify (with numbers) how long to run the piece of equipment, the specification of the raw materials used (or not used) during the process, and what defines a successful output?
Do you have a system in place for when things deviate from the process? Processes are not foolproof. Do not get hung up on deviations from the process, but don’t turn a blind eye to them. Record and monitor them. In time, they will show you clear opportunities for improvement, preventing major catastrophes.
What are the raw materials being used? Where are they coming from (who is your supplier and how did you qualify them)?
Start with the raw materials that create your product or touch your product at all stages of the process. We have seen many cases where cannabis oils fail for heavy metals, specifically lead. Extractors are quick to blame the cultivator and their nutrients, as cannabis is a very effective phytoremediator (it uptakes heavy metals and toxins from soil substrate). The more likely culprit – your glassware! Storing cannabis oil, both work in process or final product in glass jars, while preferred over plastic, requires due diligence on the provider of your glassware. If they change the factory in which it is produced, will you be notified? Stipulate this in your contract. Don’t find yourself in the next cannabis lead recall that gets the attention of the FDA.
Savings is gained through simple control of your raw materials. Variability in your raw material going into the extractor is inevitable, but the more you can do to standardize the quality of your inputs, the less work re-formulating needs to be done downstream. Eliminate the constant need to troubleshoot why yields are lower than expected, or worst case, having to rerun or throw an entire batch out because it was “hot” (either too much THC in the hemp/CBD space or pesticides/heavy metals). These all add up to significant downstream bottlenecks – underutilized equipment, inefficient staff (increase in labor cost) all because of a lack of upstream controls. Use your current process as a starting point, but implement a quality system to drive improvement in operational efficiency and watch your top line grow while your bottom-line decreases.
Have you tested and confirmed the quality of your raw material? This isn’t just does it have THC and is it cannabis, but is it a certain particle size, moisture level, etc.? Again, define the quality of your raw materials (specifications) and test for it.
Remember – ranges are your friend. It is much better to say 9-13% moisture than “about 10%”. For your most diligent extractor, 11% will be unacceptable, but for a guy that just wants to get the job done, 13% just may do!
Test your final product AFTER the process. Again, how does it stack up against your specifications? You may need to have multiple specifications based on different types of raw material. Perhaps one strain with a certain range of cannabinoids and terpenes can be expected for production.
Review the data and trend it. Are you getting lower yields than normal? This may be due to an issue with the equipment, maybe a blockage has formed somewhere, a valve is loose, and simple preventive maintenance will get you back up and running. Or, it could be that the raw biomass quality has changed. Either way, having that data available for review and analysis will allow you to identify the root cause and prevent a surprise failure of your equipment. Murphy’s law applies to the cannabis industry too.
You are able to predict and prevent most failures before they occur
You increase the longevity of your equipment
You are able to predict with a level of confidence – imagine estimating how much product you will product next month and hitting that target – every time!
Business risks are significantly mitigated – a process that spews out metal, concentrates heavy metals or does not kill microbes that were in the raw material is an expensive mistake.
Your employees don’t feel like they are running around with their hair on fire all the time. It’s expensive to train new employees. Reduce your turnover with a less stressed-out team.
Maintaining a competitive edge in the cannabis industry is not easy, but it can be made easier with the right team, tools and data. Our recommendations boil down to a few simple steps:
Make sure you have a chemical or mechanical engineer to understand, optimize and standardize your process (you should have one of these on staff permanently!)
Implement a testing program for all raw materials
Test your raw materials – cannabis flower, solvents, additives, etc. before using. Work with your team to understand what you should and should not test for, and the frequency for doing so. Some materials/vendors are likely more consistent or reliable than others. Test the less reliable ones more frequently (or even every time!)
Test your final product after you extract it – Just because your local regulatory body does not require a certain test, it does not mean you should not look for it. Anything that you specified wanting the product to achieve needs to be tested at an established frequency (and this does not necessarily need to be every batch).
Repeat, and record all of your extraction parameters.
Review, approve and set a system in place for monitoring any changes.
Congratulations, you have just gone through the process of validating your operation. You may now begin to realize the benefits of validating your operation, from your personnel to your equipment and processes.
In this article you will learn how to control pests and improve the health of your cannabis plants using integrated pest management, commonly referred to as IPM. This involves a multi-point strategy – there is no quick fix, nor is there one solution that will wipe out all your pest problems. Proper pest management requires patience, consistency and determination.
It is important to understand that not all pesticides are bad. While many are incredibly harmful not only to pests, but also humans, in this article I will educate you about some of the safer alternatives to traditional pesticides. It is possible to safely control unwanted pests in your cannabis garden without harming yourself, your employees or the natural habitat around you.
Every cultivation facility should have a well-thought-out plan for their pest management program. This program should account for the prevention, and if necessary, eradication of: spider mites, russet mites, fungus gnats, root aphids, thrips and caterpillars. These are just a few of the more common pests you’ll find in a cannabis garden. There could also be many other less commonly known bugs, so you have to be vigilant in looking closely at your plants, and the soil, at all times. Complete eradication of a targeted pest can be difficult. Once a pest has established itself, decimating or decreasing the population will require an aggressive regimen that includes spraying daily to control populations and prevent other pests from getting established.
Spraying or applying pesticides to the foliage of plants isn’t the only way to control or eradicate pest populations. There are many other ways that you can minimize the spread of pests without the use of pesticides. In greenhouse and outdoor grows, growing specific types of plants around the cultivation area will attract both beneficial and predator bugs that will naturally control pest populations. Some plants that attract these bugs are: mint, peppers, and marigold. Beneficial and predator bugs, such as ladybugs, predator wasps and predator mites, can control unwanted pest populations in the area before they even have a chance to become a problem in your garden. Plants and flowers that attract bees, birds and insects will also create helpful bio- diversity, making it more difficult for the unwanted pests to thrive.
For indoor cultivation, it is imperative that you have your cultivation facility set up for a proper workflow. If you already have pests, you need to make sure you are not contaminating the rest of your facility when going from one area to the next. Make sure that you only go to contaminated areas at the very end of your day, and when you’re done working in that area, you must immediately exit the building. Do not ever walk back through the uncontaminated parts of your facility or the pests will spread quickly.
When most people think of pests in their cannabis garden they think of the more common varieties: spider mites, russet mites, aphids and thrips. However, there are also soil-dwelling pests that can exist, without your knowledge. These will decrease the health and vigor of your plants, without you even knowing they’re there, if you’re not careful to check for them. Some of the soil dwelling pests that plague cannabis plants are: root aphids, fungus gnat larvae and grubs. It is just as important to control the pests below the soil, feeding on your roots, as it is to control the pests that feed above soil on your plants.
Maintaining healthy plants is essential to controlling pest populations, both on the foliage and below the soil. Healthy plants will have an easier time fighting off pests than unhealthy plants. Plants have immune systems just like humans, and the stronger the plant’s immune system, the more likely it will be able to ward off pests and diseases. Allowing a plant to reach its full potential, by minimizing pests, means your plants will also have a better quality, smell and flavor, not to mention a bigger yield.
Worker Safety, Regulation and REI times
The application of pesticides requires certification from the state agricultural department. In certain situations, depending on the type of pesticide and method of application, a license may even be required. The application of pesticides without proper certification is against the law. Applying pesticides in a manner that is not in accordance with the label and instructions is also a violation of law.
The proper personal protective equipment (PPE) is required for anybody handling, mixing or applying pesticides. Employees can be a liability to your company if they are applying pesticides improperly. Make sure you and your entire staff are well educated about pesticide use requirements and limitations, prior to usage, and that only a properly certified person is handling the mixing and application at your facility.
After a pesticide is applied, you must abide by the re-entry interval (REI). This is the required time period limiting all workers from re-entry into areas where pesticides have been applied. This time period will vary depending on the type of pesticide used and the method of application. In some instances, pesticides applied in the last 30 days may require employee training before work can be done in those areas.
The misuse of or improper handling of pesticides is not only unlawful and dangerous to human health, but can also cause environmental damage to waterways and wildlife. The direct effects of pesticides on wildlife include acute poisoning, immunotoxicity, endocrine disruption, reproductive failure, altered morphology and growth rates and changes in behavior. Pesticides can indirectly impact wildlife through reduction of food resources and refuses, starvation due to decreased prey availability, hypothermia and secondary poisoning. Section 1602 of the California Fish and Game Code governs requirements for permitting of any project where pesticides will be used, and strictly regulates the disposal of all waste and run-off. It is imperative to know the regulations and to abide by them, or heavy fines will ensue!
Using Pesticides in a Regulated Market
Knowing which pesticides you can’t use, to avoid failing mandatory state testing, is just as important as knowing which ones you can use safely to pass required testing. Most states with regulated markets have strict limitations on the pesticides that can be used in cannabis cultivation. Pesticide use in the cultivation of cannabis is the most strictly regulated in the agriculture industry; the pesticides allowed for use in cannabis cultivation are far more limited than any other crop.
Just because a product is certified organic does not mean that it can be used, or that it is safe to be consumed or ingested. Oftentimes when cannabis flower alone is tested it will not fail or show a detectable amount of pesticides or heavy metals. However, when that flower is turned into concentrates, banned substances are then detected in testing, leading to test failures.
Cannabis cultivation facilities that are located on land that was previously used for conventional agriculture, or located near vineyards or other agricultural crops that are heavily sprayed with harmful pesticides, run a very high-risk failing testing. This is because of either spray drift from nearby agriculture, or residual pesticides and heavy metals left in the soil from previous crops that were using pesticides banned for cannabis cultivation. Accordingly, if you’re going to be growing outdoors or in a greenhouse, it is imperative that you get a soil and water test prior to cultivation, so you can determine if there is any potential for test failures due to pesticides or heavy metals in the soil or water in that area.
Proper Application – Using the Right Tools in the Right Way at the Right Time
One of the most important factors in pest management is proper identification of pests and proper application and coverage of pesticides. It does not require an entomology degree to identify insects, these days there is a lot of information online that can help you identify cannabis pests. Proper identification of insects can make the difference between success and failure. With a good eye and a microscope, if you do your research, you can control most insects in your garden.
In order to control pests in your garden you must get proper coverage of the foliage of the plant when you are applying pesticides. There are different types of equipment that are commonly used to apply pesticides in cannabis cultivation: backpack sprayers, foggers, and airless paint sprayers are the most common. An alternative method involves using an automated dosing system such as a dosatron, which injects fertilizer or pesticides at a specific ratio into your water lines, allowing you to use only the exact amount of pesticide you need. That way you avoid wasting money on unused pesticides. It is also safer for employees because it minimizes employee exposure, since there is no mixing required, and it allows for a large volume to be sprayed, without refilling a tank or a backpack sprayer.
No matter what you are using you must ensure you get the proper coverage on your plants in order to control pests. The temperature and humidity of your cultivation area, as well as the PH and temperature of the pesticide solution, all factor into the success of your IPM. For example, PFR 97 needs to be applied at a higher humidity range, around 70% to be most effective. In some areas this is not possible so repeated applications may be required to ensure the application is effective. A high PH or alkaline PH can cause alkaline hydrolysis which will make your pesticide solution less effective and will dictate how long your pesticides remain effective after they are mixed. It is therefore important to use your pesticide solution as soon as you make it; don’t let it sit around for long periods of time before use or it will be less effective.
In cannabis cultivation there are two different primary growth cycles: vegetative and flower. These cycles require different IPM strategies. In general, during the flowering cycle, pesticides should not be applied after the second week, with some limited exceptions i.e. for outdoor cultivation there is a longer window to spray since the flower set takes longer than a plant being grown inside, or in a light deprivation greenhouse, where there is a 12/12 flowering cycle.
For the vegetative (non-flowering) cycle, a strict rotation of foliage spray applications targeting not only pests, but also molds and pathogens, will be necessary to avoid a quick onset of infestation. Starting with an immaculate vegetation room is crucial to maintaining pest and mold free plants in the flowering cycle. Preventative sprays that are safe for use include: safer soap (contact kill) for soft bodied chewing insects; Regalia (biological control) for powdery mildew; and PFR 97 (biological control) for soft bodied chewing insects. It is also helpful to spray kelp, which strengthens the cell walls of plants, making the plant healthier, and thus enabling the plant to better defend itself from pests and diseases. Also, Bacillus thuringiensis (Bt) is useful to prevent or kill caterpillars.
The best way to control a pest infestation in the flowering cycle is at the very beginning on day one. You must start aggressively, with a three-way control consisting of a contact kill and preventative during days 1-14; preventative and biological control during days 10-18; and then release predator bugs on day 25, for optimal results. Knocking back the population with an effective contact kill pesticide early on is essential to ultimately lowering populations throughout the grow cycle, so that you can spray a biological control to preclude them from returning, before you release the predatory bugs at the end of the cycle.
Biological controls can take anywhere from 3 to 10 days before they are effective. Biological pesticides are selected strains of bacteria or fungus. When the plant tissue is eaten by a targeted pest, the bacteria kills the pest from the inside providing control without having to spray pesticides repeatedly. Predator bugs are the last line of defense, used in late flowering. They can be used indoors, outdoors and in greenhouses. An example of a common predator bug is Amblyseius californicus used to control low populations of spider mites, but there are many different varieties and they are specific depending on the type of pest population you seek to control.
A common concern with the use of predatory bugs, is whether they will be present when the flowers are harvested. However, if there is no food for the bugs (i.e. pests) the predator bugs will leave in search of food elsewhere. Further, indoor predator bugs are usually very small in size and difficult to see to an untrained eye. It is very unlikely to see any signs of predator bugs near the end of the flowering cycle, or in the finished flower product. Even when using bigger predator bugs, the bugs will leave the plants when harvested and dried.
Having pests can be very stressful. It is not uncommon to have bugs, pests, rodents, animals and birds cause damage in cannabis gardens. Making an informed decision based on science and not on unproven assumptions can determine how successful you are at pest management. There are many factors that go into pest management and no one situation is the same. You must be dedicated and consistent; pest management never stops. You will always have something ready to invade your garden. Prepare, plan, prevent and repeat!
The cannabis industry is growing exponentially, and the use of cannabis for medical purposes is being adopted across the nation. With this boom in cannabis consumers, there has been an increasing need for knowledge about the product.
The role of testing labs has become crucial to the process, which makes owning and operating a lab more lucrative. Scientists testing for potency, heavy metals, pesticides, residual solvents, moisture, terpene profile, microbial and fungal growth, and mycotoxins/aflatoxins are able to make meaningful contributions to the medical industry by making sure products are safe, while simultaneously generating profits and a return on investment.
Here are the key testing instruments you need to conduct these critical analyses. Note that cannabis analytical testing requirements may vary by state, so be sure to check the regulations applicable to the location of your laboratory.
The most important component of cannabis testing is the analysis of cannabinoid profiles, also known as potency. Cannabis plants naturally produce cannabinoids that determine the overall effect and strength of the cultivar, which is also referred to as the strain. There are many different cannabinoids that all have distinct medicinal effects. However, most states only require testing and reporting for the dry weight percentages of delta-9-tetrahydrocannabinol (Δ9-THC) and cannabidiol (CBD). It should be noted that delta-9-tetrahydrocannabinolic acid (Δ9-THCA) can be converted to THC through oxidation with heat or light.
For potency testing, traditional high-performance liquid chromatography (HPLC) is recommended and has become the gold standard for analyzing cannabinoid profiles. Look for a turnkey HPLC analyzer that delivers a comprehensive package that integrates instrument hardware, software, consumables and proven HPLC methods.
Heavy Metal Testing
Different types of metals can be found in soils and fertilizers, and as cannabis plants grow, they tend to draw in these metals from the soil. Heavy metals are a group of metals considered to be toxic, and the most common include lead, cadmium, arsenic and mercury. Most labs are required to test and confirm that samples are under the allowable toxic concentration limits for these four hazardous metals.
Heavy metal testing is performed by inductively coupled plasma mass spectrometry (ICP-MS). ICP-MS uses the different masses of each element to determine which elements are present within a sample and at what concentrations. Make sure to include accompanying software that provides assistant functions to simplify analysis by developing analytical methods and automatically diagnosing spectral interference. This will provide easy operation and analytical results with exceptionally high reliability.
To reduce running costs, look for a supporting hardware system that reduces the consumption of argon gas and electricity. For example, use a plasma ignition sequence that is optimized for lower-purity argon gas (i.e., 99.9% argon as opposed to more expensive 99.9999%).
The detection of pesticides in cannabis can be a challenge. There are many pesticides that are used in commercial cannabis grow operations to kill the pests that thrive on the plants and in greenhouses. These chemicals are toxic to humans, so confirming their absence from cannabis products is crucial. The number of pesticides that must be tested for varies from state to state, with Colorado requiring only 13 pesticides, whereas Oregon and California require 59 and 66 respectively. Canada has taken it a step further and must test for 96 pesticides, while AOAC International is developing methods for testing for 104 pesticides. The list of pesticides will continue to evolve as the industry evolves.
Testing for pesticides is one of the more problematic analyses, possibly resulting in the need for two different instruments depending on the state’s requirements. For a majority of pesticides, liquid chromatography mass spectrometry (LCMS) is acceptable and operates much like HPLC but utilizes a different detector and sample preparation.
Pesticides that do not ionize well in an LCMS source require the use of a gas chromatography mass spectrometry (GCMS) instrument. The principles of HPLC still apply – you inject a sample, separate it on a column and detect with a detector. However, in this case, a gas (typically helium) is used to carry the sample.
Look for a LC-MS/MS system or HPLC system with a triple quadrupole mass spectrometer that provides ultra-low detection limits, high sensitivity and efficient throughput. Advanced systems can analyze more than 200 pesticides in 12 minutes.
For GCMS analysis, consider an instrument that utilizes a triple quadrupole mass spectrometer to help maximize the capabilities of your laboratory. Select an instrument that is designed with enhanced functionality, analysis software, databases and a sample introduction system. Also include a headspace autosampler, which can also be used for terpene profiles and residual solvent testing.
Residual Solvent Testing
Residual solvents are chemicals left over from the process of extracting cannabinoids and terpenes from the cannabis plant. Common solvents for such extractions include ethanol, butane, propane and hexane. These solvents are evaporated to prepare high-concentration oils and waxes. However, it is sometimes necessary to use large quantities of solvent in order to increase extraction efficiency and to achieve higher levels of purity. Since these solvents are not safe for human consumption, most states require labs to verify that all traces of the substances have been removed.
Testing for residual solvents requires gas chromatography (GC). For this process, a small amount of extract is put into a vial and heated to mimic the natural evaporation process. The amount of solvent that is evaporated from the sample and into the air is referred to as the “headspace.” The headspace is then extracted with a syringe and placed in the injection port of the GC. This technique is called full-evaporated technique (FET) and utilizes the headspace autosampler for the GC.
Look for a GCMS instrument with a headspace autosampler, which can also be used for pesticide and terpene analysis.
Terpene Profile Testing
Terpenes are produced in the trichomes of the cannabis leaves, where THC is created, and are common constituents of the plant’s distinctive flavor and aroma. Terpenes also act as essential medicinal hydrocarbon building blocks, influencing the overall homeopathic and therapeutic effect of the product. The characterization of terpenes and their synergistic effect with cannabinoids are key for identifying the correct cannabis treatment plan for patients with pain, anxiety, epilepsy, depression, cancer and other illnesses. This test is not required by most states, but it is recommended.
The instrumentation that is used for analyzing terpene profiles is a GCMS with headspace autosampler with an appropriate spectral library. Since residual solvent testing is an analysis required by most states, all of the instrumentation required for terpene profiling will already be in your lab.
As with residual solvent testing, look for a GCMS instrument with a headspace autosampler (see above).
Microbe, Fungus and Mycotoxin Testing
Most states mandate that cannabis testing labs analyze samples for any fungal or microbial growth resulting from production or handling, as well as for mycotoxins, which are toxins produced by fungi. With the potential to become lethal, continuous exposure to mycotoxins can lead to a buildup of progressively worse allergic reactions.
LCMS should be used to qualify and identify strains of mycotoxins. However, determining the amount of microorganisms present is another challenge. That testing can be done using enzyme linked immunosorbent assay (ELISA), quantitative polymerase chain reaction (qPCR) or matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS), with each having their advantages and disadvantages.
For mycotoxin analysis, select a high-sensitivity LC-MS/MS instrument. In addition to standard LC, using an MS/MS selective detector enables labs to obtain limits of detection up to 1000 times greater than conventional LC-UV instruments.
For qPCR and its associated needs, look for a real-time PCR amplification system that combines thermal cyclers with optical reaction modules for singleplex and multiplex detection of fluorophores. These real-time PCR detection systems range from economical two-target detection to sophisticated five-target or more detection systems. The real-time detection platform should offer reliable gradient-enabled thermal cyclers for rapid assay optimization. Accompanying software built to work with the system simplifies plate setup, data collection, data analysis and data visualization of real-time PCR results.
Moisture Content and Water Activity Testing
Moisture content testing is required in some states. Moisture can be extremely detrimental to the quality of stored cannabis products. Dried cannabis typically has a moisture content of 5% to 12%. A moisture content above 12% in dried cannabis is prone to fungal growth (mold). As medical users may be immune deficient and vulnerable to the effects of mold, constant monitoring of moisture is needed. Below a 5% moisture content, the cannabis will turn to a dust-like texture.
The best way to analyze the moisture content of any product is using the thermogravimetric method with a moisture balance instrument. This process involves placing the sample of cannabis into the sample chamber and taking an initial reading. Then the moisture balance instrument heats up until all the moisture has been evaporated out of the sample. A final reading is then taken to determine the percent weight of moisture that was contained in the original sample.
Look for a moisture balance that offers intuitive operation and quick, accurate determination of moisture content. The pan should be spacious enough to allow large samples to be spread thinly. The halogen heater and reflector plate should combine to enable precise, uniform heating. Advanced features can include preset, modifiable measurement modes like automated ending, timed ending, rapid drying, slow drying and step drying.
Another method for preventing mold is monitoring water activity (aW). Very simply, moisture content is the total amount of water available, while water activity is the “free water” that could produce mold. Water activityranges from 0 to 1. Pure water would have an aW of 1.0. ASTM methods D8196-18 and D8297-18 are methods for monitoring water activity in dry cannabis flower. The aW range recommended for storage is 0.55 to 0.65. Some states recommend moisture content to be monitored, other states monitor water activity, and some states such as California recommend monitoring both.
As you can see, cannabis growers benefit tremendously from cannabis testing. Whether meeting state requirements or certifying a product, laboratory testing reduces growers’ risk and ensures delivery of a quality product. As medicinal and recreational cannabis markets continue to grow, analytical testing will ensure that consumers are receiving accurately
labeled products that are free from contamination. That’s why it is important to invest in the future of your cannabis testing lab by selecting the right analytical equipment at the start of your venture.
RoHS 3 (EU Directive 2015/863) adds a catch-all “Category 11” of regulated products that includes electronic nicotine delivery systems (ENDS), e-cigarettes, cannabis vaporizers and vape pens. This category becomes effective July 22, 2019. The most significant restricted substance applicable to this category is lead, and RoHS requires regulated products to contain less than 1000 parts per million (ppm). This follows on the heels of California’s new 2019 regulations requiring the testing of contents of cannabis vape cartridges using even stricter limits for lead (which makes sense because it applies to the product being consumed, not the separate electronic components). These regulations may seem unrelated, but anecdotally there have been widespread reports of higher than expected lead content in China-sourced electronic components, including both cartridges and related electronics. Whether metal used in e-cigarette type products is the source of any lead in the actual nicotine, cannabis or other concentrated product is an entirely different topic, but new laws, and in particular the new RoHS catch-all category, make 2019 an important year for any company responsible for certifying or testing lead levels in e-cigarette or vape products.
Background on EU RoHS
RoHS (Restriction of Hazardous Substances) originated in the EU in 2003 as a restriction on hazardous substances in specified categories of electronics and electronic products. Other countries have passed laws styled after RoHS, but only the EU RoHS is addressed here. Unlike some environmental laws, RoHS is not only focused on the safety of products during their life cycle of consumer use, but is designed to keep restricted substances out of landfills and recycling centers.
The original RoHS restricted the use of lead, cadmium, mercury, hexavalent chromium, PBB and PBDE. RoHS now restricts the use of a total of ten substances after the EU added four types of phthalates to its restricted substance list. Compliance with RoHS became a requirement for the use of the CE mark in 2011, and replaced a RoHS compliant mark on restricted products.
RoHS specified categories for regulation include large household appliances, small household appliances, computer equipment, lighting, power tools, toys, certain medical devices, control equipment (smoke alarms, thermostats and their industrial equivalents), and ATM machines. Newly added Category 11, the “catch all” category, includes all other electronic and electrical equipment not covered in the previous categories, including electronic nicotine delivery systems, cannabis vaporizers and vape pens.
RoHS Lead Exemptions Complicate Compliance
RoHS provides numerous exceptions to its strict 1000ppm lead standard that are slated to expire in phases from 2021 through 2024. Most Category 11 exceptions will not expire until 2024. For example, RoHS permits different levels of lead for lead in glass and ceramics, lead in high temperature solders, and lead in copper and aluminum alloys. So, an e-cigarette may contain some parts that are held to the highest level of lead restriction, it may but contain isolated components that (at least through 2024) are held to more permissive standards. While this leeway may reduce manufacturing costs for certain components, it creates greater complexity in testing. Anecdotal reports suggest that especially for products that compete heavily on price, sourcing from lesser-known Chinese foundries has resulted in unpredictable lead levels.
Take Away Points
As vape and e-cigarette companies compete with new features and design elements each year, and companies rely on new manufacturers, keeping up with regulations has proven to be difficult for both U.S. and for EU regulated products. For example, a company has to comply with numerous regulations regarding the oil or concentrate that will ultimately be inhaled by a consumer, and with regulations like RoHS that regulate parts a consumer may never touch or see. Each year, some company comes out with a new set of electronic features that may interact with newly formulated oils or concentrates, other companies compete for features or price points, making these products a moving target when it comes to testing.
Adding lead to many metals makes them easier to work with and therefore cheaper. Anecdotal reports suggest that especially for products that compete heavily on price, sourcing from lesser-known Chinese foundries has resulted in unpredictable lead levels. This can be the result of any number of causes: changes in sub-contractors, uses of industrial equipment for other products that permit higher lead content, or simply unscrupulous management that is willing to risk a contract to save money manufacturing a batch of components. There is speculation that some lead may leach into oil or concentrates in e-cigarette and vape products from the contact between the oil or concentrate and internal heating elements in certain type of products. RoHS compliance with regard to lead levels may reduce the chance of inadvertent lead contamination by such means, and compliance may therefore yield benefits on several regulatory fronts.
Compliance with RoHS for each part of an e-cigarette or vape therefore requires knowing your supplier for each component, but given increased regulation of these products (both the hardware and consumable elements) this can only help compliance with regulations in every relevant jurisdiction.
With the state led legalization of both adult recreational and medical cannabis, there is a need for comprehensive and reliable analytical testing to ensure consumer safety and drug potency. Cannabis-testing laboratories receive high volumes of test requests from cannabis cultivators for testing quantitative and qualitative aspects of the plant. The testing market is growing as more states bring in stricter enforcement policies on testing. As the number of testing labs grow, it is anticipated that the laboratories that are now servicing other markets, including high throughput contract labs, will cross into cannabis testing as regulations free up. As the volume of tests each lab performs increases, the need for laboratories to make effective use of time and resource management, such as ensuring accurate and quick results, reports, regulatory compliance, quality assurance and many other aspects of data management becomes vital in staying competitive.
Cannabis Testing Workflows
To be commercially competitive, testing labs offer a comprehensive range of testing services. These services are available for both the medical and recreational cannabis markets, including:
Detection and quantification of both acid and neutral forms of cannabinoids
Screening for pesticide levels
Monitoring water activity to indicate the possibility of microbiological contamination
Moisture content measurements
Residual solvents and heavy metal testing
Fungi, molds, mycotoxin testing and many more
Although the testing workflows differ for each test, here is a basic overview of the operations carried out in a cannabis-testing lab:
Cannabis samples are received.
The samples are processed using techniques such as grinding and homogenization. This may be followed by extraction, filtration and evaporation.
A few samples will be isolated and concentrated by dissolving in solvents, while others may be derivatized using HPLC or GC reagents
The processed samples are then subjected to chromatographic separation using techniques such as HPLC, UHPLC, GC and GC-MS.
The separated components are then analyzed and identified for qualitative and quantitative analysis based on specialized standards and certified reference materials.
The quantified analytical data will be exported from the instruments and compiled with the corresponding sample data.
The test results are organized and reviewed by the lab personnel.
The finalized test results are reported in a compliant format and released to the client.
In order to ensure that cannabis testing laboratories function reliably, they are obliged to follow and execute certain organizational and regulatory protocols throughout the testing process. These involve critical factors that determine the accuracy of testing services of a laboratory.
Factors Critical to a Cannabis Testing Laboratory
Accreditations & Regulatory Compliance: Cannabis testing laboratories are subject to regulatory compliance requirements, accreditation standards, laboratory practices and policies at the state level. A standard that most cannabis testing labs comply to is ISO 17025, which sets the requirements of quality standards in testing laboratories. Accreditation to this standard represents the determination of competence by an independent third party referred to as the “Accreditation Body”. Accreditation ensures that laboratories are adhering to their methods. These testing facilities have mandatory participation in proficiency tests regularly in order to maintain accreditation.
Quality Assurance, Standards & Proficiency Testing: Quality assurance is in part achieved by implementing standard test methods that have been thoroughly validated. When standard methods are not available, the laboratory must validate their own methods. In addition to using valid and appropriate methods, accredited laboratories are also required to participate in appropriate and commercially available Proficiency Test Program or Inter-Laboratory Comparison Study. Both PT and ILC Programs provide laboratories with some measure of their analytic performance and compare that performance with other participating laboratories.
Real-time Collaboration: Testing facilities generate metadata such as data derived from cannabis samples and infused products. The testing status and test results are best served for compliance and accessibility when integrated and stored on a centralized platform. This helps in timely data sharing and facilitates informed decision making, effective cooperation and relationships between cannabis testing facilities and growers. This platform is imperative for laboratories that have grown to high volume throughput where opportunities for errors exist. By matching test results to samples, this platform ensures consistent sample tracking and traceability. Finally, the platform is designed to provide immediate, real-time reporting to individual state or other regulatory bodies.
Personnel Management: Skilled scientific staff in cannabis-testing laboratories are required to oversee testing activities. Staff should have experience in analytical chromatography instruments such as HPLC and GC-MS. Since samples are often used for multi-analytes such as terpenes, cannabinoids, pesticides etc., the process often involves transferring samples and tests from one person to another within the testing facility. A chain of custody (CoC) is required to ensure traceability and ‘ownership’ for each person involved in the workflow.
LIMS for Laboratory Automation
Gathering, organizing and controlling laboratory-testing data can be time-consuming, labor-intensive and challenging for cannabis testing laboratories. Using spreadsheets and paper methods for this purpose is error-prone, makes data retrieval difficult and does not allow laboratories to easily adhere to regulatory guidelines. Manual systems are cumbersome, costly and lack efficiency. One way to meet this challenge is to switch to automated solutions that eliminate many of the mundane tasks that utilize valuable human resources.. Laboratory automation transforms the data management processes and as a result, improves the quality of services and provides faster turnaround time with significant cost savings. Automating the data management protocol will improve the quality of accountability, improve technical efficiency, and improve fiscal resources.
A Laboratory Information Management System (LIMS) is a software tool for testing labs that aids efficient data management. A LIMS organizes, manages and communicates all laboratory test data and related information, such as sample and associated metadata, tests, Standard Operating Procedures (SOPs), test reports, and invoices. It also enables fully automated data exchange between instruments such as HPLCs, GC-FIDs, etc. to one consolidated location, thereby reducing transcription errors.
How LIMS Helps Cannabis Testing Labs
LIMS are much more capable than spreadsheets and paper-based tools for streamlining the analytical and operational lab activities and enhances the productivity and quality by eliminating manual data entry. Cloud-enabled LIMS systems such as CloudLIMS are often low in the total cost of acquisition, do not require IT staff and are scalable to help meet the ever changing business and regulatory compliance needs. Some of the key benefits of LIMS for automating a cannabis-testing laboratory are illustrated below [Table 1]:
Barcode label designing and printing
Enables proper labelling of samples and inventory
Follows GLP guidelines
Instant data capture by scanning barcodes
Facilitates quick client registration and sample access
3600 data traceability
Saves time and resources for locating samples and other records
Inventory and order management
Supports proactive planning/budgeting and real time accuracy
Promotes overall laboratory organization by assigning custodians for samples and tests
Maintains the Chain-of-custody (CoC)
Accommodates pre-loaded test protocols to quickly assign tests for incoming samples
Accounting for sample and inventory quantity
Automatically deducts sample and inventory quantities when consumed in tests
Package & shipment management
Manages incoming samples and samples that have been subcontracted to other laboratories
Electronic data import
Electronically imports test results and metadata from integrated instruments
Eliminates manual typographical errors
Generates accurate, customizable, meaningful and test reports for clients
Allows user to include signatures and additional sections for professional use
21 CFR Part 11 compliant
Authenticates laboratory activities with electronic signatures
ISO 17025 accreditation
Provides traceable documentary evidence required to achieve ISO 17025 accreditation
Audit trail capabilities
Adheres to regulatory standards by recording comprehensive audit logs for laboratory activities along with the date and time stamp
Centralized data management
Stores all the data in a single, secure database facilitating quick data retrieval
Promotes better data management and resource allocation
Enables modification of screens using graphical configuration tools to mirror testing workflows
State compliance systems
Integrates with state-required compliance reporting systems and communicates using API
Adheres to regulatory compliance
Creates Certificates of Analysis (CoA) to prove regulatory compliance for each batch as well as batch-by-batch variance analysis and other reports as needed.
Data security & confidentiality
Masks sensitive data from unauthorized user access
Cloud-based LIMS encrypts data at rest and in-transit while transmission between the client and the server
Cloud-based LIMS provides real-time access to laboratory data from anytime anywhere
Cloud-based LIMS enhances real-time communication within a laboratory, between a laboratory and its clients, and across a global organization with multiple sites
Table 1. Key functionality and benefits of LIMS for cannabis testing laboratories
Upon mapping the present day challenges faced by cannabis testing laboratories, adopting laboratory automation solutions becomes imperative. Cloud-based LIMS becomes a valuable tool for laboratory data management in cannabis testing laboratories. In addition to reducing manual workloads, and efficient resource management, it helps labs focus on productive lab operations while achieving compliance and regulatory goals with ease.
Dana Ciccone, chief executive officer of Steep Hill Hawaii, has been a patient advocate and leader in cannabis education in Hawaii, as well as a member of the Hawaii Medical Marijuana Dispensary Task Force, an organization formed by the University of Hawaii College of Social Sciences Public Policy Center to develop regulations for the state. “We are proud not only to be the first cannabis lab to be licensed in the State of Hawaii, but also now the first lab to achieve ISO certification as well,” says Ciccone. “Industry businesses, medical professionals, state regulators, and patients can be confident that our lab and its testing standards will operate to the highest international standards.”
According to the press release, the laboratory will offer services for testing cannabinoid profiles (potency), terpenes, pesticides, heavy metals, biological screening, and residual solvents, testing for 17 Cannabinoids and 43 terpenes. The release states they are locally owned and operated, providing testing services for not just industry businesses, but in-state card-holding patients as well.
“This is a turning point for the industry – we have moved very quickly to raise the industry standards in Hawaii to internationally recognized certification,” says Ciccone. “I am very proud our scientific team for the professionalism and hard work they put in to achieve this certification.”
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