Tag Archives: manufacturing

Steven Burton

3 Ways The Cannabis Industry Can Benefit By Adopting IoT Tech

By Steven Burton
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Steven Burton

The cannabis industry of the United States is unlike other horticulture markets in the country. It’s younger, less traditional and with roots in a black market, it’s no surprise that its forerunners aren’t afraid to experiment with new approaches and technology.

The rapid adoption of IoT (Internet of Things) technology is one way in particular that this new generation of producers is stepping up, and they’re beginning to reap the rewards. But to better demonstrate how significant the implementation of IoT tech can be, we’ll peek over the fence at other craft-oriented food industries—namely wine and chocolate—to discover how effective they can be long-term for serious players in the cannabis industry.

The results, as you can probably guess, are astounding.

Farm Productivity and Precision is on the Rise

IoT tech isn’t just a cool new thing for experimental growers – it’s as necessary as air in the 21st century. New and veteran farms alike are discovering ways to streamline production and enhance the quality of their crops. One of the most common implementations of IoT tech in agriculture is the installation of smart measurement tools. Remote sensors can monitor soil acidity, humidity, salt concentrations, temperature and a variety of other metrics, automating the collection of data and providing a clear picture of plant health. For many farms, like E. & J. Gallo Winery, this is a game-changer.By installing hundreds of sensors per block and upgrading to a more precise irrigation system, Gallo was able to connect moisture measurements to a central system

Before placing sensors in over 250 acres of their vineyard, Gallo could only make irrigation adjustments at the large block level. Even with careful monitoring of moisture levels, the grape yield was inconsistent in size and flavor. By installing hundreds of sensors per block and upgrading to a more precise irrigation system, Gallo was able to connect moisture measurements to a central system. The system collects the data, considers the weather forecast, and automatically irrigates small areas of the vineyard as needed to ensure all plants are optimally watered. This resulted in a more uniform crop, less water waste and more desirable grapes.

Cannabis farms are starting to pick up on this simple approach as well. Organigram, one of Canada’s leading Cannabis producers, is well aware of the benefits of this kind of automation and data collection. “All our grow rooms are helping us learn all the time,” says Matt Rogers, head of production at Organigram. “With 20 grow rooms going, we can gather as much information about these plants as you would get in a century of summers.”

Automation and precision have enabled by Gallo and Organigram to improve yield and increase precision, which has helped them achieve their well-respected status in the wine and cannabis industries.

The Supply Chain is Becoming More Transparent

As much as we would like the industry to be free of scams and crooks, there’s more than a few producers stretching the truth when it comes to labeling product. MyDx, a cannabis chemical analyzer, recently revealed that the label on the package often does not totally coincide with the product within.Protecting your brand’s reputation is a necessity and IoT tech is helping some pioneering industries do that.

For example, the most frequently tested cannabis strain, “Blue Dream”, averages a 64% difference in chemical makeup from sample to sample. Similarly, “Gorilla Glue” and “Green Crack” show as much as 83% variation from sample to sample—largely because there’s no regulation of these names.

While variation is inevitable from grower to grower, plant to plant, and even between different parts of the same plant, misleading labels and the addition of ‘fillers’ is a growing issue for edible cannabis producers, and the threat it poses to your brand isn’t minor. Protecting your brand’s reputation is a necessity and IoT tech is helping some pioneering industries do that.

Wine in China is a powerful example of how improved traceability can reduce large-scale mislabeling. Brand-name winemakers in the country face a massive problem: 70% of imported wines are counterfeits. To combat this, winemakers are attaching near-field communication (NFC) labels to imported and domestic bottles. It’s a dramatic solution, but one that’s protecting the brand of winemakers dedicated to quality and transparency.

As the legalization of cannabis spreads and coveted strains emerge, so will the availability of counterfeits—or, at the very least, less-than-truthful labeling. This has proven to be true in almost every specialty market, and adopting improved traceability tech will defend your brand and reputation from the consequences of selling a product that’s discovered to be more ‘filler’ than cannabis.

Compliance is Easily Achieved

The conversation of cannabis regulation generally revolves around age restrictions and driving while impaired, but government compliance is far more complicated – especially for facilities that create cannabis-infused food products. And here’s the frustrating part for those who must (and should) maintain a food safety plan: every time a regulation is adjusted (or every time a new variation is added in another state), facilities must be able to document changes in procedures, recipes and hazard controls. It gets complicated quickly, especially if all the documentation is kept manually.

There’s a lot to be gained by connecting your systems and products to the Internet of ThingsA central, connected system is the best way for food manufacturers to streamline and automate a variety of documentation and food safety tasks, which can mean thousands of dollars saved over months or years. Using software like Icicle, facilities can create a comprehensive data environment that’s dynamic and accessible from anywhere. Incoming measurements from connected equipment and employee records are collected and an admin dashboard allows you to see what food safety systems are thriving and which need revisiting. The records – transformed into a compliant food safety plan – can then be pulled up during audits and inspections on the spot, saving the months that companies usually spend preparing documentation.

According to Mitchell Pugh of Chewter’s Chocolates, their system “gives me a great peace of mind in the sense to know we have all our information prepared and anything that an inspector is going to ask for – whether they’re looking for one product, a general system, a certain hazard, or a bill of ingredients or materials or an allergen – is easy for us to search for it, pull it up, and find exactly what they’re looking for.”

Considering that most food manufacturers still record measurements and create food safety plans manually, this is an area where progressive companies can quickly outpace their non-automated rivals.

Whether you’re a grower, dispensary, food producer, or some other kind of cannabis professional, there’s a lot to be gained by connecting your systems and products to the Internet of Things. Which direction will you take?

control the room environment

Environmental Controls: The Basics

By Vince Sebald
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control the room environment

The outside environment can vary widely depending on where your facility is located. However, the internal environment around any activity can have an effect on that activity and any personnel performing the activity, whether that’s storage, manufacturing, testing, office work, etc. These effects can, in turn, affect the product of such activities. Environmental control strategies aim to ensure that the environment supports efforts to keep product quality high in a manner that is economical and sensible, regardless of the outside weather conditions.

For this article, let us define the “environment” as characteristics related to the room air in which an activity is performed, setting aside construction and procedural conditions that may also affect the activity. Also, let us leave the issue of managing toxins or potent compounds for another time (as well as lighting, noise, vibration, air flow, differential pressures, etc). The intent here is to focus on the basics: temperature, humidity and a little bit on particulate counts.

Temperature and humidity are key because a non-suitable environment can result in the following problems:

  • Operator discomfort
  • Increased operator error
  • Difficulty in managing products (e.g. powders, capsules, etc)
  • Particulate generation
  • Degradation of raw materials
  • Product contamination
  • Product degradation
  • Microbial and mold growth
  • Excessive static

USP <659> “Packaging and Storage Requirements” identifies room temperature as 20-25°C (68-77 °F) and is often used as a guideline for operations. If gowning is required, the temperature may be reduced to improve operator comfort. This is a good guide for human working areas. For areas that require other specific temperatures (e.g. refrigerated storage for raw materials), the temperature of the area should be set to those requirements.

Humidity can affect activities at the high end by allowing mold growth and at the low end by increasing static. Some products (or packaging materials) are hydroscopic, and will take on water from a humid environment. Working with particular products (e.g. powders) can also drive the requirement for better humidity control, since some powders become difficult to manage in either high or low humidity environments. For human operations without other constraints, a typical range for desirable humidity is in the range of 20 to 70% RH in manufacturing areas, allowing for occasional excursions above. As in the case of temperature, other requirements may dictate a different range.

control the room environment
In some cases, a locally controlled environment is a good option to reduce the need to control the room environment as tightly or to protect the operator.

In a typical work environment, it is often sufficient to control the temperature, while allowing the relative humidity to vary. If the humidity does not exceed the limits for the activity, then this approach is preferred, because controlling humidity adds a level of complexity (and cost) to the air handling. If humidity control is required, it can be managed by adding moisture via various humidification systems, or cooling/reheating air to remove moisture. When very low humidity is required, special equipment such as a desiccant system may be required. It should be noted that although you can save money by not implementing humidity control at the beginning, retrofitting your system for humidity control at a later time can be expensive and require a shutdown of the facility.

Good engineering practice can help prevent issues that may be caused by activities performed in inappropriately controlled environments. The following steps can help manage the process:

  • Plan your operations throughout your facility, taking into account the requirements for the temperature and humidity in each area and know what activities are most sensitive to the environment. Plans can change, so plan for contingencies whenever possible.
  • Write down your requirements in a User Requirement Specification (URS) to a level of detail that is sufficient for you to test against once the system is built. This should include specific temperature and RH ranges. You may have additional requirements. Don’t forget to include requirements for instrumentation that will allow you to monitor the temperature and RH of critical areas. This instrumentation should be calibrated.
  • Solicit and select proposals for work based on the URS that you have generated. The contractor will understand the weather in the area and can ensure that the system can meet your requirements. A good contractor can also further assist with other topics that are not within the scope of this article (particulates, differential pressures, managing heating or humidity generating equipment effects, etc).
  • Once work is completed, verify correct operation using the calibrated instrumentation provided, and make sure you add periodic calibration of critical equipment, as well as maintenance of your mechanical system(s), to your calibration and maintenance schedules, to keep everything running smoothly.

The main point is if you plan your facility and know your requirements, then you can avoid significant problems down the road as your company grows and activity in various areas increases. Chances are that a typical facility may not meet your particular requirements, and finding that out after you are operational can take away from your vacation time and peace of mind. Consider the environment, its good business!

HACCP

Hazard Analysis and Critical Control Points (HACCP) for the Cannabis Industry: Part 1

By Kathy Knutson, Ph.D.
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HACCP

Hazard Analysis and Critical Control Points (HACCP) Defined

Farm-to-fork is a concept to describe the control of food safety starting in the fields of a farm and ending with deliciousness in my mouth. The more that is optimized at every step, the more food safety and quality are realized. Farm-to-fork is not a concept reserved for foodies or “eat local” food campaigns and applies to all scales of food manufacture. HACCP is like putting the last piece of a huge puzzle in the middle and seeing the whole picture develop. HACCP is a program to control food safety at the step of food processing. In states where cannabis is legal, the state department of public health or state department of agriculture may require food manufacturers to have a HACCP plan. The HACCP plan is a written document identifying food safety hazards and how those hazards are controlled by the manufacturer. While there are many resources available for writing a HACCP plan, like solving that puzzle, it is a do-it-yourself project. You can’t use someone else’s “puzzle,” and you can’t put the box on a shelf and say you have a “puzzle.”

HACCP is pronounced “ha” as in “hat” plus “sip.”

(Say it aloud.)

3-2-1 We have liftoff.

The history of HACCP starts not with Adam eating in the garden of Eden but with the development of manned missions to the moon, the race to space in the 1950s. Sorry to be gross, but imagine an astronaut with vomiting and diarrhea as a result of foodborne illness. In the 1950s, the food industry relied on finished product testing to determine safety. Testing is destructive of product, and there is no amount of finished product testing that will determine food is safe enough for astronauts. Instead, the food industry built safety into the process. Temperature was monitored and recorded. Acidity measured by pH is an easy test. Rather than waiting to test the finished product in its sealed package, the food industry writes specifications for ingredients, ensures equipment is clean and sanitized, and monitors processing and packaging. HACCP was born first for astronauts and now for everyone.HACCP

HACCP is not the only food safety program.

If you are just learning about HACCP, it is a great place to start! There is a big world of food safety programs. HACCP is required by the United States Department of Agriculture for meat processors. The Food and Drug Administration (FDA) requires HACCP for seafood processing and 100% juice manufacture. For all foods beyond meat, seafood and juice, FDA has the Food Safety Modernization Act (FSMA) to enforce food safety. FSMA was signed in 2011 and became enforceable for companies with more than 500 employees in September of 2016; all food companies are under enforcement in September 2018. FSMA requires all food companies with an annual revenue greater than $1 million to follow a written food safety plan. Both FDA inspectors and industry professionals are working to meet the requirements of FSMA. There are also national and international guidelines for food safety with elements of HACCP which do not carry the letter of law.

The first step in HACCP is a hazard analysis.

Traditionally HACCP has focused on processing and packaging. Your organization may call that manufacturing or operations. In a large facility there is metering of ingredients by weight or volume and mixing. A recipe or batch sheet is followed. Most, but not all, products have a kill step where high heat is applied through roasting, baking, frying or canning. The food is sealed in packaging, labeled, boxed and heads out for distribution. For your hazard analysis, you identify the potential hazards that could cause injury or illness, if not controlled during processing. Think about all the potential hazards:

  • Biological: What pathogens are you killing in the kill step? What pathogens could get in to the product before packaging is sealed?
  • Chemical: Pesticides, industrial chemicals, mycotoxins and allergens are concerns.
  • Physical: Evaluate the potential for choking hazards and glass, wood, hard plastic and metal.

The hazards analysis drives everything you do for food safety.

I cannot emphasize too much the importance of the hazard analysis. Every food safety decision is grounded in the hazard analysis. Procedures will be developed and capital will be purchased based on the hazard analysis and control of food safety in your product. There is no one form for the completion of a hazard analysis.

HACCP risk matrix
A risk severity matrix. Many HACCP training programs have these.

So where do you start? Create a flow diagram naming all the steps in processing and packaging. If your flow diagram starts with Receiving of ingredients, then the next step is Storage of ingredients; include packaging with Receiving and Storage. From Storage, ingredients and packaging are gathered for a batch. Draw out the processing steps in order and through to Packaging. After Packaging, there is finished product Storage and Distribution. Remember HACCP focuses on the processing and packaging steps. It is not necessary to detail each step on the flow diagram, just name the step, e.g. Mixing, Filling, Baking, etc. Other supporting documents have the details of each step.

For every step on the flow diagram, identify hazards.

Transfer the name of the step to the hazard analysis form of your choice. Focus on one step at a time. Identify biological, chemical and physical hazards, if any, at that step. The next part is tricky. For each hazard identified, determine the probability of the hazard occurring and severity of illness or injury. Some hazards are easy like allergens. If you have an ingredient that contains an allergen, the probability is high. Because people can die from ingestion of allergens when allergic, the severity is high. Allergens are a hazard you must control. What about pesticides? What is the probability and severity? I can hear you say that you are going to control pesticides through your purchasing agreements. Great! Pesticides are still a hazard to identify in your hazard analysis. What you do about the hazard is up to you.

Steven Burton

Top 4 Food Safety Hazards for the Cannabis Industry

By Steven Burton
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Steven Burton

As many US States and Canadian provinces approach legalization of cannabis, the question of regulatory oversight has become a pressing issue. While public awareness is mainly focused on issues like age restrictions and impaired driving, there is another practical question to consider: should cannabis be treated as a drug or a food product when it comes to safety? In the US, FDA governs both food and drugs, but in Canada, drugs are regulated by Health Canada while food products are regulated under the CFIA.There are many food safety hazards associated with cannabis production and distribution that could put the public at risk, but are not yet adequately controlled

Of course, there are common issues like dosage and potency that pharmaceutical companies typically worry about as the industry is moving to classifying its products in terms of percentage of chemical composition (THC, CBD, etc. in a strain), much as we categorize alcohol products by the percentage of alcohol. However, with the exception of topical creams and ointments, many cannabis products are actually food products. Even the herb itself can be brewed into teas, added to baked goods or made into cannabis-infused butters, oils, capsules and tinctures.

FDAlogoAs more people gain access to and ingest cannabis products, it’s only a matter of time before food safety becomes a primary concern for producers and regulators. So when it comes to food safety, what do growers, manufacturers and distributors need to consider? The fact is, it’s not that different from other food products. There are many food safety hazards associated with cannabis production and distribution that could put the public at risk, but are not yet adequately controlled. Continue reading below for the top four safety hazards for the cannabis industry and learn how to receive free HACCP plans to help control these hazards.

Aflatoxins on Cannabis Bud

Just like any other agricultural product, improper growing conditions, handling and storage can result in mold growth, which produce aflatoxins that can cause liver cancer and other serious health problems. During storage, the danger is humidity; humidity must be monitored in storage rooms twice a day and the meter must be calibrated every month. During transportation, it is important to monitor and record temperatures in trucks. Trucks should also be cleaned weekly or as required. Products received at a cannabis facilities should be tested upon receiving and contaminated products must always be rejected, segregated and disposed of safely.

Petri dish containing the fungus Aspergillus flavus. It produces carcinogenic aflatoxins, which can contaminate certain foods and cause aspergillosis, an invasive fungal disease.
Photo courtesy of USDA ARS & Peggy Greb.

Chemical Residues on Cannabis Plants

Chemical residues can be introduced at several points during the production and storage process. During growing, every facility should follow instructions for applying fertilizers and pesticides to crops. This includes waiting for a sufficient amount of time before harvesting. When fertilizer is being applied, signs must be posted. After cannabis products have been harvested, chemical controls must be in place. All chemicals should be labelled and kept in contained chemical storage when not in use to prevent contamination. Only food-grade chemicals (e.g. cleaners, sanitizers) should be used during curing, drying, trimming and storage.

Without a comprehensive food safety program, problems will inevitably arise.There is also a risk of excessive concentration of chemicals in the washing tank. As such, chemical concentrations must be monitored for. In general, water (obviously essential for the growing process) also carries risks of pathogenic bacteria like staphylococcus aureus or salmonella. For this reason, city water (which is closely controlled in most municipalities) should be used with an annual report and review. Facilities that use well water must test frequently and water samples must be tested every three months regardless.

Pathogenic Contamination from Pest Infestations

Insects, rodents and other pests spread disease. In order to prevent infestations, a pest control program must be implemented, with traps checked monthly by a qualified contractor and verified by a designated employee. It is also necessary to have a building procedure (particularly during drying), which includes a monthly inspection, with no holes or gaps allowed. No product should leave the facility uncovered to prevent fecal matter and other hazards from coming into contact with the product. Contamination can also occur during storage on pallets, so pallets must be inspected for punctures in packaging material.

Furthermore, even the best controlled facility can fall victim to the shortcomings of their suppliers. Procedures must be in place to ensure that suppliers are complying with pest and building control procedures, among others. Certifications should be acquired and tracked upon renewal.

Pathogenic Contamination Due to Improper Employee Handling

Employee training is key for any food facility. When employees are handling products, the risk of cross-contamination is highest. Facilities must have GMP and personnel hygiene policies in place, with training conducted upon hiring and refreshed monthly. Employees must be encouraged to stay home when sick and instructed to wear proper attire (gloves, hair nets, etc.), while glass, jewelry and outside food must not be allowed inside the facility. Tools used during harvesting and other stages may also carry microorganisms if standard cleaning procedures are not in place and implemented correctly by employees.

As the cannabis industry grows, and regulatory bodies like the FDA and CFIA look to protect public safety, we expect that more attention will be paid to other food safety issues like packaging safety (of inks and labels), allergen control and others. In the production of extracts, for example, non-food safe solvents could be used or extracts can be mixed with ingredients that have expiration dates, like coconut oil. There is one area in which the cannabis industry may lead the way, however. More and more often, risks of food terrorism, fraud and intentional adulteration are gripping the food industry as the global food chain becomes increasingly complex. It’s safe to say that security at cannabis facilities is probably unparalleled.

All of this shows that cannabis products, especially edibles (and that includes capsules and tinctures), should be treated the same as other food products simply because they have the same kinds of hazards. Without a comprehensive food safety program (that includes a plan, procedures, training, monitoring and verification), problems will inevitably arise.

New Colorado Edibles Regulations Effective October 1st

By Aaron G. Biros
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Back in April of 2016, the Colorado Legislature passed HB 1436 in an effort to make infused products less appealing to children. On October 1st, 2017, the new law goes into effect, which will prohibit the sale of edibles in the shape of a human, animal or fruit.

The THC universal symbol

Colorado has a history of regulating the market like this, with laws designed to limit the dosing, consistency and appeal of edibles to children. In 2015, regulators placed a 100-milligram cap on THC in infused products, separated into 10-milligram servings. In 2016, regulators began requiring the THC stamp on edibles, a symbol with a clear representation of what the product contains.

Some in the industry are welcoming of these new laws, while others think it might be overregulation. Regardless, manufacturers that have previously produced things like fruit candies or gummy bears now need to update their processes to use non-descript shapes for their products in order to stay compliant.

incredibles logoBob Eschino, founder and president of Incredibles, an infused product manufacturer in Colorado, says these rules are not very effective at preventing kids from obtaining edibles, but it could help. “I believe consumer protection comes from CRP [child-resistant packaging], proper labeling, education and safe storage,” says Eschino. “CDPHE said themselves that stamping or shaping the products is the least effective way to prevent accidental ingestion. It’s a step that will add to consumer protection in a small way, but every little bit helps for now.” There are a number of more effective measures that regulators in Colorado take to prevent edibles from getting in the hands of children, such as child-resistant packaging, prohibiting advertising of cartoon characters, requiring opaque packaging and warning messages on labels.

Products like infused gummy bears will no longer be permitted for retail; Photo: Tamara S., Flickr

According to Peggy Moore, partner of Love’s Oven, an infused product manufacturer, and board president of the Cannabis Business Alliance, the major change companies need to make to stay compliant is ordering new molds. “Depending on the quantity ordered, molds can cost $10,000 or more to fabricate and produce.,” says Moore. “If a company was not using molds previously there is also training that may be required to orient production staff on technique for making molded confections.” She says there are still plenty of options for manufacturers to use like botanical shapes (a cannabis leaf, for example), circles, squares, rectangles and other shapes.

Her company, Love’s Oven, makes caramels, baked goods, crackers and other non-descript shapes already. “At this point I am not aware of any manufacturers who are not already compliant with this rule in advance,” says Moore. “The most common solution is to move to a square, circle or other shape utilizing molds. “ Moore believes it is a producer’s duty to make products that are not enticing to children. “Regardless of the industry (alcohol, cannabis, pharma) I think we should exercise great caution to not produce products that are targeting children,” says Moore. “While I would love to see manufacturers self-regulate in this regard, clearly some guardrail regulations are needed at this point.”

In addition to the rule on using non-descript shapes, HB 1436 prohibits the use of additives in retail cannabis products that are designed to make it addictive, more appealing to children or misleading consumers. The rule does, however, exclude common baking and cooking ingredients. There is also a stipulation that permits local fire departments to perform annual fire inspections at cannabis cultivation facilities.

extraction equipment

Implementing a HACCP Plan in Cannabis Processing

By Aaron G. Biros
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extraction equipment

Hazard analysis and critical control points (HACCP) is a robust management system that identifies and addresses any risk to safety throughout production. Originally designed for food safety through the entire supply chain, the risk assessment scheme can ensure extra steps are taken to prevent contamination.

The FDA as well as the Food Safety and Inspection Service currently require HACCP plans in a variety of food markets, including high-risk foods like poultry that are particularly susceptible to pathogenic contamination. As California and other states develop and implement regulations with rigorous safety requirements, cannabis cultivators, extractors and infused product manufacturers can look to HACCP for guidance on bolstering their quality controls. Wikipedia actually has a very helpful summary of the terms referenced and discussed here.

Dr. Markus Roggen, vice president of extraction

The HACCP system consists of six steps, the first of which being a hazard analysis. For Dr. Markus Roggen, vice president of extraction at Outco, a medical cannabis producer in Southern California, one of their hazard analyses takes place at the drying and curing stage. “When we get our flower from harvest, we have to think about the drying and curing process, where mold and bacteria can spoil our harvest,” says Dr. Roggen. “That is the hazard we have to deal with.” So for Dr. Roggen and his team, the hazard they identified is the potential for mold and bacteria growth during the drying and curing process.

The next step in the HACCP system is to identify a critical control point. “Correct drying of the flower will prevent any contamination from mold or bacteria, which is a control point identified,” says Dr. Roggen. “We also have to prevent contamination from the staff; it has to be the correct environment for the process.” That might include things like wearing gloves, protective clothing and hand washing. Once a control point is identified, the third step in the process is to develop a critical limit for those control points.

A critical limit for any given control point could be a maximum or minimum threshold before contamination is possible, reducing the hazard’s risk. “When we establish the critical limit, we know that water activity below 0.65 will prevent any mold growth so that is our critical limit, we have to reach that number,” says Dr. Roggen. The fourth step is monitoring critical control points. For food manufacturers and processors, they are required to identify how they monitor those control points in a written HACCP plan. For Dr. Roggen’s team, this means using a water activity meter. “If we establish the critical control point monitoring, water activity is taken throughout the drying process, as well as before and after the cure,” says Dr. Roggen. “As long as we get to that number quickly and stay below that number, we can control that point and prevent mold and bacteria growth.”

One of the cultivation facilities at Outco

When monitoring is established and if the critical limit is ever exceeded, there needs to be a corrective action, which is the fifth step in a HACCP plan. In Dr. Roggen’s case, that would mean they need a corrective action ready for when water activity goes above 0.65. “If we don’t have the right water activity, we just continue drying, so this example is pretty simple,” says Dr. Roggen. “Normal harvest is 7 days drying, if it is not dry enough, we take longer to prevent mold or bacteria growth.”

The sixth step is establishing procedures to ensure the whole system works. In food safety, this often means requiring process validation. “We have to double check that our procedure and protocols work,” says Dr. Roggen. “Checking for water activity is only a passive way of testing it, so we send our material to an outside testing lab to check for mold or bacteria so that if our protocols don’t work, we can catch those problems in the data and correct them.” They introduced weekly meetings where the extraction and cultivation teams get together to discuss the processes. Dr. Roggen says those meetings have been one of the most effective tools in the entire system.

Dr. Roggen’s team identified worker safety as a potential hazard

The final step in the process is to keep records. This can be as simple as keeping a written HACCP plan on hand, but should include keeping data logs and documenting procedures throughout production. For Dr. Roggen’s team, they log drying times, product weight and lab tests for every batch. Using all of those steps, Dr. Roggen and his team might continue to update their HACCP plans when they encounter a newly identified hazard. While this example is simplistic, the conceptual framework of a HACCP plan can help detect and solve much more complex problems. For another example, Dr. Roggen takes us into his extraction process.

Dr. Roggen’s team, on the extraction side of the business, uses a HACCP plan not just for preventing contamination, but for protecting worker safety as well. “We are always thinking about making the best product, but I have to look out for my team,” says Dr. Roggen. “The health risk to staff in extraction processes is absolutely a hazard.” They use carbon dioxide to extract oil, which carries a good deal of risks as well. “So when we look at our critical control points we need to regularly maintain and clean the extractor and we schedule for that,” says Dr. Roggen.

Gloves, protective clothing, eyewear and respirators are required for workers in the extraction process.

“My team needs respirators, protective clothing, eyewear and gloves to prevent contamination of material, but also to protect the worker from solvents, machine oil and CO2 in the room.” That health risk means they try and stay under legal limits set by the government, which is a critical limit of 3,000 ppm of carbon dioxide in the environment. “We monitor the CO2 levels with our instruments and that is particularly important whenever the extractor is opened.” Other than when it is being opened, Dr. Roggen, notes, the extractor stays locked, which is an important worker safety protocol.

The obvious corrective action for them is to have workers leave the room whenever carbon dioxide levels exceed that critical limit. “We just wait until the levels are back to normal and then continue operation,” says Dr. Roggen. “We updated our ventilation system, but if it still happens they leave the room.” They utilize a sort of double check here- the buddy system. “I took these rules from the chemistry lab; we always have two operators working on the machine on the same time, never anyone working alone.” That buddy check also requires they check each other for protective gear. “Just like in rock climbing or mountain biking, it is important to make sure your partner is safe.” He says they don’t keep records for employees wearing protective gear, but they do have an incident report system. “If any sort of incident takes place, we look at what happened, how could we have prevented it and what we could change,” says Dr. Roggen.

He says they have been utilizing some of these principles for a while; it just wasn’t until recently that they started thinking in terms of the HACCP conceptual framework. While some of those steps in the process seem obvious, and it is very likely that many cannabis processors already utilize them in their standard operating procedures and quality controls, utilizing the HACCP scheme can help provide structure and additional safeguards in production.

Soapbox

Quality Controls and Medical Cannabis: What We Can Learn from Pharma

By Dr. Ginette M. Collazo
1 Comment

When we discuss growing and producing medical cannabis, we must think of it as a medicine. By definition, it is a substance intended to assist you with a medical condition, to help you feel better and not harm you. Drugs produced in the pharmaceutical industry go through extensive quality controls to ensure a level of safety for the consumer or patient. Yet when we talk process and quality controls in medical cannabis production, there is still a lot to learn.

Are we waiting for the wake-up call? Well, ring! Recently Health Canada, the regulatory body overseeing Canada’s medical cannabis market, decided that “It will begin random testing of medical marijuana products to check for the presence of banned pesticides after product recalls affecting nearly 25,000 customers led to reports of illnesses and the possibility of a class action lawsuit.”

Proper quality controls help protect businesses from unforeseen issues like those massive recalls in Canada. These can assure that the product is safe (won’t harm you), has integrity (free of contamination), and that the product is what it says it is (identity). To achieve this important goal, we must have robust systems that will guarantee product quality. Why is this important? Quality controls can ensure a safer and more consistent product, helping build patient and consumer trust and brand loyalty, preventing a public relations nightmare like a recall due to pesticide contamination.

Food processing and sanitation
Product recalls due to manufacturing errors in sanitation cause mistrust among consumers.

The FDA, among other regulatory bodies, has established excellent guidelines to implement these controls. So there is a lot we can learn from the pharmaceutical industry and that FDA guidance regarding quality controls and assurance. After all, we are all interested in the same thing: a safe and effective product.

So, let’s take a look at some of the controls included in the CFR (Code of Federal Regulation), Part 211 , which include Good Manufacturing Practices (GMPs) for finished products, and how you can implement them in the growing business of growing cannabis.

  1. Personnel selection and training: The GMPs establish that “Each person engaged in the manufacture, processing, packing, or holding of a drug product shall have education, training… to enable that person to perform the assigned functions.” These include the creation of specific curricula per position and the establishment of requirements for specialized tasks. We all want to be successful so training, in this case, is what we call the vaccine for mistakes.
  2. Facilities: “Any building or buildings used in the manufacture, processing, packing, or holding of a drug product shall be of suitable size, construction, and location to facilitate cleaning, maintenance, and proper operations.” This requirement includes segregation of spaces to avoid cross-contamination, housekeeping, the cleaning process and detergent types, material storage conditions, humidity levels, temperature, water, and even ventilation requirements to prevent contamination with microorganisms. All with the intention of protecting the product.
  3. Pest control: “There shall be written procedures for the use of suitable rodenticides, insecticides, fungicides, fumigating agents, and cleaning and sanitizing agents. Such written procedures shall be designed to prevent the contamination of equipment, components, drug product containers, closures, packaging, labeling materials, or drug products and shall be followed.” There have been many issues pertaining this requirement. In 2010, Johnson & Johnson received many complaints claiming that the product had a musty, moldy odor. Later, the firm identified the cause of the odor to be a chemical, called 2, 4, 6-Tribromoanisole or TBA; a pesticide used to treat wooden pallets. One of the specific requirements of this section is to avoid the use of wooden pallets, but if you decide to use them, the method of sterilization by heat treatment seems like the only safe option for sterilizing wooden pallets and wood cases.
  4. Equipment/Instrumentation: “Equipment used in the manufacture, processing, packing, or holding of a drug product shall be of appropriate design, adequate size, and suitably located to facilitate operations for its intended use and its cleaning and maintenance.” The intention is to not alter the safety, identity, strength, quality, or purity of the drug product beyond the official or other established requirements. What would happen if lubricants/coolants or any other substance, not intended to be part of the product, comes in contact with the product?
  5. Procedures and documentation: “There shall be written procedures for production and process control designed to assure that the drug products have the identity, strength, quality, and purity they purport or are represented to possess. Such procedures shall include all requirements of this subpart. These written procedures, including any changes, shall be drafted, reviewed, and approved. When we have followable, well written, clear, and specific procedures, we avoid possible errors that can get us in trouble.
  6. Defects Investigation: “Written production and process control procedures shall be followed in the execution of the various production and process control functions and shall be documented at the time of performance. Any deviation from the written procedures shall be recorded and justified.” We want to be successful, for that we need to learn from failures, understanding the root causes, correcting and preventing re-occurrence is what will keep you competitive. As you can see this requirement is essential for, quality, business and to evidence that such deviations did not adulterate the product.
  7. Process controls: Besides written procedures and deviations management, operation controls are pivotal in guaranteeing the quality as well as complete documentation of your process. These controls will vary depending on your technology and your product. If you do alcohol (ethanol) extraction, for example,  you want to keep an eye on the temperature, dissolution time, and even have color standards to be able to quickly and correctly identify possible abnormalities, while you can still correct the mistake. In-process product testing will allow you to monitor “performance of those manufacturing processes that may be responsible for causing variability in the characteristics of in-process material and the final product.”

Regardless of federal regulatory guidance, quality controls can be that one factor which can make or break your business. Why re-invent the wheel?

California Releases Draft Medical Cannabis Regulations

By Aaron G. Biros
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Last week, Governor Brown’s Administration released a set of proposed rules for the medical cannabis, attempting to provide some oversight to the once unregulated market. In 2015, the governor signed three bills into law that established a regulatory framework via the Medical Cannabis Regulation and Safety Act. That legislation set up the Bureau of Medical Cannabis Regulation inside the Department of Consumer Affairs as the overseeing regulatory agency.

According to the press release, the proposed regulations for manufacturing and cultivation have also been published. “The proposed licensing regulations for medical cannabis are the result of countless hours of research, stakeholder outreach, informational sessions and pre-regulatory meetings all across the state,” says Lori Ajax, chief of the Bureau of Medical Cannabis Regulation. “And while we have done quite a bit of work and heard from thousands of people, there is still so much more to do. In order to make our program successful we still need your feedback.”

According to their website, the legislation divides responsibility for licensing businesses between three regulatory bodies: The CA Department of Food and Agriculture the CA Department of Public Health and the Bureau of Medical Cannabis Regulation, which will be the leading body in charge of licensing. The proposed regulations are not set in stone, but give us an important glimpse into how the state hopes to regulate the market.

Among the proposed rules are a number of regulatory compliance nuances expected to raise prices, but provide extra measures to protect consumer safety. According to the SF Gate, regulators expect prices could climb $524 per pound. But with that price jump comes a lot of regulations that other states have so far successfully implemented. The laboratory testing and traceability stipulations are presumably designed to safeguard public health, preventing things like black market diversion and off-label pesticide use.

The proposed ‘cannabis product symbol’

In addition to the medical regulations, the proposed manufacturing regulations set some notable requirements. Those rules are set by the Office of Manufactured Cannabis Safety, established in the Center for Environmental Health of the California Department of Public Health (CDPH) after the 2015 legislation was signed into law. Good Manufacturing Practices, food product standards, operational and labeling requirements are included in the provisions, along with a list of licensing tiers, application requirements and fees. They have a handy summary of the proposed regulations for those looking for the key highlights.

Omar Figueroa, an attorney with a cannabis law practice in California, says his clients in the industry are preparing to suggest changes to the proposed regulations and possibly legal challenges. “They are looking at this as overregulation by people that are not in the cannabis industry,” says Figueroa. “These are outsiders with a limited knowledge base creating somewhat uninformed regulations.” He says a good example of this is the potency limit on infused products. “They make perfect sense for [the recreational market] but for the medical market it is simply unacceptable. Patients develop a tolerance to THC and would have to increase their caloric intake and buy more infused products if this proposed regulation becomes final.” He says there are a number of regulations that seem kind of arbitrary. “Like prohibiting cannabis-infused caffeine products; there doesn’t seem to be a necessity in the rulemaking for this,” says Figueroa. “A lot of these regulations are going to be susceptible to challenges because California requires regulations to be necessary and alternatives to be considered.”

Although the lab testing regulations won’t be published for another few days, Figueroa expects them to be a huge disruptor for the market. “Most labs in the state are not ISO 17025-accredited, which means many labs might not be able to issue certificates of analysis when the regulations get enforced,” says Figueroa. He says it is safe to say California regulators are looking at other jurisdictions, like Colorado and Oregon for example, in crafting these rules, but we can expect a sea change in these regulations before they get enforced.

Manufacturers will be required to use a cannabis product symbol with a ‘THC!’ marking on their labels. There is also a 100-milligrams-per-package limit for THC in infused products, which is similar to rules we saw Colorado and Oregon roll out during a preliminary period of legal recreational cannabis.

For those looking to get involved in the regulatory process, there is a 45-day comment period on the proposed rules.

Soapbox

Human Error? No Problem

By Dr. Ginette M. Collazo
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If you are in the business of growing cannabis, you should be aware of the common reasons for production losses, how to address root causes and how to prevent future occurrences in a sustainable way. Human error is the number one root cause identified in investigations for defects in the cultivation business. Sadly, little is known about the nature of these errors, mainly because our quest for the truth ends where it should begin, once we know it was a human error or is “someone’s fault.”

Yes, human error usually explains the reason for the occurrence, but the reason for that error remains unexplained and consequently the corrective and preventive actions fail to address the underlying conditions for that failure. This, in turn, translates into ineffective action plans that result in creating non-value added activities, wasting resources and money as well as product.

Human error can occur when workers are in direct contact with the plant

So after investigating thousands of human error events and establishing systems to improve human reliability in manufacturing facilities, it became even clearer to me, the need to have good, human-engineered standard operating procedures (SOPs).

In the cannabis growing process, there are different types of mistakes that, when analyzed, all can be addressed in the same manner. For example, some common errors that we see are either overwatering or nutrient burn, which can occur when the plant is overfed. The same is true in the opposite scenario; underfeeding or under watering lead to problems as well. If your process is not automated, the reason for these failures was most likely human error. Now, why did the person make that mistake? Was there a procedure in place? Was the employee trained? Is there a specific process with steps, sub-steps, quantities and measures? Were tools available to be able to do the task correctly? There is so much that can be done about these questions if we had clear, well-written and simple, but specific instructions. The benefits greatly outweigh the effort required.

Also, besides providing step-by-step instructions to avoid commission errors (to perform incorrectly as opposed to omit some step), there are other types of errors that can be avoided with SOPs.

Decision making like detecting nutrient deficiencies can lead to human error.

Decision-making is another reason why we sometimes get different results than the ones expected. If during your process there are critical, knowledge-based decisions, workers need to be able to get all the information to detect as well as correct situations. Some decisions are, for example, when (detection) and how (steps) should I remove bud rot? Is there a critical step in the process (caution) to avoid other plants from becoming affected? Any information on the what, how, when, where and why reduces the likelihood of a decision error, later described as obvious.

When we face manufacturing challenges like nutrient deficiency in a particular stage, mold, fungus, gnats or even pollination of females, we want to do whatever we can to prevent it from happening again. So consider that from avoiding to detecting errors, procedures are a critical factor when improving human performance.

Here are some guidelines when writing procedures to prevent human error.

  1. Use them. Enforce the use of procedures at all times. As humans, we overestimate our abilities and tend to see procedures as an affront to our skills.
  2. Make sure it is a helpful procedure and users are involved in the process. People that participate in writing rules are more likely to follow them.
  3. Make sure they are available for their use.
  4. All critical activities should have a procedure.
  5. The procedure needs to be clear, have a good format, clear graphics, appropriate level of detail and specific presentation of limits.
  6. Make sure that facts, sequence and other requirements are correct and all possible conditions are considered e.g. “what if analysis”.

Human error won’t be eradicated unless we are able to really identify what is causing humans to err. If eliminating or “fixing” the actual individual eliminates or potentially reduces the probabilities of making that mistake again, then addressing the employee would be effective. But if there is a chance that the next in line will be able to make the same mistakes, consider evaluating human factors and not the human. Take a closer look and your process, system and ultimately your procedures.

Operational Inefficiencies in Commercial Cannabis Cultivation

By Drew Plebani
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From the perspective of sustainable cannabis cultivation models, it seems clear that outside of the particular cultivation methodology adopted, that operational efficiency and the implementation of lean manufacturing principles will be necessary for successful and truly “sustainable” businesses, in the current, ever growing, cannabis space.

Implementing lean manufacturing principles as an integral part of the cannabis cultivation facility just makes sense- it is a manufacturing operation after all. From a lean perspective, doing away with the non-value-added costs in the supply chain and production model are quite important.

Let’s look at this case study as evidence for the necessity of operational efficiency:

A 300-light flowering, indoor cultivation facility in Colorado.

The system was purchased with ongoing pest/disease issues, recent updates to Colorado’s approved pesticide list, had prompted the implementation of an updated integrated pest management (IPM) program, which had been moderately successful in developing an albeit short-term solution to keeping ongoing root aphids, powdery mildew, and botrytis, to name a few, at bay.

This existing facility was producing roughly 60 pounds of trimmed cannabis per week, equivalent to almost $6M annual gross, however they were losing a percentage of their yields to product that did not pass Colorado’s contaminant testing requirements.

It is important to note that any deviation from the existing manufacturing schedule and system would create a change to the potential productivity of the system, for better or worse.

At the most basic level, one would hope that a new operator taking over an existing facility would analyze the system and implement incremental or perhaps major changes to create more efficient and profitable outcomes. That being said, currently the average grower likely doesn’t have much understanding of the lean manufacturing process. That will undoubtedly change.

When we look at basic manufacturing facility operations, on an annual gross potential basis, each daily task not completed on the existing manufacturing timeline is, at least, a 0.3% (1/365) loss in potential productivity. In monetary terms, for this particular facility, each 0.3% equates to a potential $18,000 in lost productivity.

The information that follows is taken from observations during the first week of this facility ownership transition and below is a generalized outline representing just one aspect of the operational inefficiencies (created or existing) that were observed :

  • Plant group A put into flowering 4 days behind schedule (4 days x 0.3%) =1.2%
  • Plant group B transplanted 3 days behind =0.9%
  • Plant group C transplanted 7 days behind =2.1%
  • Plant group D (clones) taken 7 days behind =2.1%
  • IPM applications not completed for 7+ days

That equals a 6.3% loss in potential annual productivity, which translates into a rough estimate of up to $378,000 in lost revenue.

Changes to the nutrient program in the midst of the plant’s life cycle had created nutrient deficient plants in all stages of vegetative and flowering growth, coupled with changes to the existing IPM program, all add to the potential losses incurred. Deviations in the plant nutrition program and IPM scheduling are hard to quantify mid-cycle, but will certainly be quantifiable when the hard numbers come home to roost.

These inefficiencies, once compounded, could potentially equal more than a 20% loss in potential productivity during the subsequent 3.5 month plant cycle. The current 60 pounds-per-week would likely be reduced for the next 2 months, down to roughly 50 pounds, or even much less, per-week. This could become a loss upwards of $500,000 in annual potential revenue in the first quarter of operation alone.

These seemingly small and incremental delays in the plant production cycle are all greatly compounded. The end result is that each subsequent cycle of plants is slightly smaller due to delays in transplanting and less days at maximized vegetative growth, etc. Undoubtedly, the cumulative effect of these operational inefficiencies creates a significant drop in the existing level of productivity, with the end result being a significant, undesired loss of revenue.

The sum of the lessons learned from this cultivation facility, is this: a sustainable operation, in the most pragmatic sense, is an efficient one both in terms of productivity and in terms of the carbon footprint and waste generated. The more streamlined and successful the operations are, the greater likelihood of success. Perhaps all of this is to say don’t forget about all the little parts that make up the whole, and strive to create a work environment/corporate culture that empowers your employees, your managers and all involved to participate and contribute to the process of improving the operations for mutual benefit.

Lessons learned from the aerospace manufacturing industry: Even the smallest zip tie on a spaceship matters! Some food for thought: If it’s truly beneficial it should stick around… If it is beneficial and it’s not sticking around, then there are limiting factors in the system that need to be addressed.