Science and Research Committee on Oct. 1st, 2024

Defining disincentives could be different, depending on the vantage point. With the introduction of producer responsibility, one of its objectives was in fact to disincentivize or incent, depending on which side of the coin you're looking at, producers and manufacturers to look at better designed goods, be it swapping out materials for a better choice or maybe refill or reuse. Then sort of, lastly, it was about really understanding the costs of the system. Before there was producer responsibility, industry had no idea how much municipalities and taxpayers were actually spending on blue boxes.

There are opportunities for us to look at costing pollution. A great example of that is charging for plastic bags at the point of sale. I was involved many moons ago, when the provincial Government of Ontario was contemplating banning plastic bags. There was, obviously, a reaction by the retail sector, as we would expect, and the plastic manufacturers of plastic bags. In lieu of banning them from sale, they worked with the province, and us as a convenor in that discussion, to look at other mechanisms.

What they committed to was actually reducing the supply of plastic bags to consumers by half at a certain time frame. They exceeded that time frame, and they exceeded that amount. Many of them actually priced a plastic bag and offered a reusable one, which we now know is really quite successful. In fact, it carved the runway for the federal government, the Government of Canada, to come in and effectively ban them as a single-use item.

Disincentives and pricing pollution can be a very effective tool to incent the kind of behaviour you want and not to incent the behaviour you don't, and that's at every level.

Good afternoon, everyone.

My name is Éric Leclair, and I am the director of plastic processing at Coalia.

Coalia is a college centre for technology transfer in Quebec, and the only centre specializing in plastics. We are a technology access centre and the only one working in the plastic manufacturing sector in all of Canada. Coalia is a non-profit organization, located at the Cégep de Thetford, in Quebec, and has about 35 employees.

We are active in a variety of sectors, and plastics recycling is an important activity for our organization. We do work for the entire supply chain, whether it be municipal sorting centres, recyclers, users, process managers who mould new parts, or industries that generate plastic waste.

We find the best ways to recycle polymers. We have a wide range of recycling transformation tools. We have good labs specialized in identifying characteristics. We also collaborate with various universities, as well as other organizations such as Recyc-Québec and Éco Entreprises Québec. At the Canadian level, we conduct activities with the Circular Plastics Taskforce.

Having said that, I have no idea why I was called here today.

Thank you.

Good evening, honourable members of the committee. I am Sarika Kumari, CEO of BioLabMate. It is an honour to speak with you today on the subject of innovation, science and research in recycling plastics, with a particular emphasis on the critical issue of plastic waste generated in research labs and medical facilities.

Globally, we generate approximately 300 million tonnes of plastic waste annually, with a significant portion attributed to the medical and research sector. The COVID-19 pandemic has intensified this challenge, increasing reliance on PPE, testing kits and other disposable plastic items. Research labs alone contribute around 5.5 million tonnes of plastic waste each year, a number equivalent to the total plastic waste output of some small countries.

Single-use plastic in research labs remains a significant but frequently overlooked problem. For instance, a single lab can produce around 44,600 pieces of single-use plastic monthly, depending on the size of the lab, costing in Canadian dollars between $14,000 and $18,000 and weighing up to 60 kilograms or 80 kilograms. When you scale across entire university and research institutes, the magnitude of the problem becomes clear.

At BioLabMate we conducted extensive market research, engaging with over 100 potential customers in research and health care settings. Through this process, we identified bioplastics as a viable and sustainable solution. Our focus is on utilizing locally available renewable resources, specifically seaweed, to create bioplastic that can replace traditional single-use plastic items seamlessly.

While recycling has long been promoted as a solution to plastic waste, it is not enough to address the scale of the issue. Recycling is often hindered by several challenges—for example, contamination. Plastics mixed with food and other waste are difficult to recycle effectively. There are infrastructure gaps. Canada's recycling infrastructure is insufficient for the handling of all recyclable materials. There's also downcycling. Plastics often degrade in quality after recycling, making them unsuitable for reuse in precision environments like research labs.

To address the challenges, we recommend stricter regulations on what types of plastics can be recycled, investment in advanced recycling technologies, and public education, particularly in the research lab, to improve recycling practices and reduce contamination.

At BioLabMate we view bioplastics as a crucial part of the solution to plastic waste in research labs. Unlike conventional plastics derived from fossil fuels, bioplastics are made from such renewable resources as seaweed. These bioplastics are designed to be biodegradable or compostable, significantly reducing their environmental impact. Our seaweed-based bioplastics are ideal for replacing single-use items in labs, such as tips, plates and tubes, thereby cutting both waste and carbon emissions.

Seaweed as the primary material for our bioplastics offers a host of benefits. For example, on environmental impact, seaweed is a rapidly renewable resource that absorbs CO2, helping to mitigate climate change. It grows without fresh water, fertilizers or pesticides, making it a sustainable alternative to land-based crops. In terms of the economic opportunity, seaweed farming provides a new source of revenue for coastal communities, especially in Atlantic Canada, offering job creation and economic diversification.

Despite the potential of bioplastics, there are hurdles to overcome. For example, there's the cost. Currently, bioplastics are more expensive than traditional plastics, but we anticipate that costs will decrease with growing demand and increased production. In terms of infrastructure, the limited number of industrial composting facilities in Canada hinders the proper degradation of these bioplastics. There's also R and D support. Continued research is essential to improve the performance and cost-effectiveness of bioplastics.

We urge the government to provide grants and subsidies for companies like BioLabMate that are developing sustainable alternatives; mandate the use of bioplastics in high-risk sectors, particularly health care and research; support research and development to accelerate bioplastics adoption; and expand composting infrastructure to ensure that bioplastics are processed correctly.

Recycling alone cannot solve Canada's plastic waste crisis. A combined approach of improved recycling practices and the adoption of bioplastics is essential. BioLabMate’s seaweed-based bioplastics offer a sustainable and scalable alternative, particularly for the research and medical sectors. With government support, Canada can lead the transition to a circular economy, significantly reducing both plastic waste and its environmental impact.

Thank you for your time. I look forward to your questions.

This is our product, and we are doing a patent on it. We don't know exactly how much it would cost if we compare it to the fossil fuel plastic. However, it's not that costly. The polymer has two grades. One is when you work with the research lab grade, and one is when it makes it to the commercial base. Seaweed biopellets are near to the same as you would count research-grade pellets.

Yes, bioplastic is.... It's very common now, saying “bioplastic, bioplastic”. However, bioplastic is not bioplastic until it is biodegradable and biocompostable, like it's home compostable. We at BioLabMate are making the biopellets that are home compostable. It should be compostable. It should not need any industrial set-up to compost it in a big area.

Yes. As we know, people have used seaweed in their backyards to grow their plants. Yes, it's going to go in the soil, and it's actually going to go as a fertilizer in the soil.

That's the goal.

I feel that recycling is one option, but it is not the very best option. Any which way, what we are doing is, again, grinding those plastics, and it's going to stay in there. As bioplastic, we are are making it, and it's going to the end use. Then, it's just going into nature again. It's not going to hamper—

Thank you for that question.

I think the standardization of packaging for a broad spectrum of products is a pretty hefty ask. I think, within product categories, certainly we are seeing efforts to standardize certain product packaging. However, producers need the opportunity to define and to determine the best material that suits their particular product, whether it is food product, beverage, consumer goods or a medical device or health product. They need to make sure that their consumer can afford it and will accept it.

There are a lot of considerations that go into the packaging decisions. We hear the conversation on standardization. I would just tell you that we are working with a common set of principles to improve recyclability by design.