Tag Archives: Stephen Lougheed

Ceapro (a Canadian biotech company) and its pressurized gas expanded technology with a mention of cellulose nanocrystals

At the mention of cellulose nanocrystals (CNC), my interest was piqued. From a Nov. 10, 2015 news item on Nanotechnology Now,

Ceapro Inc. (TSX VENTURE:CZO) (“Ceapro” or the “Company”), a growth-stage biotechnology company focused on the development and commercialization of active ingredients for healthcare and cosmetic industries, announced that Bernhard Seifried, Ph.D., Ceapro’s Senior Research Scientist and a co-inventor of its proprietary Pressurized Gas Expanded Technology (PGX) will present this morning [Nov. 10, 2015] at the prestigious 2015 Composites at Lake Louise engineering conference.

A Nov. 10, 2015 Ceapro press release, which originated the news item, describes the technology in a little more detail and briefly mentions cellulose nanocrystals (Note: A link has been removed),

Dr. Seifried will make a podium presentation entitled, “PGX – Technology: A versatile technology for generating advanced biopolymer materials,” which will feature the unique advantages of Ceapro’s enabling technology for processing aqueous solutions or dispersions of high molecular weight biopolymers, such as starch, polysaccharides, gums, pectins or cellulose nanocrystals, into open-porous morphologies, consisting of nano-scale particles and pores.

Gilles Gagnon, M.Sc., MBA, President and CEO of Ceapro, stated, “Our disruptive PGX enabling technology facilitates biopolymer processing at a new level for generating unique highly porous biopolymer morphologies that can be impregnated with bioactives/APIs or functionalized with other biopolymers to generate exfoliated nano-composites and novel advanced material. We believe this technology will provide transformational solutions not only for our internal programs, but importantly, can be applied much more broadly for Companies with whom we intend to partner globally.”

Utilizing its PGX technology, Ceapro successfully produces its bioactive pharmaceutical grade powder formulation of beta glucan, which is an ingredient in a number of personal care cosmeceutical products as well as a therapeutic agent used for wound healing and a lubricative agent integrated into injectable systems used to treat conditions like urinary incontinence. The Company is developing its enabling PGX platform at the commercial scale level. In order to fully exploit the use of this innovative technology, Ceapro has recently decided to further expand its new world-class manufacturing facility by 10,000 square feet.

“The PGX platform generates unique morphologies that are not possible to produce with other conventional drying systems,” Mr. Gagnon continued. “The ultra-light, highly porous polymer structures produced with PGX have a huge potential for use in an abundant number of applications ranging from functional foods, nutraceuticals, drug delivery and cosmeceuticals, to advanced technical applications.”

Ceapro’s novel PGX Technology can be utilized for a wide variety of bio-industrial processing applications including:

  • Dry aqueous solutions or dispersions of polymers derived from agricultural and/or forestry feedstock, such as polysaccharides, gums, biopolymers at mild processing conditions (40⁰C).
  • Purify biopolymers by removing lipids, salts, sugars and other contaminants, impurities and odours during the precipitation and drying process.
  • Micronize the polymer to a matrix consisting of highly porous fibrils or spherical particles having nano-scale features depending on polymer molecular structure.
  • Functionalize the polymer matrix by generating exfoliated nano-composites of various polymers forming fibers and/or spheres simply by mixing various aqueous polymer solutions/dispersions prior to PGX processing.
  • Impregnate the polymer matrix homogeneously with thermo-sensitive bioactives and/or hydrophobic modifiers to tune solubility of the final polymer bioactive matrix all in the same processing equipment at mild conditions (40⁰C).
  • Extract valuable bioactives at mild conditions from fermentation slurries, while drying the residual biomass.

The highly tune-able PGX process can generate exfoliated nano-composites and highly porous morphologies ranging from sub-micron particles (50nm) to micron-sized granules (2mm), as well as micro- and nanofibrils, granules, fine powders and aerogels with porosities of >99% and specific surface areas exceeding 300 m2/gram. The technology is based on a spray drying method, operating at mild temperatures (40°C) and moderate pressures (100-200 bar) utilizing PGX liquids, which is comprised of a mixture of food grade, recyclable solvents, generally regarded as safe (GRAS), such as pressurized carbon dioxide and anhydrous ethanol. The unique properties of PGX liquids afford single phase conditions and very low or vanishing interfacial tension during the spraying process. This then allows the generation of extremely fine particle morphologies with high porosity and a large specific surface area resulting in favorable solubilisation properties. This platform drying technology has been successfully scaled up from lab scale to pilot scale with a processing capacity of about 200 kg/hr of aqueous solutions.

Ceapro is based in Edmonton in the province of Alberta. This is a province with a CNC (cellulose nanocrytals) pilot production plant as I noted in my Nov. 10, 2013 posting where I belatedly mentioned the plant’s September 2013 commissioning date. The plant was supposed to have had a grand opening in 2014 according to a Sept. 12, 2013 Alberta Innovates Technology Futures [AITF] news release,

“Alberta Innovates-Technology Futures is proud to host and operate Western Canada’s only CNC pilot plant,” said Stephen Lougheed, AITF’s President and CEO. “Today’s commissioning is an important milestone in our ongoing efforts to provide technological know-how to our research and industry partners in their continued applied R&D and commercialization efforts. We’re able to provide researchers with more CNC than ever before, thereby accelerating the development of commercial applications.”

Members of Alberta’s and Western Canada’s growing CNC communities of expertise and interest spent the afternoon exploring potential commercial applications for the cellulose-based ‘wonder material.’

The CNC Pilot Plant’s Grand Opening is planned for 2014. [emphasis mine]

I have not been able to find any online trace of the plant’s grand opening. But I did find a few things. The AITF website has a page dedicated to CNC and its pilot plant and there’s a slide show about CNC and occupational health and safety from members of Alberta’s CNC Pilot Plant Research Team for their project, which started in 2014.

No mention in the Alberta media materials is ever made of CelluForce, a CNC production plant in the province of Québec, which predates the Alberta plant by more than 18 months (my Dec. 15, 2011 posting).

One last comment, CNC or cellulose nanocrystals are sometimes called nanocrystalline cellulose or NCC. This is a result of Canadians who were leaders at the time naming the substance NCC but over time researchers and producers from other countries have favoured the term CNC. Today (2015), the NCC term has been trademarked by Celluforce.

Alberta gave its cellulose nanocrystal (or nanocrystalline cellolose) production plant a soft launch in September 2013

It’s been a little over two years since Alberta’s proposed cellulose nanocrystal (CNC), then called nanocrystalline cellulose (NCC), pilot plant was first announced (my July 5, 2011 posting). I gather that the plant was quietly opened in Sept. 2013. Finding a news release about the event has proved to be a challenge. The Alberta Innovates website does not list it in its Newsroom while the Alberta Innovates Technology Futures website does list a news release (September 12, 2013Alberta’s one-of-a-kind CNC pilot plant commissioned: Cellulose-based ‘wonder material’ now available to researchers, industry partnersf), despite numerous efforts on my part (try it yourself), I’m unable to access it. Happily, I was able to track down some information elsewhere.

First (in the order in which I found the information), there’s an Oct. 2, 2013 news item on the WorkingForest.com website submitted by Pulp and Paper Canada),

Alberta’s cellulose nanocrystals (CNC) pilot plant, which produces up to 100 kilograms of CNC per week, was commissioned in early September at Alberta Innovates-Technology Futures’ (AITF) Mill Woods facility before a crowd of researchers, industry leaders and government representatives.

The $5.5-million pilot plant, created through a collaboration of the governments of Canada and Alberta in partnership with industry under the Western Economic Partnership Agreement (WEPA), uses wood and straw pulp from plants such as flax and hemp to create CNC for testing in commercial applications that will lead to production.

“Alberta Innovates-Technology Futures is proud to host and operate Western Canada’s only CNC pilot plant,” said Stephen Lougheed, AITF’s president and CEO. “We’re able to provide researchers with more CNC than ever before, thereby accelerating the development of commercial applications.”

The grand opening of the CNC pilot plant’s is planned for 2014.

Then, there was more information about the plant and the event in Catherine Griwkowsky’s Sept. 12, 2013 article for the Edmonton Sun,

A new cellulose nanocrystals (CNCs) pilot plant will take wood and agricultural fires and turn it into a form that can make products stronger, give them sunlight-absorbing properties, add a negative electromagnetic charge and more.

The $5.5-million project in Mill Woods will churn out up to 100 kilograms of the crystals each week.

Technical Lead Frank Tosto said researchers will study various properties of the crystals, and work with an internal team as well as external industry and other researchers to transform knowledge of the properties into ideas for applications. Later, the team may experiment with unconventional sources of cellulose.

The CNCs can be used for drilling fluids, paints, industrial coatings, automotive components, building materials, plastics and packaging.

The process [of refining hemp, etc.] breaks down cellulose into smaller building blocks using a chemical process of acid hydrolysis, that separates crystal formations in cellulose from other structures. The width is between five to 10 nanometres with a length of 150 to 200 nanometers. To scale, cellulose fibre would be the size of a hockey rink and the nano crystal would be like a pen or pencil, he explained.

Ultimately, Tosto hopes they will find commercial applications for the CNCs. The pilot should last five to seven years. He said it’s hard to think outside the box when they don’t know where all the boxes are.

I’d love to know if any of the entrepreneurs who contacted me privately about accessing CNC so they could develop new applications are now able to purchase product from the Alberta plant or from the one in Quebec (CelluForce), which had a stockpile last I heard (my Oct. 3, 2013 posting). It seems odd to be building another plant when the country’s first such plant has stopped production. Meanwhile, there’s some action on the international scene. An Israeli startup company, Melodea has developed its own CNC/NCC extraction process and has received money to develop applications, from my Oct. 31, 2013 posting),

Melodea Ltd. is developing an economic ally viable industrial process for the extraction of NCC from the sludge of the paper industry, a waste stream produced at millions of tons around the world. The core of the novel technology was developed by the lab of Professor Oded Shoseyov from the Hebrew University of Jerusalem and was licensed exclusively to Melodea.

Moreover, the company develops unique technologies to self-assemble the NCC into ecologically friendly foams for industrial applications.

Melodea Ltd. announced today that it has been awarded above 1,000,000 Euro in 3 projects of the European Union Seventh Framework Program (FP7).

You’ll note Melodea’s process extracts CNC from the paper industry’s sludge which leads me to this question: will there be any discussion of this extracting CNC from sludge technique at the 2014 TAPPI (Technical Association for the Pulp, Paper, Packaging and Converting Industries) nanotechnology conference being held in Vancouver (Canada), June 23-26, 2014 (mentioned in my Nov. 14, 2013 posting about the conference’s submission deadline, Nov. 22, 2013)?