ACCN, the Canadian Chemical News: Nov | Dec 2011 by Chemical Institute of Canada

November • December | novembre • décembre 2011

Canadian Chemical News | L’Actualité chimique canadienne A Magazine of the Chemical Institute of Canada and its Constituent Societies | Une magazine de l’institut de chimie du canada et ses sociétés constituantes

Body of Work

Molly Shoichet gets creative with regeneration

The big desalination sell Rubber Renaissance

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Chemical

Table of Contents

Features

November • December | novembre • décembre Vol.63, No./No 10

Chemical Engineering

Business

Body of Work

University of Toronto’s Molly Shoichet is tilling the field of regenerative medicine, which seeks to stimulate human organs to self-repair. By Peter Calamai

Chemistry

Reinventing Rubber

The rubber meets the road at the new LANXESS AG centre for R&D in London, Ont. By Tyler Irving Pour obtenir la version française de cet article, écrivez-nous à magazine@accn.ca

Departments

Salt-lution

A thirsty world dependent upon desalination is a glass half full to a Vancouver pair with an ingenious solution. By Tyler Hamilton

From the Editor

Guest Column By Karen Burke

hemical News C By Tyler Irving

Society News

ChemFusion By Joe Schwarcz

november • December 2011 CAnadian Chemical News 3

FRom the editor

Executive Director

olly Shoichet is not quite a household name. But it seems inevitable that this University of Toronto professor of chemical engineering and applied chemistry is well on her way to joining the ranks of such Canadian icons as Banting and Best, whose discovery of insulin earned them an enduring place not only in the annals of science but the hearts of Canadians. Shoichet has already captured the national imagination with her research into regenerative medicine technologies, which have the ultimate goal of stimulating human organs to repair themselves, promising mobility for those with spinal cord injuries and renewed health for those with diabetes, cancer or heart disease. A few months ago, Shoichet was awarded an Order of Ontario, adding to a veritable charm bracelet of endowments that includes Canada Research Chair in Tissue Engineering, Fellow of the Royal Society of Canada and of the American Association for the Advancement of Science, as well as Killam and Steacie fellowships. Such laurels, however, have not lulled Shoichet into a more leisurely research pace. Her latest groundbreaking work, the creation of three-dimensional protein-patterned scaffolds for tissue engineering, was the cover story in last month’s Nature Materials. And while ACCN may not have quite the same international stature as Nature, we are proud nonetheless to present an update on Shoichet’s research in our cover story “Body of Work.” Equally laudable is a breakthrough by Saltworks Technologies co-founders Joshua Zoshi and Ben Sparrow, who have engineered a deceptively clever new method of desalination, as described in the feature “Salt-lution.” This Vancouver invention is sure to help alleviate serious water shortage and pollution problems throughout the world. Finally, the chemistry family as a whole bids farewell to the United Nations’ International Year of Chemistry. ACCN was honoured to record the creative outreach initiatives undertaken across the country by thousands of people in university departments, colleges, high schools, local CIC sections and industry. IYC may be over, but the good will and interest generated should be considered a building block for further outreach in 2012. As Karen Burke, president of the Canadian Society for Chemistry, discusses in this issue’s guest column, opportunities abound for chemists to participate in outreach activities. It is not outreach for outreach’s sake, however. Rather, young students need to be inspired to join the ranks of chemistry researchers because, as Burke points out, “society cannot survive without chemists.”

Roland Andersson, MCIC

ACTING EDITOR

Roberta Staley

Editor (on leave)

Jodi Di Menna

news editor

Tyler Irving, MCIC

contributing editor

Tim Lougheed

art direction & Graphic Design

Krista Leroux Kelly Turner

Society NEws

Bobbijo Sawchyn, MCIC Gale Thirlwall

Marketing Manager

Bernadette Dacey

Marketing Coordinator

Luke Andersson

Circulation

Michelle Moulton

Finance and Administration Director

Joan Kingston

Membership Services Coordinator

Angie Moulton

Editorial Board

Joe Schwarcz, MCIC, chair Milena Sejnoha, MCIC Bernard West, MCIC

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Ichikizaki Fund for Young Chemists The Ichikizaki Fund for Young Chemists provides financialassistance to young chemists who show unique achievementsin basic research by facilitating their participationin international conferences or symposia.

Eligibility: • be a member of the Canadian Society for Chemistry or the Chemical Society of Japan; • not have passed his/her 34th birthday as of December 31 of the year in which the application is submitted; • have a research specialty in synthetic organic chemistry; • be scheduled to attend, within one year, an international conference or symposium directly related to synthetic organic chemistry. Conferences taking place in January to March of each year should be applied for a year in advancein order to receive funding in time for the conference.

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Chemists must inspire young students By Karen Burke

ompanies cutting their R&D budgets. Pharmaceutical research facilities being closed across Canada. A recent article on the website BNET listed 10 “High Paying Jobs with No Future.” Number eight on their list? Chemist. Should we still recommend that students study science? Sir Harold Kroto, 1996 Nobel Prize winner in chemistry, says that “science is the only way we can understand truth.” From his perspective, it is an ethical issue — we must teach science to children so they learn how to assess claims based on evidence, not blind faith. Clearly that is important, but can it translate to a career? There is concern in Canada that you may have to abandon your science studies to have a successful career. While chemistry jobs in the pharmaceutical industry may be fewer than in past years, they still exist. Even if one follows a non-traditional career path for a chemist, we rarely “leave it behind.” We build on our science background as a lawyer, a regulatory affairs professional, a clinical researcher, or a CEO. A science education provides skills that support success in a career: the ability to think critically, to communicate effectively and to solve problems. I think a science background is beneficial not only for the individual, but important for the economic health and growth of our country. I am not alone in this belief: nearly 90 per cent of Canadians believe that young people’s interest in science is essential for the country’s future prosperity. The issue may not be in what to do with a science degree, but rather how to get students interested in science in the first place. So where do we stand in Canada? A 2010 Angus Reid survey found that only 37 per cent of Canadian teenagers aged 16 to 18 are interested in taking a science course at the post-secondary level — and these are students currently enrolled in at least one high school science course. And while 82 per cent of Canadian teenagers recognize that studying science opens many different career options, only four per cent of them perceive people working in science-related professions as ‘cool.’ How can we shift that perception? I offer a few suggestions: • Support science education. The company where I work, Amgen Canada, is strongly committed to science education. To that end, Amgen honours outstanding science teachers with the Amgen Award for Science Teaching Excellence (AASTE). In 2011, four teachers across Canada received this award, which consists of a $5,000 unrestricted grant for

the teacher and a $5,000 grant for their school to be used to fund science education. This type of recognition promotes and rewards excellence in science teaching, while helping attract bright young minds to science. It would be a positive step if even more support would come to our valuable science teachers from industry. But of course, the future of our children is not all in the hands of the school teacher. • Get involved. Numerous opportunities exist for chemists to participate in outreach activities in their communities, such as: • Local Chemical Institute of Canada sections or public events like Edmonton’s Cafe CIC (contact this section for more details or ideas); • Offer your time to non-profit educational outreach groups. One such group is Let’s Talk Science, which provides resources and education programs that help inspire creativity, curiosity and a life-long love of science and learning in Canadian youth; • Volunteer to be a judge at a local science fair. Your science expertise will be greatly welcomed; • Be an ambassador. Learn how to speak about chemistry in simple language. Share the wonder that we feel about chemistry with young people and give them hands-on experiences. A few months ago, while at an airport in the United States, I came across a store where every product they sold, whether clothing, jewellery, or toy, changed colour in sunlight. Even the bag in which they placed your purchase was a colour-changer: white transformed to a soft pink in the sun then returned to white. This is pure chemistry, delivered in a way that engages people; • Give out glow-sticks to kids at your next evening get-together, drop Mentos candies into Diet Coke (I recommend doing this outside!) or have a fireworks display next Victoria Day long weekend. Chemistry is fun and we all know that society cannot survive without chemists. Build and keep that sense of magic in the student, so that they consider pursuing studies in chemistry. As scientists, we all have an important role to play in making this happen. Karen Burke is an executive at Amgen Canada and president of the Canadian Society for Chemistry.

november • December 2011 CAnadian Chemical News 7

Chemical News Analytical Chemistry

ELECTRONIC NOSE DEVELOPED AT NRC

The human nose contains millions of cells coated with more than 1,000 types of olfactory receptors. Now, researchers at the National Research Council (NRC) have found a way to mimic this process, creating a prototype ‘e-nose’ that can detect a range of substances, from toxic pollutants to dangerous goods. Three years ago, a group led by Gerardo Diaz-Quijada at the NRC’s Steacie Institute for Molecular Sciences was asked to develop a more effective chemical sensor for formaldehyde, a toxic compound that often leaches out of building materials. They did this using polyaniline (PANI), a polymer that consists of phenyl rings connected by nitrogen groups. The unique structure of PANI contains many de-localized bonds, which allow electrons to flow along the chain and give it a mild conductivity. At the same time, the nitrogen groups are reactive and can temporarily bond to The reaction between polyanaline and formaldehyde is shown molecules like formaldehyde. This bonding contorts the polymer above. The polymer is normally planar (A) but contorts on and changes the electrical conductivity. By detecting this change, bonding (B) which changes its conductivity. An array of similar the sensor can identify the presence of formaldehyde in less than a polymer-based sensors comprises the electronic nose (bottom). second, even at the parts per billion level. Even more promisingly, PANI’s structure — and therefore its reactivity — can be easily altered by the addition of various side chains. Diaz-Quijada imagines creating a family of related polymer sensors, each one of which would bond to a given molecule in a slightly different way. “This is exactly how we sense smells with our noses,” Diaz-Quijada says. “You smell something not because we have highly selective receptors, but because the molecule will partially bind to many different receptors and your brain is able to decode this as a pattern.” This pattern or ‘fingerprint’ model explains how humans are able to detect about 10,000 different odours, despite having far fewer unique receptors. The formaldehyde detector is currently on track to be commercialized within a year, although the e-nose will take longer to develop. The team is currently shopping the prototype to companies interested in sensing applications from environmental pollutants to explosives. Diaz-Quijada estimates that the e-nose might be sniffing around airports or factories in about five years. Nanotechnology

NANOPARTICLES COULD IMPROVE NICKEL RECOVERY Nano-scale bumps on this lotus leaf [left] improve its hydrophobicity. Similarly, by decorating particles like this glass bead [right] with nanoparticles of polystyrene (each about 290 nm in diameter) researchers can alter its hydrophobic properties. The technique could improve the recovery of nickel from low-grade ores in Canada.

8 L’Actualité chimique canadienne

novembre • DÉcembre 2011

Canada's top stories in the chemical sciences and engineering By Tyler Irving

BioAmber Inc.

business

BioAmber currently produces 3,000 tonnes of bio-based succinic acid per year at this demonstration plant in Pomacle, France. The company has selected Sarnia, Ont. as the location for its first commercial-scale plant.

BIO-BASED SUCCINIC ACID PLANT PLANNED FOR SARNIA

The world’s first commercial-scale bio-based succinic acid plant is set to be built in Sarnia, Ont. The announcement was made this past August by BioAmber Inc., which will build the plant through its subsidiary, Bluewater Biochemicals. Succinic acid is a chemical building block used in a variety of biodegradable and non-biodegradable plastics. It’s also an ingredient in many flavourings and fragrances, as well as engine coolants and even salts that melt ice and snow. Although it’s traditionally sourced from petroleum products, BioAmber has developed a process that uses microorganisms to produce succinic acid from a variety of biomass sugars. “The initial feedstock for the plant in Sarnia will be corn syrup, which is mostly glucose,” says Jim Millis, BioAmber’s chief technology officer. “Our intent is to source whatever will be the lowest-cost glucose, but certainly the Ontario-based corn processing plants are one of those options,” Millis adds. Eventually, the company plans to use cellulosic agricultural waste like corn stover as a feedstock.

In addition to being close to agricultural land, Sarnia was chosen for its combination of chemical infrastructure, skilled labour and competitive transportation costs. In addition, the plant received a total of about $35 million in support from the Ontario Ministry for Economic Development and Trade, Sustainable Development Technology Canada and the Sustainable Chemistry Alliance. “This is the first biobased chemical company to build a plant in North America,” says Murray McLaughlin, president and CEO of the Sustainable Chemistry Alliance. “It says that Sarnia and Canada are a place to do business in the new economy of biobased chemistry.” The plant is expected to cost about $80 million and is set expected to begin production in 2013. Its initial capacity will be 17,000 metric tonnes of biosuccinic acid per year. Through the introduction of next-generation yeast, the company hopes to eventually double that production to 35,000 metric tonnes per year. The product will be sold in markets in North America, Asia and Europe.

As high-grade ores becomes depleted, Canadian nickel miners are looking for new technologies to make recovery of low-grade ores more economical. That’s just what a team at McMaster University is developing, with a new froth-flotation strategy based on nanoparticles of polystyrene (PS). Froth-flotation involves pulverizing minerals into a wet slurry of particles around 100 µm in size then adding chemical agents known as collectors, which are often short chains of hydrocarbons with surfactant properties. These molecules selectively bind to nickel-rich particles and increase their hydrophobicity, allowing them to hitch a ride on air bubbles and float to the surface, where they are skimmed off. Robert Pelton of McMaster’s Department of Chemical Engineering, along with PhD candidate Songtao Yang, have been looking for new types of collectors. Since naturally hydrophobic surfaces like lotus leaves have nano-scale bumps on them, the pair reasoned that coating the micro-scale mineral particles with nanoparticles of polymers like

p olystyrene might improve flotation. Preliminary studies on glass beads have shown even better performance than theory predicted. “You can get it to work with as low as five per cent coverage,” says Pelton. “That’s really important commercially, because you can’t afford to paint the whole mineral surface with these hydrophobic nanoparticles.” The researchers are now working on altering the polystyrene to make it stick to pentlandite, a common nickel-bearing ore. It’s a difficult balancing act; the nanoparticles have to be hydrophilic enough to be colloidally stable in water but hydrophobic enough to float. “Our first indications are that pure polystyrene is pretty good, it seems to be kind of a sweet spot. So the real challenge becomes, how do you get the selective deposition onto real minerals without sacrificing those properties?” If successful, the new technique could apply not only to nickel mining but other precious metals like copper and gold. The work is published in two recent articles in the journal Langmuir.

november • December 2011 CAnadian Chemical News 9

Chemical News polymers

POLYMER MADE FROM RECYCLED BOVINE BITS Bev Betkowski, University of Alberta

Bioplastics made from starch or oil crops are nothing new, but researchers at the University of Alberta have gone one step further — they’ve created a structural polymer from unwanted beef parts. The project began in the wake of the bovine spongeform encephalopathy (BSE) crisis which turned animal parts like the brain or spinal column from a valuable source of protein for animal feed into a liability to be disposed of. One disposal method is hydrolysis — treating the materials with hot water or caustic solution to break down the proteins and destroy any infectious prions that might be present. The result is a deep brown, molasses-like material of dubious value. In 2007 a team led by David Bressler of the Department of Agricultural, Food, and Nutritional Science at U of A set out to find a use for the waste material. “Until we got started, I don't think anybody knew chemically what it was,” Bressler says. The team discovered that hydrolysis broke proteins down from 150—200 kilodaltons in size to about 10. Their next move was to see if the nitrogen groups on these small protein pieces could be knitted together into some kind of structural matrix. As it turned out, several cross-linking agents that were already known to the polymer industry worked well.

Unwanted cow parts from meat processors can be broken down into short peptides and then cross-linked to create structural polymers for possible use in automobiles and other applications. By adjusting their recipes, Bressler’s team can alter the properties of the plastics to fit any number of applications. “Right now, we're targeting the automotive industry because they have some of the most rigorous standards and testing,” he says. “If we shoot for Mars and we end up on the moon, that's still pretty cool.” The process was patented earlier this year and the team is currently working with companies like the Woodbridge Group to meet the desired standards. Bressler says the most rewarding part is the fact that a waste material has been turned into something valuable. “It's one of the first s tories about BSE that’s positive.”

environment

CHEMICAL AGENT SPEEDS SOLIDS SETTLING 10 L’Actualité chimique canadienne

Fines — clay particles less than 44 µm across — can take years to settle from oil sands tailings ponds. But a new chemical approach developed at the University of Alberta could greatly speed this process, which is poised for commercialization. Traditionally, two methods have been used to accelerate the settling of fines. Coagulation involves adding positively charged ions like calcium or aluminum to attract the negatively charged fine particles together. By contrast, flocculation employs a high molecular weight polymer, usually polyacrylamide (PAM), to act as a microscopic spider web, entangling the fine particles and forcing them to sink. However, both methods often fail to collect all the particles, leaving behind a dirty supernatant.

novembre • DÉcembre 2011

Canada's top stories in the chemical sciences and engineering By Tyler Irving Materials Science

Jiang Tang

SIX PER CENT SOLAR CELL SUCCESS Six per cent may not sound like a big number, but for Ted Sargent, Canada Research Chair in Nanotechnology at the University of Toronto, it’s meaningful. It represents the power conversion efficiency of his group’s colloidal quantum dot (CQD) solar cells — the highest ever reported for this technology. Traditional silicon photovoltaics are fabricated as a single rigid crystalline layer. By contrast, CQD technology is based on nanoparticles of semiconducting materials (in this case, lead sulphide) that can be spin-coated or sprayed on a substrate surface, including ones that are lumpy or flexible. Because the size of the particles is on the same scale as the wavelengths of light, researchers can tune them to absorb whatever wavelength they like by making them slightly bigger or smaller. This past July, Sargent’s group published a paper in Nature Photonics reporting the firstever tandem CQD solar cell, which absorbed sunlight from two different frequencies using two different sizes of CQD particles. Their latest breakthrough concerns the passivation layer, a coating that surrounds each nanoparticle and holds them together in a matrix. Traditionally, this layer was composed of bulky organic compounds like ethanedithiol. But in their latest paper, published in Nature Materials, the group was able to replace this compound with inorganic compounds: ions of bromine, chlorine and iodine. This effectively shrunk the passivation layer to the thickness of a single atom, which greatly improved the transport of electrons through the quantum dot layer. It led to the six per cent efficiency, beating the previous record of 5.1 per cent, also set by Sargent’s group. In the future, it is hoped that CQD technology will lead to highly efficient solar cells that take less energy to produce, are flexible and absorb more of the sun’s energy than silicon,

which is limited by its inherent absorption spectrum. Sargent admits that the group has more work to do in order to meet the 10 per cent efficiency that’s considered the target for CQD solar cell commercialization, or the 14 to 18 per cent achievable with silicon. But he’s confident that within the next decade or so, CQD will come into its own. “This shows that inorganic passivation strategies can be extremely effective and there’s no reason to believe that we’ve come anywhere close to what’s possible,” he says. “I think we’ve just scratched the surface.”

Bulky organic molecules like ethanedithiol (yellow and blue spheres) are often used as a passivating layer on colloidal quantum dots made of lead sulphide (red and green spheres) in solar cells (A). By replacing these with halogen ions (B, blue spheres) a team at the University of Toronto has improved electron transport between the quantum dots and increased the efficiency of the solar cells to record levels.

A team headed by Zhenghe Xu, who holds the NSERC Industry Research Chair in Oil Sands Engineering at U of A, along with former chair holder Jacob Masliyah, decided to use a hybrid approach. They prepared a chemical called Al-PAM, which consists of a positively charged aluminum hydroxide core surrounded by branches of polyacrylamide. In lab tests, Al-PAM performed better than traditional flocculation agents. “The settling rate is comparable to conventional polyacrylamide and its derivatives,” says Xu. “But it flocculates fine particles very effectively, so the supernatant is much clearer.” This allows for effective filtration of fine tailings and recycling of the water and could reduce or even eliminate the use of tailing ponds. Although Al-PAM is easy to make in the lab, it remains to be seen if it can be produced effectively on the large scale. Currently, that research is being carried out by one of Xu’s industrial partners, Champion Technologies. “It’s very

xciting to see them take over what e we discovered in the lab,” says Xu. “That’s one of the most rewarding aspects of research, when we discover something that will have a benefit for people’s lives.” If successful, Xu hopes to see Al-PAM being used in tailings ponds within three to four years.

november • December 2011 CAnadian Chemical News 11

Chemistry — Our Life, Our Future The Chemical Institute of Canada’s highlights from the International Year of Chemistry (IYC) • A Guinness World Record is set at Université Laval • Dr. Joe Schwarcz represents chemists on Daily Planet • Alex Trebek informs us about IYC in an episode of Jeopardy! which featured chemistry trivia • Canadian students participate in the Global Water Experiment to create a worldwide database for water quality • Canada Post launches a commemorative stamp for IYC • British Columbia students receive $4,000 in funding for further education by sweeping the “It’s Chemistry, Eh!?” YouTube contest for high school students • Canada’s high school student chemistry team performs their best ever at the International Chemistry Olympiads in Turkey • Across the nation, thousands particapate in chemistry demonstrations and lectures during Science Rendezvous • Canada’s university chemistry and chemical engineering departments join in the celebrations, hosting public education events throughout 2011 • The Canadian Society for Chemistry hosts its largest ever chemistry conference • More than one million Canadians reached by IYC activities

For more success stories, visit IYC2011.ca

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Body of Work

Molly Shoichet is the leading researcher at University of Toronto's new Centre for the Commercialization of Regenerative Medicine, creating technologies to treat and possibly cure diabetes, cancer, heart disease and spinal cord injuries. By Peter Calamai

or decades, observers have bemoaned the gap between the curiosity-driven mission of academic researchers and the commercial-based needs of industry, blaming it in part for Canada’s lacklustre record in innovation. “I call it the ‘development void,’ ” says polymer chemist and biomedical engineer Molly Shoichet, a woman of infectious enthusiasm, gamine-like charm and boundless energy. Unlike the hand-wringers, however, Shoichet is taking a central role in an effort to build a bridge across that void in one specific research area, the field of regenerative medicine that uses stem cells, tissue engineering and biomaterials to stimulate organs in the human body to repair themselves. A professor in the University of Toronto’s department of chemical engineering and applied chemistry, Shoichet is the lead scientist for biomaterials and tissue mimetics (imitations), one of three “platform areas” of the Centre for the Commercialization of Regenerative Medicine. Headquartered at U of T, the centre was formally established this past June on the basis of a five-year, $15 million federal government grant

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Chemical Engineering | regenerative medicine

november â&#x20AC;˘ December 2011 CAnadian Chemical News â&#x20AC;&#x201A; 15

16 L’Actualité chimique canadienne

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Peter Calamai

and almost as much in cash and in-kind commitments from industry, institutional and other partners. The centre’s mission is to be an incubator for regenerative medicine technologies in their early stages and develop a commercialization pipeline to bring the technologies to market, ideally through companies in Canada. Technologies that could treat — and possibly even cure — afflictions such as diabetes, cancer, heart disease and spinal cord injuries are priorities. “We’re really excited about working at the interface of engineering, chemistry and medicine,” Shoichet says during an interview at the new Donnelly Centre for Cellular and Biomolecular Research at the U of T where her laboratory spreads across a large sunlit swath of the top floor. The 46-year-old scientist-engineer has been beavering away at that particular triple interface throughout her career, continually devising structures to bridge gaps, both conceptual and physical. Shoichet’s success in these

frontier research areas is reflected in a plethora of honours and awards: an initial Tier 2 Canada Research Chair in Tissue Engineering followed by a Tier 1 Chair which runs until 2013, Fellow of the Royal Society of Canada and of the American Association for the Advancement of Science, holder of both Killam and Steacie high-prestige fellowships, the Order of Ontario and a Young Explorer’s Award from the Canadian Institute for Advanced Research back in 2002. Yet it almost didn’t unfold that way. When the Toronto native finished her PhD in polymer chemistry at the Amherst campus of the University of Massachusetts in 1992, she had to choose between two job offers. One was from a small, American biopharmaceutical start-up working at the leading edge of science on a scheme to deliver cells encapsulated in a hollow fibre membrane to the central nervous system. The other was from a major cosmetic corporation, designing lipsticks and nail polishes. “I followed my passions,” says Shoichet about the decision to join the start-up, and about her career path in general. One of those passions is medicine, a legacy of pre-medical studies at the Massachusetts Institute of Technology — and of parental insistence on having a career. Another passion is polymers, sparked when she produced polyvinyl alcohol in an MIT lab. “It’s a simple reaction but it was the first chemistry experiment where I could see the result.” Finally, there’s the passion of engineering a mechanical solution to a medical problem, most likely involving a minimally intrusive way of delivering drugs or stem cells to a hitherto irreparable organ. Shoichet’s return to Canada came after she and her husband, a Harvard MBA, extensively surveyed the best locales for their respective careers. Toronto came third in that hard-headed analysis, but again Shoichet followed her passions. During an international conference she quizzed

U of T tissue engineering guru Michael Sefton about opportunities in her home town. “After just a few minutes of talking with her, I realized that Molly was a keeper and that we had to get her here,” Sefton says. But it was 1995 and cash-strapped universities in Canada were imposing salary freezes. The only way U of T’s chemical engineering department could hire Shoichet was for her to win a special University Faculty Award from the Natural Sciences and Engineering Research Council (NSERC) which provided five-years salary and a research grant. “Writing that grant forced me to think of a research project right away. I figured that I had a PhD in polymer chemistry so I could make my own materials, which not a lot of people then in biomedical engineering could. I thought about where in the central nervous system would you want to implant materials. And I said to myself: ‘I bet I could design a better material that we could implant into a spinal cord that’s been damaged.’ That was how my first foray into spinal cord engineering began.” From that spinal cord beginning Shoichet’s research interests have since extended to regenerative strategies for stroke and for severe vision impairment such as age-related macular degeneration and retinitis pigmentosa. Some of the approaches centre on drugs that spur the body’s own stem cells to transform into specialized cells and repair damaged tissue, others involve transplanting stem cells from elsewhere. In all cases, however, what’s needed is a way to deliver the drugs or cells with minimal harm to the already damaged tissue in the spinal cord, brain or eye and then to keep the cells alive. “The two fundamental problems in cell delivery are survival and regeneration — 99 per cent of transplanted cells don’t survive. My lab’s approach is to provide the cells with a wonderful soup and then be the FedEx of cell delivery or drug delivery.” Like FedEx, the Shoichet laboratory has perfected its own exclusive packaging over the years, a hydrogel (a water-based gel) known as HAMC that is a physical blend of hyaluronan and methylcellulose. Hyaluronan occurs naturally in human skin and cartilage; combining it with methycellulose speeds up the gelling process allowing HAMC to be injected by ultrafine needles yet quickly set into a protective scaffold for drugs or cells. Gary Goodyear, the federal Minister of State for Science and Technology, got to experience these specialized

properties for himself when he was handed a syringe loaded with HAMC during a visit to Shoichet’s lab this past June. Goodyear had no trouble getting the drop of gel to appear on the end of the needle. Shoichet’s research at the U of T has led to 30-plus patents (some covering HAMC formulations), more than a 110 peerreviewed journal articles, at least 240 invited lectures and the training of 13 post-doctoral fellows and 46 graduate students. “She is one of a half-dozen leaders around the world who set the agenda in neural tissue engineering as well as a spectacular collaborator,” says Sefton, a distinguished university professor in the Institute of Biomaterials and Biomedical Engineering. As a patron of the Koffler Centre for the Arts and the Mount Sinai Research Foundation, Shoichet is also a force to be reckoned with well beyond the university. In addition, starting in 1998, she’s been a founder or co-founder of three biomedical start-up companies. This combination of corporate sector experience and bench researcher makes Shoichet a much-valued member of the Science, Technology and Innovation Council, says Howard Alper, who chairs the federal advisory body. As both a scientist and an engineer Shoichet brings unique qualities to STIC deliberations. “She’s truly multi-dimensional in terms of her interests,” says Alper, a catalysis chemist who is the former vice-rector of research at the University of Ottawa. Among other interests and activities on her CV, Shoichet lists mother of two sons, skiing, fluent French, half-marathon runs and reading fiction. Plus a private pilot’s licence, which she hasn’t kept current. Soon she’ll be able to add video producer. For the past two years, Shoichet has been promoting the idea of videos to boost science engagement by the general public. A prototype about cardiac stem cells has been produced by Mark MacMillan of Toronto’s Lithium Studios and will shortly be shown to potential funders to raise funds for a series of one-minute online videos and 30-second versions for commercial broadcast. Shoichet remarks: “Right now in Canada we have a ‘pull’ mentality to science engagement. We wait for people who are interested to find out about our work. Instead we went to switch to a ‘push’ mentality, with these videos acting like commercials for the value of basic research.” The campaign slogan is “Today’s Research, Tomorrow’s Reality” and if it succeeds it will be just one more example of the kinds of bridges that Shoichet builds across gaps.

november • December 2011 CAnadian Chemical News 17

 Canadian Society for Chemistry (CSC)

95th Canadian Chemistry Conference and Exhibition

May 26—30, 2012 Calgary, Alberta

Energizing Chemistry Energy Futures Symposium Application Deadline: December 15, 2011 Energy Futures: A multidisciplinary symposium for graduate students involved in e nergy related chemical research in Canada. The organizing committee of the 95th Canadian Society for Chemistry Conference and Exhibition is pleased to announce “Energy Futures ,” an afternoon symposium for outstanding chemistry graduate students performing energy related research - broadly defined - in any subdiscipline of chemistry. The symposium will be held on Tuesday, May 29, 2012 and feature seven to eight 20-minute oral contributions by selected graduate students and a keynote lecture by Thomas Meyer, Arey Distinguished Professor of Chemistry at the University of North Carolina, Chapel Hill. The selected graduate students will each receive complimentary registration and a contribution towards their travel expenses from the organizing committee and the best presentation will be awarded the “Energy Futures Prize.” Eligibility:

• Students must be carrying out energy related research (broadly defined) at a Canadian University in an M. Sc or PhD program. • Applications must be supported by the student’s supervisor. • Students from the University of Calgary will not be considered.

Applications should include the following:

• A draft abstract describing the topic of the research to be presented in the 20-minute oral timeslot. • A brief (one page or less) explanation of how the research relates to a problem in e nergy research (e.g. conversion, storage, provision, recovery, carbon management or the environmental effects of the energy industry). • A letter of support from the student’s supervisor. • All documentation should be combined into one .pdf file and sent by email to Prof. Curtis Berlinguette at cberling@ucalgary.ca.

Host Sponsor for Energy Futures: www.solar.ucalgary.ca

www.csc2012.ca

Q Reinventing Rubber A &

LANXESS AG’s newest research facility in Ontario is uncovering new uses for an old material.

By Tyler Irving

ANXESS AG is a major producer of butyl rubber, a chemical found in such commodities as car tires and chewing gum. This past June, the global giant officially opened its new research and development centre at the University of Western Ontario Research Park in London, Ont. ACCN spoke to Ralf Ingo Schenkel, vice-president, LANXESS Butyl Rubber Global Research and Development, about what the centre means for the butyl rubber business worldwide. ACCN What is butyl rubber and where is it used? RS Butyl rubber is essentially poly(isobutene) with two mol

per cent of isoprene in the polymer chain. The small amount of isoprene in the polymer backbone means that it contains roughly two mol per cent of unsaturation. This makes it reactive and allows it to be vulcanized or halogenated. Butyl rubber has excellent impermeability to air and moisture, which leads directly to the most important application of this polymer: the inner liner in automobile tires. You don’t see it from the outside, but this is the part of the tire that keeps the air inside, providing safety and endurance. The second most important application is in pharmaceutical closure systems. These are the small seals that are used to close vials containing pharmaceutical solutions. The reasons are the same: impermeability against air and moisture and also chemical and biological inertness. In both of these applications, butyl rubber is used as a halogenated polymer, which we call halobutyl. There is also an interest in niche applications for butyl rubber that is not halogenated. This is a very high quality grade and is used in gum base, which is a key component in

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chewing gum. It’s one of the few products of the chemical industry that can be eaten. ACCN What is the history of LANXESS in Canada? RS LANXESS is the leading manufacturer for rubber

polymers. If you look just at butyl rubber, we are the secondlargest manufacturer in the world and the only company that is truly global in that market. We have two existing plants: one in Sarnia, Ont. and the other one in Zwijndrecht, Belgium. Most of the butyl rubber that’s manufactured is used by the tire industry worldwide. In recent years, the tire industry has shifted to Asia and we are currently constructing a new production site for butyl rubber in Singapore. The history of the Sarnia plant goes back to Polysar, a Canadian company that in the 1980s was one of the largest manufacturers of rubber. Polysar was acquired by Bayer AG in 1990 and in 2005 Bayer spun off most of the chemical and polymer activities into a new company, which is LANXESS. ACCN What convinced you that LANXESS needed a new global R&D centre for butyl rubber? RS It sprung from the changes going from Bayer to

LANXESS. The rubber business within Bayer was not a core business, so it did not receive much management attention, nor the necessary capital for investment. Within LANXESS, the strategy changed; the butyl rubber business was one of the most important business units and in 2006 a strategic review was conducted. Our questions were: how do we want to operate our innovation, do we need innovation, is innovation even possible with butyl rubber? We saw a lot of innovation

LANXESS

business | Rubber innovation

potential for butyl and wanted to lead this innovation. We concluded that we needed a world-class R&D organization. ACCN Why did you decide to put it in Canada and London in particular? RS We looked at sites all over the world; we could have put it next to our corporate headquarters, which was in Leverkusen, Germany, or our business unit headquarters in Fribourg, Switzerland. But we also considered our manufacturing sites. These have some key know-how and we wanted to make sure we didn’t lose that. Sarnia today is the largest manufacturing site and it’s also the place where most of our know-how is located. The people who know how to work with butyl rubber and who understand the applications work there. So then we tried to find a place that would provide a world-class innovation culture. There are many research and innovation parks in Ontario, but London and Sarnia are just a one-hour drive apart. What we found in London at the University of Western Ontario (UWO) was really excellent. In 2008 we started construction at UWO research park and the building was ready by the end of 2009. Then we set up the labs. The organization still had to be staffed and we did that in 2010. Currently we have 60 people with diverse backgrounds: organic chemists, polymer chemists, chemical engineers and technologists and some other specialists. ACCN How do you innovate with a material as familiar

and established as butyl rubber? RS The global tire industry today is under a lot of competitive pressure. Oil prices are going up but demand is increasing as people worldwide want to drive cars. The economic growth, especially in China and India, drives research to some extent. And there’s real pressure on tire companies to develop new tires that are more energy-efficient and safer in terms of reduced braking distance. We are developing new materials for tires together with the tire industries. But that is only the current markets; there are also new areas that have not been exploited. The polymer butyl rubber has many interesting properties such as its biological inertness. This means we can use it for applications in the health sector, maybe even in the human body. We see a lot of future potential.

Ralf Ingo Schenkel, vice-president, LANXESS Butyl Rubber Global Research and Development

ACCN Can you give some examples of projects you’re working on? RS As mentioned earlier, in the tire market brominated

butyl rubber is currently used inside tires only. We are working on a new application for brominated butyl rubber for the outside tread portion of the tire. If you put a specific amount of brominated butyl rubber into the tread, you can increase traction, so that means you reduce braking or stopping distance significantly. That in turn improves safety, especially on wet roads or under winter conditions. So that’s in the process of being commercialized. On the medical side, in any health care application, it’s important that systems are clean. Normally, vulcanization requires chemicals like sulphur and zinc oxide, which are not much liked in the health-care industry. We have developed a new polymer that can be cured by using peroxides, which leave no trace behind and represent a very clean pure system. I would also like to highlight the raw material aspect. For the past 40 or 50 years, butyl rubber has been made

november • December 2011 CAnadian Chemical News 21

Inaugurated earlier this year, the LANXESS Global Research and Development Centre in London, Ont. will search for new applications for butyl rubber, which is currently used mainly in the inner liner of automobile tires. The facility will also assist in the commercialization of a new form of butyl rubber made from renewable feedstocks.

from crude oil. What about the next 50 years? How are we going to supply the industries with these polymers if the oil price is too high? That is one of the big challenges for our generation — to shift the raw material base from crude oil to a renewable raw material base. And that’s what we are currently working on, together with the US-based biotech company GEVO. Initially, the feedstock will be based on corn, but in the medium-term the idea is also to use a cellulose product from the forestry industry.

on renewable feedstocks. So that’s one of the first success stories from London that we can now communicate. ACCN How important is collaboration with other groups in the research park? RS Surface Science Western Institute is there and they are

one of our partners. We have more than one research project together with them. The research park is an entity of the university and they are a strong partner.

ACCN What challenges do you face in shifting to a bio-based feedstock?

ACCN How important is this centre for the future of your business?

RS Butyl rubber is created by polymerizing isobutene with small amounts of isoprene at roughly –100°C, using cationic polymerization. This kind of polymerization is very sensitive to impurities, even in the parts per million or parts per billion range. Both crude oil based and bio-based feedstocks contain isobutene as the main component, but you’re dealing with a totally different spectrum of impurities. So these are the scientific and technical challenges: to get the impurities under control and make sure that the bio-based feedstock leads to exactly the same polymer as we get from crude oil. The project is definitely in a very advanced stage already, not only in research but also in engineering. We have demonstrated the feasibility in the laboratory and now the project has moved on in its last stage. We’ll scale it up, likely build a plant and within a few years manufacture butyl rubber based

RS Going forward, the butyl rubber business will become even more global. Our business headquarters are now in Singapore. Everything will be international; we will expand the business further, we will expand capacity and we will also diversify. The tire application remains an important application for us, but other market segments will also become more important. We will be larger, more successful, but also more sustainable. Bio-based raw materials are only one component; there’s only a selected number of projects we can communicate at this time. But as an R&D group, we’re involved in all these activities supporting the whole business. Personally I’m proud of the team we have developed. Within record time they were working together as a high-performing team, as proven by the success stories. This is what I’m most proud of.

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Vancouver's Saltworks Technologies has captured the attention of the desalination industry and a petroleum sector thirsty for solutions to water quality problems. By Tyler Hamilton

24 L’Actualité chimique canadienne

he sun is strong, as is the smell of fish and the sea at the headquarters of Saltworks Technologies, a small start-up nestled between a seafood packing plant and a cold storage facility near East Vancouver’s harbour. A young man with black dishevelled hair, wearing jeans and a dock worker’s rubber boots, walks out of the building, once home to a fish processing plant. This is Saltworks co-founder and chief executive Ben Sparrow, whose casual appearance belies a high-minded ambition — to create technology that will quench the thirst of an increasingly parched planet. Sparrow strides to a shipping container and opens up its doors, revealing a complex arrangement of plastic pipes, rubber tubing and insulated water tanks, all connected to proprietary thermo-ionic de-salting devices and a central control system. “This is our pilot plant,” Sparrow says, then launches into a description of how his desalination machine works, why it’s better than rival technologies on the market and why it matters. That last part — why it matters — is an easy one. “One-third of the world’s population lives in water-stressed countries,” chemical engineering professors William Phillip of the University of Notre Dame and Menachem Elimelech of Yale University write in a paper recently published in Science. “Increasing population, contamination of fresh water sources and climate change will cause this percentage to increase over the coming decade.”

novembre • DÉcembre 2011

Chemistry | Desalination

In other words, the world is running out of fresh water at a time when people, animals, crops and industrial processes are increasingly demanding it. This makes desalination big business, a market expected to become bigger as more countries turn to the oceans as their prime source of drinking water. Market intelligence firm Pike Research estimates that annual investment in desalination technologies will rise to nearly US $17 billion by 2016, double the investment levels seen in 2010. There are nearly 15,000 desalination plants in operation around the world today and two technologies currently dominate the market. One is multi-stage flash distillation, which involves the rapid vaporization of seawater followed by condensation to produce fresh water. This process is energy-intensive, as it requires huge amounts of heat. The other leading and increasingly popular approach is reverse-osmosis, by which salt water is forced through special membranes that selectively prevent salt ions from passing through. Reverse-osmosis uses less energy than flash distillation, but because of the high pressures needed to reverse the osmotic flow of water a considerable amount of electricity is required to operate the pumps. Saltworks boasts a more efficient technology that can cut energy costs by at least half compared to a reverse-osmosis system. It also works under low pressure — as low as five pounds per square inch versus 1,000 psi for reverse-osmosis — meaning expensive stainless steel and titanium pipes aren’t required. All of it can run on low-cost plastic piping of the sort found at Home Depot. Key to the process is the concept of concentration gradients and the tendency of sodium, chloride and other ions found in salt water to flow naturally, without outside energy inputs, from higher to lower salinity concentrations. Sparrow explains that a Saltworks desalination plant would begin by taking in an initial batch of seawater, which contains about 3.5 per cent salt and further concentrating it to 18 per cent or higher. This would be accomplished through evaporation, using low-grade waste heat from a nearby industrial process or by way of a shallow-pond system exposed to the heat of the sun. That salt-concentrated ocean water would then be pumped into a tank, called tank A. Next to it are three other

tanks: B, C and D, which contain seawater with normal concentrations. When A is connected to B and C, the ions in the more concentrated tank A are naturally drawn to the two tanks with lower concentrations. Separating this flow, however, are chemically treated filters called ion exchange membrane stacks. These stacks are manufactured by Saltworks and together with process arrangement represent the company’s core innovation. The membrane stack between tanks A and B only lets negative ions pass through. The stack between tanks A and C only lets positive ions pass through. The result is that tank B ends up with a higher concentration of negative ions, such as chloride, and tank C ends up with a higher concentration of positive ions, such as sodium. As a result, tanks B and C are out of balance. Regular seawater is still sitting in tank D. When tank B with the surplus negative ions is connected to D, it desperately wants to be in balance again, so it strips out all of the positive ions (such as sodium, magnesium, calcium) from D. Likewise, when C is connected to D it pulls the negative ions (such as chloride, sulphate, bromine) out of D in an effort to rebalance itself. This leaves tank D completely salt free. Sparrow is an engineer as well as an executive, born in 1976. It’s also the birth year of Saltworks’ president Joshua Zoshi, Sparrow’s schoolmate from Simon Fraser University and co-founder of the company. Both men had no previous experience in the desalination industry. This, combined with their age, left them somewhat naïve about the initial market opportunity for their technology. “We worked on desalination for a year and a half before we realized there was a bigger market to pursue,” says Sparrow, explaining that producing drinking water from seawater was their original focus. “We thought our attention had to be on the Middle East and Australia” — two regions of the world becoming increasingly dependent on desalination. This perspective evolved, however, after Sparrow and Zoshi travelled to Dubai in 2009 to demonstrate their technology at the World Congress on Desalination and Water Reuse. To impress attendees, they created a mini-version of their desalination process and packaged it within a briefcase, allowing them to desalt small amounts of

november • December 2011 CAnadian Chemical News 25

Tyler Hamilton

seawater for anyone who asked. “We initially saw reverseosmosis as our main competition,” says Sparrow, joking that he and Zoshi tried to avoid crossing paths with their market foes. “But when we started presenting at this and other conferences, the overwhelming pull we received actually came from the reverse-osmosis people. It turns out they are looking for a way to treat their waste brine.” The bottom line, says Sparrow, “we’re now working with the competition.” Waste brine — the rejected salty water left over from reverse-osmosis treatment — isn’t a problem with coastal desalination plants. It simply gets returned back to the ocean. Inland systems, however, don’t have anywhere convenient or economical to dispose of their waste brine. Sparrow and Zoshi quickly learned that Saltworks could solve a major problem for the inland market. The opportunity was huge — potentially eight times larger than the seawater desalination market. More communities, such as El Paso, Texas, are being forced to depend on inland desalination of brackish water found in huge underground aquifers. “It turns out a lot of the U.S. desalination market is inland,” Sparrow says.

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As well, industry — such as the oil and gas and mining sectors — is increasingly dependent on desalination as a way to comply with strict water regulations. “Treating brine water is a huge industrial application,” says Rick Whittaker, chief technology officer at clean-technology granting agency Sustainable Development Technology Canada (SDTC), based in Ottawa. “In the oil sands we’re finding that permits for expansion are now largely limited by water availability.” Alberta, for example, has issued draft regulations that would require in situ oil sands projects to recycle more water, rely more on brackish resources and reduce the amount of brine waste they discharge. Reverse-osmosis has been the technology of choice for these industries, but it can’t do the job on its own. Brackish water, for example, tends to contain about one per cent salt. When put through a reverse-osmosis process, 75 per cent of that water comes out pure and the other 25 per cent left over contains up to eight per cent salt. At that concentration, reverse-osmosis reaches its operational limit. Industry is left with the high cost of injecting the brine back underground, assuming the geology is available.

[Left] Saltworks Technologies co-founders Joshua Zoshi and Ben Sparrow beside a demonstration unit of their desalination machine. Saltworks Technologies’ desalting device with the ion-exchange membrane stack.

Alternatively, the brine can be evaporated in open ponds (a land-intensive option often prohibited by regulation) or put through special crystallizers to produce pure salt. Both options come with a high price tag. This is where Saltworks enters the picture. Its process can turn about 60 per cent of that leftover brine water into pure water, boosting total recovery from 75 to 90 per cent and leaving behind a much smaller volume of brine waste. But it can go a step further. The company has developed a new evaporator tower technology that can retrieve the remaining water from the brine and leave behind an easy-to-handle solid salt. “I can’t say too much about our salt maker,” says Sparrow, explaining that patents for the process have been filed but are not yet granted. What is known is that Saltworks has co-developed the product with SPX Cooling Technologies, a global manufacturer of cooling towers and air-cooled condensers. Whittaker says Saltworks’ process dovetails nicely with reverse-osmosis and industry likes it because it doesn’t undermine existing capital investments in reverse-osmosis systems — it adds value to them. “The more incremental you can make the change, the easier it is for industry to adapt,” says Whittaker. Sparrow is quick to point out, however, that Saltworks does have an edge over reverse-osmosis when it comes to the petroleum sector. Oil and gas often emerges from wells along with salty water and that water has to be treated.

The residual hydrocarbons in that water will gum up reverse-osmosis membranes, but they don’t have an affect on Saltworks’ low-pressure thermo-ionic process. “It’s a fluke, really, we never anticipated this,” says Sparrow, adding that the company’s process can also assist in taking salts out of oil sands tailing ponds as part of remediation efforts. “Folks in the oil and gas community like our process, because they have tremendous amounts of waste heat they can use to drive our process.” It’s part of the reason why Calgary-based oil company Cenovus Energy invested $2.5 million in Saltworks back in June. Mining giant Teck Resources, recognizing the value of Saltworks’ process in the mining sector, is also an investor. Meanwhile, Saltworks is building a pilot plant for use in the oil sands as part of a project partly funded by SDTC. It will be tested when complete and then shipped from Vancouver to Fort McMurray, becoming operational by next summer. The oil sands developer that will use the plant has not yet been disclosed. Sparrow still has his eye on the market for drinking water, and in time the company’s thermo-ionic technology could prove a formidable competitor to reverse-osmosis. But in the near term, working with — rather than against — reverse osmosis is proving the path of least resistance. “It just turns out that industry moves much faster,” he says.

november • December 2011 CAnadian Chemical News 27

Society news STUDENTS

John C. Polanyi to deliver the mail

Scholarships for chemical engineering students

luke andersson

INTERNATIONAL YEAR OF CHEMISTRY

Canada Post unveiled a limited-edition stamp honouring world-renowned chemist and Nobel Laureate John C. Polanyi, HFCIC, on Oct. 1 at the University of Toronto’s Chemistry Nuit Blanche celebrating the International Year of Chemistry. The stamp features a photograph of Polanyi and a design that represents his laboratory’s ongoing work in Scanning Tunneling Microscopy. Polanyi, a faculty member at U of T’s Department of Chemistry since 1956, is one of three winners of the 1986 Nobel Prize in chemistry in recognition of the development of the new field of reaction dynamics. He was cited for his pioneering work in developing the method of infrared chemiluminescence. Polanyi’s list of awards and honours includes the Royal Medal of the Royal Society of London, Fellowship of the Royal Societies of Canada, London and Edinburgh as well as the American Academy of Arts and Sciences, the U.S. National Academy of Sciences, the Pontifical Academy of Rome and the Russian Academy of Sciences. He is a member of the Queen’s Privacy Council for Canada, a companion of the Order of Canada and has 30 honorary degrees from universities around the world. Polanyi has also made significant contributions in the areas of peacekeeping and science policy, such as serving as co-editor of The Dangers of Nuclear War and as co-chair of the Department of Foreign Affairs International Consultative Committee on a Rapid Response Capability for the United Nations.

Testing the waters in New Brunswick In celebration of the International Year of Chemistry, the 100 th anniversary of Parks Canada and the induction of the Bay of Fundy as a UNESCO Biosphere Reserve, students from Riverview, N.B. undertook an innovative environmental analysis project called “The Riverview High School Water Project.” Under the guidance of chemistry teacher Ian Fogarty, five students: Robyn O’Dell, Marlise O’Brien, Rebecca Laffoley, Shandelle Murray and Ha-Gyoung Yoon mapped out water quality throughout the Fundy Biosphere Reserve. The students employed Pasco probeware to test for pH, temperature, dissolved oxygen, phosphate and nitrates. They are investigating how these properties change throughout the day as well as collecting base line data for the reserve for a citizen science legacy project. The students’ research earned them an invitation to the Chemistry World Youth Congress this month in Lima, Peru.

This year’s winners of the CSChE Chemical Engineering Local Section Scholarships, sponsored by the Sarnia CIC, Edmonton CSChE and London CIC Local Sections, are Jervis Pereira of McMaster University and Joseph Paul Lagasca of the University of Calgary. The awards were presented at the CSChE Conference in London, Ont. last month. Scholarships are given to those students who make significant contributions to the CSChE, such as participation in Student Chapters, and who demonstrate outstanding leadership qualities and high academic achievement. upcoming events

November 14‒16, 2011 Interamerican Congress of Chemical Engineering Santiago, Chile www.ciiq2011.cl

March 11‒15, 2012

Pittcon Conference & Expo Orlando, Florida. www.pittcon.org

May 26‒30, 2012

95th Canadian Chemistry Conference and Exhibition Calgary, Alta. www.csc2012.ca

October 14‒17, 2012 62nd Canadian Chemical Engineering Conference Vancouver, B.C. www.csch2012.ca

May 21‒25, 2013

4th Georgian Bay International Conference on Bioinorganic Chemistry Parry Sound, Ont. www.canbic.ca

november • December 2011 CAnadian Chemical News 29

Chemfusion

Wieners unfairly banished to the doghouse By Joe Schwarcz

erusing the scientific literature reveals studies that link the frequent consumption of cured meats with stomach and colon cancer, chronic obstructive pulmonary disease, leukemia, diabetes and heart disease. While there may be valid criticisms of many of these studies — eating processed meats may be a marker for an unhealthy lifestyle — it is hard to escape the conclusion that curbing our intake of these foods has no downside, except perhaps disappointing the taste buds. Some organizations, however, have gone overboard with their interpretation of the data. The Physicians Committee for Responsible Medicine (PCRM) recently unveiled a billboard near the Indianapolis Motor Speedway in Indiana that features hot dogs in a cigarette pack inscribed with skull and crossbones and the message, “Warning: Hot dogs can wreck your health.” Really? Where’s the evidence? Nevertheless, PCRM wants hot dogs to sport a warning label, “Consuming hot dogs and other processed meats increases the risk of cancer.” Nitrates and nitrites define the traditional meat curing process. Their discovery can be traced to the use of salt that was contaminated with potassium or sodium nitrate, also known as saltpeter. Meat treated with these chemicals retains a red colour, acquires a characteristic taste and, most importantly, is less amenable to contamination with disease-causing bacteria, particularly the dangerous Botulinum clostridium. By the 1980s, it became apparent that certain bacteria were capable of converting nitrates into nitrites and that nitrites were the active species preventing contamination. Consequently, nitrites

30 CAnadian Chemical News

are now added directly to processed meat instead of relying on bacteria to produce them from nitrates. This allows for better control of nitrite concentrations, a critical aspect of processed meat production. Why critical? Because it is well known that nitrites can react with amines, naturally occurring compounds present in meat, as well as in human tissues, to form nitrosamines. And that is the fly in the hot dog — nitrosamines can trigger cancer! Of course, demonstrating that nitrosamines can produce mutations in a Petri dish or that animals treated with high doses develop cancer does not mean that these compounds are responsible for cancers in humans. In any case, changes in manufacturing methods and a reduction in the amount of added nitrite have essentially solved the problem of nitrosamine formation in cured meat. In spite of the weak epidemiological evidence linking nitrites to cancer and the fact that 95 per cent of all the nitrite we ingest comes from bacterial conversion of nitrates naturally found in vegetables, many consumers have a lingering concern about eating nitrite-cured processed meats. But one person’s concern is another’s business opportunity. In this case, producers have responded with an array of “natural” and “organic” processed meats sporting such catchy phrases as: “no synthetic preservatives” or “no nitrites added.” But given the crucial role nitrites play in processed meats, how do you replace them? You don’t. You just replace the source of the nitrite. Celery has a very high concentration of natural nitrate, and treating celery juice with a bacterial culture produces nitrite. The concentrated juice can then

november • December 2011

be used to produce “no nitrite added” processed meat. Curiously, regulations stipulate that the traditional curing process requires the addition of nitrite and thus “organic” processed meats that are treated with celery juice have to be labeled as “uncured.” Such terminology is confusing because most consumers look to “organic” processed meats in order to avoid nitrites, but the fact is that these do contain nitrites, sometimes in lesser, sometimes in greater amounts than found in conventional products. That’s because the amount of nitrite that forms from nitrate in celery juice is hard to monitor. In conventionally cured processed meats, the addition of nitrite is strictly controlled by regulations designed to minimize nitrosamine formation and maximize protection against botulism. This means any risk due to nitrosamine formation or bacterial contamination in the “organic” version is more challenging to evaluate. So what does this mean? Buying “organic” hot dogs or bacon with a view towards living longer by avoiding nitrites makes no sense. Limiting such foods because of their high fat and salt content, whether organic or conventional, makes very good sense. Cutting them out totally, as the PCRM would have us do? No thanks. It is unrealistic to evaluate every bite of food as being healthy or unhealthy. It is the overall diet that matters. Emphasize a mostly plant-based diet? By all means. But dogmatic tirades against hot dogs? That’s ideology, not science. Joe Schwarcz is the director of McGill University’s Office for Science and Society. Read his blog at chemicallyspeaking.com.