Researchers harnessreducing potential renewable sugars

Researchers harness the reducing potential of renewable sugars

11:33 AM, 3rd March 2016
Undergraduate student David Austin University of Huddersfield
Undergraduate student David Austin has participated in the research, working on using sugars as the catalyst for producing drug-like molecules.

HUDDERSFIELD, UK: Inspired by nature, University of Huddersfield scientist Dr Jason Campis pioneering the use of simple sugars to power chemical reactions. It means that industries such as pharmaceuticals and agro-chemicals will have a renewable, inexpensive and non-toxic method of catalysis.

Camp, who is a senior lecturer in the department of chemical sciences at the University’s School of Applied Sciences, has been exploring sugar-powered catalysis for the last six years. He heads a group of scientists at Huddersfield and also the University of Nottingham – where he was previously based - who are carrying out the research.

Their findings appear in the new edition of RSC Advances, published by the Royal Society of Chemistry.

The concept of sugar-powered catalysis has also attracted interest at the House of Commons, when University of Huddersfield chemistry student David Austin – who has been working with Camp – took part in an event showcasing the UK’s best undergraduate research.

Camp said that although biological processes were the basis for his work, the research is pure chemistry.  “We are inspired by nature, but we don’t use enzymes or biological processes.”

“Sugars have been used for catalysis in the past, but techniques such as advanced spectroscopy have enabled him and his co-researchers to make key breakthroughs such as the requirement to minimize oxygen from the system in order to allow for a sugar-powered process,” said Camp.

The researchers have investigated a variety of reducing sugars – including sucrose and fructose – but glucose has become their principal focus. Camp and his team are also examining the use of environmentally-benign solvent that contains no oil-derived substances.

To this end, collaboration has been formed with the multi-national company Circa, which is a pioneer in the processing of cellulose into a novel green solvent. Camp and his team have also attracted financial backing from a wide range of UK-based companies, including AstraZeneca, Pfizer, GlaxoSmithKline, Vertex and Johnson Matthey.

Posters in parliament

Sugar-powered catalysis has many potential applications, said Camp, who is currently exploring its use its use the development of novel dyes for solar-cell in collaboration with Dr Elizabeth Gibson of the University of Newcastle.

But he anticipates that agro-chemistry and pharmaceuticals will be the principal industries to use the new technology that he is developing, appreciating the cost and environmental benefits of using sugars.

At the University of Huddersfield, Camp has PhD researcher Thomas Bousfield working with him on sugar-powered catalysis. Undergraduate David Austin, who completes his four-year MChem degree this year, has also participated in the research, working on using sugars as the catalyst for producing drug-like molecules.

David created a poster describing the sugar-powered catalysis concept and entered it into a contest organised by the British Conference of Undergraduate Research. It was selected for display at the prestigious Posters in Parliament even.

David spent the year-long work-placement component of his degree course at the Halifax plant of chemical industry multi-national Solvay. Keen to continue working on industrially-relevant chemistry, he saw Camp’s project as an ideal opportunity and he is convinced of its potential.

© University of Huddersfield News

0 Comments

Login

Your Comments (Up to 2000 characters)
Please respect our community and the integrity of its participants. WOC reserves the right to moderate and approve your comment.

Related News


Covestro introduces new long-lasting, cost-efficient floor sealant

LEVERKUSEN, GERMANY: Floors in industrial and commercial buildings or in public spaces are exposed to extreme wear and tear. Day after day, any number ...

Read more
Understanding the cancer-killing properties of a chemical commando

NEW HAVEN, US: A Yale University lab has unlocked the process by which a natural anti-cancer agent is able to bind to DNA and directly break both stra ...

Read more
Argonne, Los Alamos labs to develop affordable fuel cell components

LOS ALAMOS, US: Researchers at the US Department of Energy’s (DOE) Argonne and Los Alamos national laboratories have teamed up to support a DOE ...

Read more
From backyard pool chemical to nanomaterial

MONTREAL, CANADA: Could a cheap molecule used to disinfect swimming pools provide the key to creating a new form of DNA nanomaterials? Cyanuric acid ...

Read more
Dow settles urethanes class action litigation, pays $835 million

MIDLAND, US: The Dow Chemical Company said that it has entered into a settlement agreement to resolve the In re Urethanes Class Action litigation, by ...

Read more
Asahi Glass, Japan Material collaborate to produce bio-organic acids

TOKYO, JAPAN: Asahi Glass Co Ltd (AGC) said that in collaboration with Japan Material Technologies Corporation (JMTC), it has established a new compan ...

Read more
www.worldofchemicals.com uses cookies to ensure that we give you the best experience on our website. By using this site, you agree to our Privacy Policy and our Terms of Use. X