We鈥檙e leading a bio-industrial revolution.
Since the Industrial Revolution fossil fuels have been our primary energy source. But our dependency on them can’t continue. The combined effect of fossil carbon depletion and climate change means 21st century industry must find cleaner, more sustainable forms of energy. We need solutions that will help us respond to society’s grand challenges: an ever-increasing and ageing population, affordable health care, resource efficiency, food security, climate change and energy shortages. We’re a research powerhouse and we’re working with industry partners to tackle these global challenges head-on.
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A bio-industrial revolution
Just as Manchester was at the heart of the first Industrial Revolution, The 91视频 is now leading the way, both nationally and across Europe, towards a bio-industrial revolution. We’re at the forefront of a European industrial renaissance, creating next-generation chemicals for industrial and health care needs.
Biotechnology and the manufacture of bio-based chemicals underpins one of the largest industrial sectors. The UK bioeconomy is now estimated to be worth more than £150 billion and generates more than four million jobs.
Using biological resources such as plants, algae, fungi, marine life and micro-organisms, biotechnology, combined with the emerging science of synthetic biology, is changing how we manufacture chemicals and materials, and provides a source of renewable energy.
We’re channelling the full breadth of our expertise in chemicals, materials and energy to find the answers. In the Manchester Institute of Biotechnology (MIB), the University has one of Europe’s leading industry-interfaced institutes, with world-leading capabilities in chemicals synthesis and manufacture.
Since its inception in 2006 the MIB’s pipeline of discovery through innovation has supported over 51 patents, 8 and more than 230 new invention disclosures and 12 licenses.
Get an in-depth insight into some of our world-changing biotechnology research.
At the forefront of future growth
Manchester has a major role to play in the delivery of the UK governments Bioeconomy and Clean Growth strategies that will propel the UK to sustainable future growth.
Biotechnology research is revolutionising our understanding of chemical and biological processes. With new discoveries in biotechnology holding the key to developing solutions to some of the world’s greatest challenges such as feeding a growing population and offering new alternatives to our scarce natural resources.
In a series of flash lectures, experts from Manchester address the big questions the world must answer in building back from the pandemic.
Biotechnology: research breakthroughs
Developing synthetic, cost-effective renewable sources of energy.
Research that is enabling early diagnosis of life-changing diseases like Parkinson's.
Global challenges, Manchester solutions
Efficient production of medicines
Statins are a major breakthrough in health care: widely used drugs that decrease the risk of coronary heart disease and strokes by lowering cholesterol levels. To make them more widely available we need to reduce production costs.
Researchers from our Manchester Institute of Biotechnology have worked with industry partners at DSM to devise a single-step fermentative method for the industrial production of pravastatin, replacing the previous costly dual-step fermentation and biotransformation process. This new biotechnologically advanced method forms the basis of a patented process for efficient production of this blockbuster drug.
Propane, a major component of liquefied petroleum gas, is the world’s third most widely used motor fuel and provides heat and energy for an estimated 14 million homes. Reducing its environmental impact is crucial in tackling global climate change.
Researchers from our Manchester Institute of Biotechnology, in collaboration with Imperial College London and the University of Turku, have created a synthetic pathway for biosynthesis of propane gas. This cutting-edge process has the potential to revolutionise the production of biofuel, avoiding the environmental issues associated with extracting fuel from non-renewable sources and drastically reducing the transport costs and carbon emissions associated with production.
Cleaner and sustainable manufacturing
Biotechnology has the potential to revolutionise manufacturing, supporting a transition to a cleaner bio-based economy. However, it can take years for leading academic research to be adopted by industry and turned into new medicines or sustainable energy solutions.
The 91视频 leads the Future Biomanufacturing Research Hub, which boosts interaction between academics and industry, promoting the translation of research into societal and economic benefits. This new UK centre is developing innovative biotechnologies for high-value manufacturing to sustainably produce pharmaceuticals, chemicals and materials.
Parkinson鈥檚 early diagnosis
Every hour, someone in the UK is told they have Parkinson’s disease – a progressive neurological condition with no definitive diagnostic test and no cure. It affects 127,000 people in the UK and 7.5 million worldwide, leaving many patients struggling to walk, speak and sleep.
We’re tackling the development of a noninvasive diagnostic test that may have the ability to diagnose early Parkinson’s, possibly even before physical symptoms are displayed. Our researchers are undertaking investigations to identify novel small molecules from sebum – an oily substance found in the skin – which are believed to emit a subtle but unique scent in patients in the early stages of Parkinson’s.
New biomaterials for a greener future
The UK government’s Clean Growth Strategy sets out proposals for decarbonising all sectors of the economy in the coming decades. New materials inspired by biology could help us meet this ambitious new green strategy.
Pioneering Manchester scientists at the Synthetic Biology Research Centre for Fine and Speciality Chemicals (SYNBIOCHEM) are taking inspiration from nature to develop the next generation of synthetic biological materials with amazing properties, such as enhanced strength, flexibility and lightness. Recent research into bioplastics has highlighted new biomanufacturing processes that can provide positive environmental impact and allow affordable and sustainable production.
Improving chemicals production
Many flavours and fragrances are sourced from botanicals. However, some of which contain only minute levels of the target compound. Engineering bacterial strains that produce these compounds could reduce the environmental
impact of traditional chemical synthesis.
Hosted by the Manchester Institute of Biotechnology, the Synthetic Biology Research Centre for Fine and Speciality Chemicals (SYNBIOCHEM) focuses early activity in three key chemical targets: alkaloids, flavonoids and terpenoids. These projects aim to accelerate the production and scale-up of important chemical targets, which are key to a wide range of sectors.
Producing inexpensive pharmaceuticals
Hepatitis C is a major health problem affecting around 150 million people worldwide. Many infected people live in countries where access to modern expensive treatments is a major issue.
We’ve helped develop a new class of drugs that are highly effective in tackling hepatitis C, completely removing the virus from most patients. Efforts can now focus on making telaprevir – the leading medicine in this area – widely available and affordable. In collaboration with the Free University of Amsterdam, we devised an efficient synthesis of telaprevir that combines biocatalysis with multicomponent chemistry.
Antibiotics production crisis
According to the World Health Organization, there are not enough new antibiotics in development. Since their 1960s heyday, the production of novel antibiotics has declined markedly – it’s been 30 years since a major new class of antibiotics for clinical use has been discovered.
Researchers at Manchester’s Synthetic Biology Research Centre, SYNBIOCHEM, have married biology with engineering to find new routes to antibiotics. Using synthetic biology we can rewrite the DNA sequences of the antibiotic biosynthesis pathways and introduce different enzymes from other organisms. Our pioneering robotic technology, meanwhile, can test thousands of these compounds every year, bringing new synthetic antibiotics a step closer.
Accelerating medicine development
It can take years or even decades to develop and produce new medicines, with those affected unable to be helped by the latest developments in biotechnology.
Our researchers have created a new way to speed up the genome evolution of baker’s yeast Saccharomyces cerevisiae, the same yeast used in bread and beer production. This innovation could help with the mass production of advanced medicines to treat illnesses such as malaria and tuberculosis. It could also have massive implications for the future study of DNA.
Institute receives prestigious award
The Manchester Institute of Biotechnology collected the Queen's Anniversary Prize at a ceremony held at Buckingham Palace.
Queen鈥檚 Anniversary Prize awarded for environmental research
The Manchester Institute for Biotechnology has been named a winner of the Queen鈥檚 Anniversary Prize for Higher and Further Education.
Enzyme structure key to all life on earth
Research into enzyme structure provides basis for harnessing light energy crucial for light-to-chemical energy conversion.
Bacteria could replace crude oil in biofuels
Researchers are exploring how to create bio-based jet fuels from bacteria that grows in seawater rather than using crude oil.
Helping robots build new antibiotics
Manchester researchers have engineered a common gut bacterium to produce a new class of antibiotics to combat diseases and cancer, using robotics.
New hub to boost bio-tech in Greater Manchester
A new bio-tech facility, based at the University, is set to transform the bio-tech manufacturing process, driving clean growth and increasing commercial viability.
University signs up to help Manchester go zero carbon and plastic free
The University will work to remove avoidable single-use plastics from catering, labs and stationery by 2022 and play a major role in the city鈥檚 zero carbon by 2038 target.