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A sustained joint research partnership with Biocompatibles UK Ltd has stimulated innovation underpinning the company's product development pipeline. Products include a family of soft contact lenses, enhanced medical device coatings, and novel treatments for liver cancer. Innovative enhancements, such as the unique non-biofouling nature of the company's ocular and cardiovascular devices and the practical utility of its drug eluting therapies for targeting liver malignancies, have delivered improved clinical performance and differentiated these products from those of competitors in the same markets. The company's continuing success in developing innovative medical technology products was recognised by the sale of Biocompatibles UK for £177m in 2011.
The University of Brighton's sustained musculoskeletal research programme has, through the development of novel standardised data collection tools, improved data capture, communication, policy and business planning at local practitioner level and at organisational/regulatory body levels (e.g. Physio First, the private physiotherapy practitioner group of the Chartered Society of Physiotherapy (CSP) UK and the General Osteopathic Council (GOsC)). Secondly, research findings from a study exploring patients' expectations have significantly informed the recent revision of the GOsC's osteopathic practice standards and a new revalidation scheme for osteopaths. Thirdly, as a result of studies identifying research priorities for the physiotherapy profession, changes have occurred in the direction and focus of research funding applied by the CSP's charitable trust.
The University of Brighton (UoB) has developed a new corpus-evidence-based approach to lexicography along with supporting tools and training resources. This approach has resulted in the development of a computational lexicography tool, the Sketch Engine, commercialised by Lexical Computing Ltd. The Sketch Engine has been adopted by four of the UK's five major dictionary publishers, national language institutes in nine European countries and over 100 universities, to support commercial dictionary production, language technology products and to enable language teaching. It has also been used to substantiate arguments in a pervasive debate about language use in the art world.
Researchers at the University of Brighton (UoB) have developed innovative low-cost solutions to pressing global disease problems. In Haiti, rapid deployment of new wastewater technology averted further human crisis when the 2010 earthquake exposed water resources to hospital wastewaters contaminated by the cholera pathogen. In Malawi, the re-design and improved management of rural wells have provided low-income communities with safer drinking water. In Europe, new methods have identified human faecal contamination of rivers and established viral removal rates in a wastewater reuse system, enabling two water companies and two national environmental agencies to meet international standards and protect public health.
Our research led to the creation of Football4Peace (F4P), which is a vehicle for conflict resolution and peace building in divided societies. By challenging cultural prejudice F4P has transformed passive citizens into active ambassadors for peace. More than 8,000 children, 595 coaches and many community leaders have participated in F4P projects during the census period, generating political discourse in the community and in governments up to ministerial level. Innovative community relations research in the context of Northern Ireland's peace process led to the development of the F4P initiative. Subsequently it changed the policies of sporting organisations in Israel, Jordan, Palestine, Ireland, South Africa and South Korea.
3D scanning technology has enabled multiple opportunities for innovation in diverse areas such as manufacturing, design, and the arts. However, full utilisation of this technology requires not just the scanning hardware, but accompanying software that can build meaningful, editable models. This development has been pioneered by research conducted in the School of Computer Science and Informatics, at Cardiff University. Innovative algorithms for reverse engineering and digital shape reconstruction were devised that enabled the reconstruction of complex computer aided design (CAD) models from data captured by 3D scanners. The algorithms have been endorsed by Geomagic Inc, a market leading American software corporation (recently acquired by 3D Systems), that has subsidiaries in Europe and Asia and global distributors, and incorporated into their software product suite. This is accessed by nearly 10,000 licensed users worldwide, who have applied the product for industrial applications including aerospace and automotive engineering, product design, cultural heritage preservation, and healthcare. Accordingly, the impacts claimed are twofold: a) economic gain manifesting in the benefits to Geomagic and a plethora of end users who have utilised the software, b) impact on practitioners and professional services in diverse domains.
Since 2003, participatory action research in Brighton and Hove has identified the specific health and well-being needs of LGBT people in mental health, safety, housing, drugs and alcohol. The research changed local and national policy and reshaped services to reflect the diverse needs and experiences of LGBT communities. In the UK, the research influenced policy resulting in the first local LGBT housing strategy and the first suicide strategy in Brighton that centralises LGBT people. The research played a key role in ensuring the survival of the only LGBT mental health charity in the UK. Recommendations from the research have been adopted in the UK by the Department of Health, the UK Drug Policy Commission, the Cabinet Office and the Equalities and Human Rights Commission. The research has influenced policy developments in Australia through the National LGBTI Health Alliance and has been incorporated into a guide to GLBTI inclusive practice for health and human services in the state of Victoria.
Femtocells provide short-range (e.g. 10m) wireless coverage which enables a conventional cellular communication system to be accessed indoors. Their widespread and growing use has been aided by the work in UoA11 by the University of Bedfordshire (UoB).
In 2008, while the femtocell concept was still in its infancy, researchers at UoB with expertise in wireless networks recognised that coverage prediction and interference reduction techniques would be essential if the benefits of that concept were to be realised.
Collaboration with two industrial partners (an international organisation and a regional SME) resulted in tools that enable operators to simulate typical femtocell deployment scenarios, such as urban, dense apartments, terraced house and small offices, before femtocells can be reliably deployed by users without affecting the rest of the network (a benefit of the technology). These tools have been deployed by those partners to support their businesses. A widely-cited textbook, written for network engineers, researchers and final year students, has brought knowledge of femtocell operation to a wider audience.
The volume and diversity of data that companies need to handle are increasing exponentially. In order to compete effectively and ensure companies' commercial sustainability, it is becoming crucial to achieve robust traceability in both their data and the evolving designs of their systems. The CRISTAL software addresses this. It was originally developed at CERN, with substantial contributions from UWE Bristol, for one of the Large Hadron Collider (LHC) experiments, and has been transferred into the commercial world. Companies have been able to demonstrate increased agility, generate additional revenue, and improve the efficiency and cost-effectiveness with which they develop and implement systems in various areas, including business process management (BPM), healthcare and accounting applications. CRISTAL's ability to manage data and their provenance at the terabyte scale, with full traceability over extended timescales, based on its description-driven approach, has provided the adaptability required to future proof dynamically evolving software for these businesses.
This case study embodies a non-linear relationship between underpinning research, software development and deployment. It involves computer science research at UWE in conjunction with its applied development for the world's largest particle physics laboratory and onward deployment commercially into private sector industry.
Automotive design analysis software based on qualitative reasoning research in the Advanced Reasoning Group at Aberystwyth is deployed at more than 200 automotive and aeronautic OEMs and Tier 1 suppliers world-wide. The software necessitates companies changing their process for performing design analysis, and companies are willing to do this because of the attendant benefits.
The major benefits of use of the software are early feedback on potential problems with the design of automotive systems, and improved safety of automotive designs. Related benefits are improved product time to market, and cost savings. A representative example of production savings of $2.5 million has been given for use of the software on a single product design, as well as Ford Motor Company's estimate of $20M per year saved in just their company.