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REF impact found 9 Case Studies

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Design of a new total knee replacement

Summary of the impact

Each year an estimated 1,324,000 artificial knee joints (total knee replacements — TKR) are implanted worldwide; an estimated third of these utilise an implant manufactured by DePuy International. Underlying computer-based research performed by the Bioengineering Sciences Research Group has played a central role during the development of a new design of TKR for DePuy. The design programme, the biggest in DePuy's history, had a budget in excess of US$10 million and aimed to replace the existing TKR system, which had annual sales of approximately US$100 million.

Between 2007-2010, DePuy adopted the computational techniques developed by the group as screening tools to (i) assess polyethylene wear and (ii) account for the effects of surgical variability during the early design phases. DePuy states "This research allowed us to choose the most robust solution when proceeding to mechanical testing and saved years in the design cycle. Patients also benefit from increased confidence in an implant that is able to withstand the rigors of use".

Submitting Institution

University of Southampton

Unit of Assessment

General Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Mathematical Sciences: Statistics
Engineering: Biomedical Engineering
Medical and Health Sciences: Clinical Sciences

Lower wearing, longer lasting joint replacements in the hip and knee

Summary of the impact

This UoA has developed the largest independent simulation laboratory in the world for pre-clinical evaluation of the wear of artificial joints, which has been used to develop and commercialise novel pre-clinical simulation systems for joint replacements, in partnership with Simulation Solutions Ltd. Simulation Solutions Ltd is now the market leader of joint simulation systems outside North America.

We have also co-developed lower wearing ceramic-on-ceramic and ceramic-on-metal bearings for hip joints, and have worked with DePuy Orthopaedics Inc to define lower wearing tribological solutions for polyethylene knees. This work has benefited hundreds of thousands of patients worldwide during the REF period.

Submitting Institution

University of Leeds

Unit of Assessment

Aeronautical, Mechanical, Chemical and Manufacturing Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Biomedical Engineering, Materials Engineering
Medical and Health Sciences: Clinical Sciences

Improved Surgical Practice Through Engineering Research

Summary of the impact

Long-term fixation integrity is a critical issue in joint replacement surgery that affects both quality of life of patients and the economy. The unique comprehensive study of long-term acetabular cement fixation carried out at the University of Portsmouth has significantly informed orthopaedic surgeons and impacted on their surgical practice. In addition, research on a commercial hydrogel implant TRUFIT has informed clinical and commercial decisions on the use of the implant for load bearing applications, which has led to the withdrawal of the implant from the global market.

Submitting Institution

University of Portsmouth

Unit of Assessment

Aeronautical, Mechanical, Chemical and Manufacturing Engineering

Summary Impact Type

Health

Research Subject Area(s)

Engineering: Biomedical Engineering
Medical and Health Sciences: Clinical Sciences

Precision Techniques for Hip Joint Replacement Surgery Improves Quality of Life for over 10,000 Patients

Summary of the impact

Over 100,000 hip joint replacements are performed each year in the UK. The correct restoration of joint centre is critical to the successful outcome of total hip replacements. Failure to do so results in dislocation, increased wear and leg length discrepancy.

In collaboration with QUB, over 4,000 patient-specific custom hip prostheses were manufactured and implanted at Musgrave Park Hospital, Belfast, leading to accurate restoration of anatomical joint centre.

As a consequence a new surgical instrument has been developed and utilised in more than 4,000 surgeries. Surgical costs are reduced compared to the alternative of computer-aided surgery. The DePuy Synthes Companies are funding the development of a later version of this surgical instrument

Submitting Institution

Queen's University Belfast

Unit of Assessment

Aeronautical, Mechanical, Chemical and Manufacturing Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Biomedical Engineering
Medical and Health Sciences: Clinical Sciences

Light-weighting of automotive and aerospace transport

Summary of the impact

The automotive and aerospace industries are keen to reduce their environmental impact and so have looked to move to lightweight materials. This creates issues in terms of joining, using and disposing of dissimilar materials. Oxford Brookes has therefore worked with national and multi-national companies in the adhesive, materials, automotive and aerospace industries to try to solve these problems. This has resulted in high quality research publications, innovative test equipment, improved numerical methods, novel designs, design guidelines, manufacturing procedures, British Standards, patents, commercial products and further funding. The impact of the work has global safety, environmental and economic benefits with multi-national aerospace and automotive companies implementing the results in current developments.

Submitting Institution

Oxford Brookes University

Unit of Assessment

General Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Aerospace Engineering, Civil Engineering, Materials Engineering

Joint Venture: Working in partnership to develop a unique hip replacement treatment

Summary of the impact

The University of Southampton's world-leading record in bioengineering continues to deliver significant benefits, resulting from recent research crucial to the development, pre-clinical verification and CE-marking of a revolutionary hip-resurfacing implant. In the wake of growing concerns over some previous implant designs, this work has positively impacted on a wide range of audiences: over 9800 patients have received the new implants with excellent early clinical results at two years' follow-up. Within 4 years UK PLC benefited with considerable additional turnover [exact figure removed for publication], a majority from abroad, and the technology attracted three years of investment for a start-up company at Southampton Science Park. This award-winning knowledge transferring research has been widely acknowledged as an example of best practice, and has increased appreciation of science and technology further through outreach.

Submitting Institution

University of Southampton

Unit of Assessment

General Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Biomedical Engineering
Medical and Health Sciences: Clinical Sciences

Improved Hip Replacement Fixation Techniques to Increase Implant Longevity

Summary of the impact

Our research has developed improved hip replacement fixation techniques, which have improved the biomechanical stability of implanted artificial joints. These techniques have been employed by orthopaedic surgeons, for example at Mid-Essex Hospitals Services Trust (MEHT), in primary and revision total hip replacement operations. As a result, the number of patients requiring revision hip surgery due to cup loosening has fallen by 50%. Additionally, these techniques have reduced the recovery time per operation by 3-5 days, which in addition to benefitting the patient have also resulted in an average saving per operation of £1,200.

Submitting Institution

Anglia Ruskin University

Unit of Assessment

General Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Biomedical Engineering
Medical and Health Sciences: Clinical Sciences

Optimising materials interfaces: Supporting the growth of an SME

Summary of the impact

Since the mid-1990s, the Materials and Structures Research Group has been conducting research into materials-joining processes, including metal-ceramic joining for high-temperature applications. The group's research on metal-ceramic interfacial relationships and metal-ceramic joining subsequently assisted Cambridge-based C4 Carbides to optimise metal-to-diamond brazing and develop cutting tools with improved quality and longer lifetimes. Since 2010 the company has also [text removed for publication]

This continuing collaboration has helped C4 Carbides secure a TSB smart award and begin its strategic shift from niche SME to mainstream supplier.

Submitting Institution

University of Hertfordshire

Unit of Assessment

General Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Chemical Sciences: Inorganic Chemistry
Engineering: Materials Engineering

Structural mechanics - enabling weight reduction and performance enhancement of composite aerospace structures (for redaction)

Summary of the impact

For aerospace vehicles, the development of new materials and structural configurations are key tools in the relentless drive to reduce weight and increase performance (in terms of, for example, speed and flight characteristics). The economic drivers are clear — it is widely recognised that it is worth approximately $10k to save one pound of weight in a spacecraft per launch and $500 per pound for an aircraft over its lifetime. The environmental drivers (ACARE 2050) are also clear — reduced aircraft weight leads to lower fuel burn and, in turn, to lower CO2 and NOx emissions. With such high cost-to-weight ratios, there is intense industrial interest in the development of new structural configurations/concepts and enhanced structural models that allow better use of existing or new materials. Analytical structural mechanics models of novel anisotropic structures, developed at the University's Advanced Composites Centre for Innovation and Science (ACCIS), are now used in the industrial design of aircraft and spacecraft. Based on this research, a new, unique anisotropic composite blade, designed to meet an Urgent Operational Requirement for the MoD, is now flying on AgustaWestland EH101 helicopters that are deployed in Theatre. In addition, the new modelling tools and techniques have been adopted by Airbus, AgustaWestland, Cassidian and NASA and incorporated into LUSAS's finite element analysis software. These tools have, for example, been used to inform Airbus's decision to use a largely aluminium wing design rather than a hybrid CFRP/aluminium wing for the A380.

Submitting Institution

University of Bristol

Unit of Assessment

General Engineering

Summary Impact Type

Technological

Research Subject Area(s)

Engineering: Aerospace Engineering, Civil Engineering, Materials Engineering

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