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Research by Professor Parmjit Jat (first at the Ludwig Institute for Cancer Research, then part of UCL; later at the UCL Institute of Neurology) established and applied the critically important scientific concept of conditional immortalisation to a wide variety of cell lines, enabling cells to be grown indefinitely in vitro but differentiate upon altering the growth conditions. Two companies were established in partnership with Jat to exploit this research, ReNeuron (now worth £63.5m and publicly traded on the London AIM market) and XCellSyz (now part of Lonza AG). More than 20 patents based on Professor Jat's work have been issued. Reagents based on his research have been evaluated, licensed and used by 17 companies worldwide: Amgen, Amylin, Boehringer Mannheim, Cell Genesys, Chiron, Eli Lilly, Genentech Inc., Genetics Institute, Immunex, Johnson & Johnson, Medarex, Novartis, Ortho Pharm., Pfizer Inc., Regeneron, ReNeuron, Takeda, EMD Serono, and XCellSyZ/Cambrex Bioscience/Lonza.
The Cybernetics team at the University of Reading works at the frontier of human-machine interaction. The group carries out research on therapy and human enhancement in collaboration with medical professionals, to research new therapeutic treatments for patients with paralysis. Our work has led to the first human implantation of BrainGate, an intelligent deep brain stimulator, and the culturing of neurons within a robot body. Our work has been used by neurosurgeons in experimental human trials with the aim to enhance the standard of living of paralysed individuals. This ground breaking, and sometimes controversial work, has sparked widespread discussion and debate in the public sphere, within the media and at the government level, on the use of machines to enhance humans and vice versa.
Brain diseases cost European healthcare agencies approximately €800 billion each year, but are very poorly understood. Neuroscientists and cyberneticists at the University of Reading study how individual brain cells subserve higher cognitive functions, using brain-computer interfaces to understand how individual cells form neuronal networks. This work has engaged the public imagination through mainstream media, attracted investment from pharmaceutical companies whose drug development programmes demand an understanding of how cellular networks function in the brain and enhanced the use of stem cell derived human neural tissue, thereby enabling a reduction in the use of animals in such research.
Neural stem cells offer enormous therapeutic potential for stroke but they require regulatory approval. Researchers at King's College London (KCL) devised a technology to immortalise stem cells, generated clinical-grade neural stem cell lines and demonstrated efficacy in an animal model of stroke. KCL research underpins the first approvals in the UK for a therapeutic stem cell product. This led to an industry-sponsored clinical trial of a stem cell therapeutic that has demonstrated vital improvement in all the first five stroke patients treated. KCL research has made a significant impact by considerably reducing the timetable for delivering potential therapies which will affect the life sciences industry and the process now in place acts as a model for other technology developments in this area.
Cancer research at the University of Salford focuses on developing new and improved treatments for cancer, particularly for children with cancer, demonstrating the following impact:
3D polyHIPE scaffold materials and synthetic retinoids developed at Durham University for applications in cell biology have been commercialized by Reinnervate, a Durham spin-out company, using a patent/licensing strategy. Reinnervate has raised £8m venture capital investment and has employed an average of 12 FTE staff since 2008, peaking at 27 in 2012. Polystyrene-based highly porous polyHIPE materials which act as 3D in vitro cell culture scaffolds were launched under the Alvetex® brand in November 2010 and a retinoid derivative, designed to control cellular development including stem cell differentiation down neural pathways, was launched as ec23®. The products have won several awards and Alvetex® was voted one of "The Scientist" magazine's top 10 Life Science Innovations of 2010.
Fundamental to effective treatment of diabetes is the understanding of complex mechanisms regulating the function and demise of insulin-secreting pancreatic beta-cells. Inherent limitations relating to pancreatic beta-cell supply coupled with short functional life in culture prompted the challenge to establish model clonal human beta-cells. Ulster exploited an innovative approach to first establish clonal rodent beta-cells. Further development of our novel technology resulted in the generation, patent protection, and commercialisation of world-first electrofusion-derived functional human beta-cells. Our unique and valuable beta-cell lines have been licensed to multi-national pharmaceutical companies for diabetes drug development and further commercialised by sales through ECACC (now Public Health England) to directly impact on both bio-industry and the international research community by providing a limitless supply of high quality model beta-cells for translational research and diabetes drug development.
Seven patients with avascular necrosis of the femoral head and bone cysts have been treated successfully with skeletal stem cell therapy, developed by Southampton researchers, resulting in an improved quality of life. This unique multi-disciplinary approach linking nano-bioengineering and stem cell research could revolutionise treatment for the 4,000 patients requiring surgery each year in the UK and reduce a huge financial burden on the NHS. The work has been granted three patents and the team are in discussions on development of the next generation of orthopaedic implants with industry.
Pioneering research in miniature in-vitro microfluidic diagnostic systems at the University of Southampton has produced major economic impacts by driving new business activities in major multinational corporations. Philips Research Cambridge are investing £5 million p.a. and employing 12 FTEs to develop new Point of Care systems for rapid diagnosis and management of disease based on the research. Patented advances in electronic fluid-handling technologies is driving £3 million R&D investment in Sharp Labs Europe in partnership with Southampton to develop a rapid assay platform for prompt detection of antibiotic-resistant bacterial infections. Health impacts from the research are the provision of new home based diagnostics that provide targeted and early risk identification resulting in improved patient healthcare and reduced costs.
Research into novel immunotherapies has given rise to a novel drug (EtxB), which is now in Phase II clinical trials, and to a profitable contract research company partnering with the pharmaceutical industry to develop their compounds. Trident Pharmaceuticals was formed around patents filed by the University of Bristol, has received investment of [text removed for publication], successfully completed Phase I trials (2011) and is in the midst of Phase IIa trials in humans with inflammatory disease (2013). KWS BioTest arose as a result of the underpinning research and experience gained from developing EtxB, and is now a leading contract research organisation working with pharmaceutical and biotechnology companies developing novel treatments for human disease. KWS has directly contributed to the development of therapies at more than 75 different companies, employs 28 people, has exported [text removed for publication] and was 2012 winner of a Biomedical iNet Award for outstanding business achievement.