Log in
Labelled compounds form an essential part of drug discovery and development within the pharmaceutical industry. Novel iridium catalysts, developed by Kerr at WestCHEM since 2008, have introduced a step-change in the ability to label pharmaceutical candidate compounds with radioactive (tritium) or non-radioactive (deuterium) isotopes.
The catalysts are applicable to specific types of compounds that comprise approximately one-third of all drug candidates. Advantages of the catalysts include greater efficacy (less catalyst needed and higher yield of labelled product, giving cost savings), greater speed (efficiency savings), and a significant decrease in radioactive waste compared with previous methods (environmental and safety benefits).
Even since 2008, their adoption within the pharmaceutical industry has been extremely rapid; e.g., the multinational pharmaceutical company AstraZeneca now applies the Kerr methodology to 90% of their relevant candidate compounds. Additional impact has been achieved by Strem Chemicals who have been manufacturing and marketing the catalysts worldwide since October 2012. Even in that very short period, multiple sales have been made on three continents providing economic benefit to the company.
University of Huddersfield research in physical organic chemistry has delivered economic, industrial and societal benefits. It has led to process improvements in chemical manufacturing, most notably in the optimisation of the synthesis of antisense oligonucleotides and in the use of liquid ammonia as a solvent. It has also led to the development of new inhibitors of bacterial β-lactamases for use as antibacterials. The research team's expertise has been reflected in the success of IPOS (Innovative Physical Organic Solutions), a unit established in 2006 to carry out research in process and other areas of chemistry for the chemical industry. IPOS expanded significantly from 2009 to 2013 and has now collaborated with more than 150 companies, many of them based in Yorkshire/Humberside where regeneration is critically dependent on the success of new, non-traditional, high-technology firms and industries. Through these collaborative projects, IPOS has contributed to the growth and prosperity of both regional and national industry.
The EKG technology developed by Newcastle has launched an entirely new spectrum of applications for geosynthetic materials and has resulted in changing established practice in civil, construction and mining engineering. The commercialisation of the technology, linking industry to applications of EKG products and processes, has been driven by the spin-out company Electrokinetic Limited. Amey, a leading international infrastructure services provider, incorporated the EKG technology into £1M projects for Network Rail and the Highways Agency in 2011-12. The end results were a 30% cost saving and 40% reduction in CO2 compared to established methods. The new range of EKG products has been recognised by British Standards, leading to the revision of BS 8006 for reinforced soil in 2010.
Drug development is a highly regulated environment. Identifying the need for an independent, academic-led centre of excellence in research and training of pharmacokinetics, we established the Centre for Applied Pharmacokinetic Research (CAPKR) to engage in problems of generic interest to the Pharmaceutical Industry. CAPKR has been highly influential by informing regulatory practice in Europe and the USA, by establishing and optimising industrial practices related to drug development, particularly those related to drug-drug interactions, by reducing the usage of animals in research and by allowing the commercial development and extensive use of simulation software tools for quantitative prediction of pharmacokinetics in order to improve patients' safety.
The Abraham solvation parameter approach developed at UCL has become integral to the work carried out by drug discovery teams at [text removed for publication] and other major pharmaceutical companies, as well as research and development groups at international chemical companies including Syngenta and [text removed for publication]. It enables chemists to predict physicochemical and biochemical properties of chemicals, including drugs and agrochemicals, rapidly and efficiently, without the need to conduct time-consuming experiments. The method helps drug discovery teams to identify and optimise the most promising compounds, and often results in fewer compounds being made before a candidate is selected, saving time and resources. The approach has been integrated into software used for drug discovery [text removed for publication].
The activities of the Organic Materials Innovation Centre (OMIC) at the University of Manchester generate impact from its research activities through knowledge transfer to industry. This is exemplified by:
Provision of research-based training in the field of printed electronics and sensors to over 250 people from 2008 onwards.
The growth and performance of Biofocus Galapagos Argenta (BGA) and Pulmagen Therapeutics (PT) are underpinned by research from the Imperial-based TeknoMed project that started in 1997. BGA was formed in 2010 through the acquisition of Argenta Discovery (AD) by Biofocus Galapagos for €16.5 million and is one of the world's largest drug discovery service organisations with 390 plus employees and turnover of €135 million [section 5, A]. PT was formed as a separate company to own the complete AD drug pipeline. It develops new medicines to treat asthma, cystic fibrosis and allergic diseases. In 2011 BGA signed agreements with PT for an initial £6million fee and with Genentech for £21.5million.
Global drug crime involving the illicit production of synthetic drugs and the emergence of new legal highs has a detrimental effect on our society and its citizens at all levels. In order to address this global problem, research was conducted that resulted in three significant impacts over the assessment period. These were:
(1) New capability for law enforcement agencies by provision of new tools to identify specific manufacturing routes of illicit drugs and link this back to criminal intelligence data,
(2) Improvement in the accuracy and reliability of identification of legal highs for use by legal practitioners, and
(3) The influencing of policy and protocol for the United Nations Office on Drugs and Crime on addressing legal high drug identification.
The research has underpinned the implementation of new analytical methodologies now routinely used in Malaysia and in over 900 drug sample identification cases in Scotland alone across the assessment period.
Newcastle University research discovered the first potent inhibitors of the DNA repair enzyme poly (ADP-ribose) polymerase 1 (PARP-1) through medicinal chemistry and preclinical work leading to first-in-man clinical studies. This research led to the development of Rucaparib, an agent that inhibits the ability of cancer cells to survive drug treatments or radiotherapy. As a result of Newcastle's research a further 8 PARP inhibitors are in development. Major pharmaceutical companies have invested an estimated $385 million in clinical trials, with at least 7000 patients enrolled in PARP inhibitor trials since 2008. Cancer patients worldwide have already been successfully treated with these new anti-cancer drugs.
Clinical pharmacology studies conducted at Newcastle have led to optimisation of the administration of the chemotherapy drug carboplatin in children with neuroblastoma and other cancers. The research provided the rationale for carboplatin dosing based on patient renal function, with individualised dosing resulting in increased drug efficacy and reduced toxicity. This approach is now in widespread use in national and European treatment protocols, benefitting over 2,500 children. Similar drug monitoring approaches are being implemented for an increasing number of important drugs. Following a recent Newcastle-led national clinical trial, new dosing guidelines for the drug 13-cis retinoic acid have been adopted for high-risk neuroblastoma patients across Europe.