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A low-cost, efficient, blood cell salvage technology (HemoSep) has resulted from research carried out at Strathclyde between 2008 and 2013. The novel technology has been patented and licensed to Brightwake Ltd., who manufacture the device in the UK and market it through a global distribution network. HemoSep has now been used in clinical centres across Europe, North America, and South Africa since its commercial launch in late 2012. The use of the device has been shown to reduce the need for donor blood transfusions in open-heart surgical patients by at least 1 unit (450 ml) with an associated reduction in transfusion related complications such as heightened inflammatory response and bleeding. The reduction in blood transfusions associated with the use of HemoSep has a considerable cost benefit to healthcare providers (in North America blood costs up to $1600 per unit). In addition, commercialisation of HemoSep has led to the creation of new manufacturing, marketing and sales jobs in the UK and overseas.
Malaria is endemic in more than 100 countries but its rapid and accurate diagnosis in locations remote from clinical laboratory facilities remains challenging yet desperately needed. This case study describes how scientific discoveries made in the field of digital data storage have been developed and applied to deliver a rapid, reliable and low cost malaria diagnosis sensor suitable for field application. Diagnostic devices have been both laboratory-tested and clinically trialled on over 900 patients under adverse field conditions in malaria endemic countries with very promising results. The health impact includes not only significantly reducing unnecessary treatments but potentially saving millions of lives.
A long programme of research By Neil Avent has led to the development of powerful screening and diagnostic measures. It has enabled the implementation of molecular blood grouping and Non- invasive prenatal diagnosis (NIPD) into clinical use. The work began with research that took the lead in developing the commercially available products BLOODchip and MLPA, used extensively in the management of difficult to transfuse patients. This was developed into investigations of NIPD of fetal blood groups (particularly RhD), and through EC funding, drove workshops to establish non-invasive RhD typing as routine in the clinical management of haemolytic disease of the fetus and newborn. This work has shaped the standardisation of NIPT for fetal Rhesus D (RhD) and fetal sexing via External Quality Assessment (EQA) and the EC network Eurogentest.
Research at UCL on human haemolytic anaemias known as the `hereditary stomatocytoses' has improved diagnosis of these conditions, meaning that patients now avoid unnecessary and potentially life-threatening splenectomies, and inappropriate investigation and treatment for raised potassium levels. Identification of a common single nucleotide polymorphism that causes apparently normal red blood cells to leak salt when cooled (as is normal procedure with donated blood) has raised awareness of this issue in the NHS Blood and Transfusion service, with the result that individuals with this condition have been identified among existing donors, and work is underway to develop a screening method to exclude such individuals from donating blood that cannot be stored safely. Finally, the research has facilitated diagnosis of the recessive metabolic disorder phytosterolaemia by blood count, allowing these individuals to be given appropriate dietary treatment to control their cholesterol levels.
The MRC Prion Unit was established at UCL in 1998 to address national public health issues posed by bovine spongiform encephalopathy (BSE) and variant Creutzfeldt-Jakob disease (vCJD). One of our key strategic priorities has been to create a validated blood test for vCJD in order to protect public health through the screening of donated blood and organs for transplantation. The blood test we have developed has been demonstrated to detect infection in over 70% of patients with vCJD with, to date, 100% specificity and is now in use at the National Prion Clinic for evaluation.
The Boutelle team has developed a biosensor that uses rapid-sampling microdialysis (rsMD) to detect ischaemia (restricted blood supply to tissue) during surgery and intensive care. The rsMD biosensor is implanted into tissue at risk and provides a real-time readout of chemical markers of metabolism. By 2009, technical improvements researched in the Department of Bioengineering had made the system suitable for routine clinical use. The system has reduced morbidity and mortality by alerting the surgical team to otherwise undetected ischaemia. It has been used by an international consortium of clinical centres to help decide treatment in approximately 100 patients with brain injury. More recently it was adopted by a Portsmouth hospital to monitor cancer patients undergoing reconstruction of the face and jaw; the biosensor detected a failure of perfusion in transplanted tissue in two of the first ten patients, prompting the surgical team to remove otherwise undetected blood clots that could have led to death from septicaemia.
For stroke patients and any patient undergoing surgery the time period from diagnosis to treatment is a major factor in clinical outcomes. Research carried out at the University of Warwick has led to the development of sensors that can be used to measure, in whole unprocessed blood, diagnostically useful analytes that can be used to select the best therapeutic treatments. Point-of- care diagnosis and prompt referral to an appropriate care pathway, facilitated by the use of biosensors, will result in efficiency savings for healthcare professionals and the NHS in the long- term, and will also improve patient outcomes. To commercialize these biosensors, Sarissa Biomedical Ltd was founded in 2002, as a UK-based spinout from the University of Warwick. Sarissa sells, around the world, microelectrode biosensors fabricated by a unique enzyme deposition technology protected by patents filed in 2004 and 2008 by the University of Warwick. The diagnostic sensors are based on technology that incorporates Ruthenium Purple and use a sol-gel coating to entrap enzymes on a microelectrode. Sarissa is pursuing human trials of its biosensors as diagnostic tools in two main areas: stroke, and trauma with associated sepsis.