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Sudden cardiac death causes 4.5 million deaths worldwide each year many of which could be prevented by implantable cardioverter defibrillators (ICDs), but these also carry risks. Research in the groups of Huang and Grace has led to diagnostic assays offering three times the predictive accuracy of current approaches in guiding cardiologists concerning indications for ICD implantation. The assay has been clinically trialled; since 2008, through the trial, the lives of three patients identified by the assay as at high risk were saved. Further work led by Grace and colleagues provided an improved, subcutaneous ICD (SICD); Grace also participated in a US-based clinical trial (NCT00399217) providing the evidence required for FDA approval supporting also later inclusion into NICE guidance. Since 2008 the SICD has been implanted in over 2500 patients in 16 countries.
Basic molecular genetic research undertaken over the last 20 years by UCL Cardiovascular Genetics has had a significant impact on the identification and treatment of patients with familial hypercholesterolaemia (FH). We have developed DNA testing methods in the three genes currently known to cause FH and have established DNA diagnostic protocols which are now in wide use throughout the UK. As a direct consequence of our work, we estimate that up to 3,000 FH patients in the UK have had their diagnosis of FH confirmed by a DNA test. Our work led to the National Institute of Health and Clinical Excellence (NICE) in 2008 strongly recommending DNA and cascade testing and early treatment with high intensity statins, and furthermore, the inclusion of FH checks in the NHS's Vascular Checks programme.
Research at the UCL Institute of Ophthalmology over the last 20 years has resulted in the identification of a large number of novel genes that cause inherited retinal disease. These genes have been incorporated into diagnostic tests, which have allowed molecular diagnosis, improved genetic counselling including pre-natal/pre-implantation diagnosis, better information about prognosis and have informed decisions about which diseases should be prioritised for clinical trials of novel treatments. The identification of these genes has greatly improved understanding of disease mechanisms, an essential prerequisite for developing new treatment approaches such as gene therapy.
Our research on brain/B-type naturietic peptide (BNP) has helped to diagnose both types of heart failure (systolic and diastolic heart failure) and to identify high-risk aortic stenosis patients for surgery. We were first to demonstrate the value of BNP as a biomarker for left ventricular systolic dysfunction, isolated diastolic dysfunction and for aortic stenosis. BNP testing is now recommended in Guidelines as a screening test for patients with suspected heart failure (Class I recommendation) and in the current European Society of Cardiology consensus statement for diagnosis of diastolic heart failure. The European Society of Cardiology Guidelines have also introduced BNP testing in the management of patients with aortic stenosis (Class IIb recommendation).
Understanding and finding treatments for rare disease represents a major challenge across medicine. We have shown this is possible for rare muscle channelopathies and our work has directly benefited the lives of patients. Our 15 year basic research programme has elucidated the genetic architecture and identified new disease mechanisms for these disabling muscle conditions. We also determined the true disease frequency through the only UK epidemiology study. We translated fundamental research into new DNA-based diagnostic testing and electrophysiological diagnostics for rapid and reliable diagnosis. Our research led directly to our centre being commissioned by the NHS (£6m) as the only UK centre for diagnosis and management and we established the UK NHS national genetics channelopathy reference laboratory. We have built the world's largest genetically stratified patient cohorts which allowed us to lead the first international randomised controlled trial. This trial showed clear efficacy of a reprofiled mexiletine. This led to a successful European orphan product status application for this indication and national treatment guidelines.
Our research has had impact on the activities of practitioners and their services, health and welfare of patients, on society and on public policy. New diagnostic tests for genetic deafness have been introduced, and healthcare guidelines and professional standards adopted through our investigation of the aetiology of childhood-onset hearing loss. Disease prevention has been achieved by our research on antibiotic-associated deafness, public awareness of risk to health and hearing has been raised, and we have increased public engagement through debate on scientific and social issues. We have also influenced public policy on ethics of genetic testing for deafness with our research resulting in improved quality, accessibility and acceptability of genetic services among many hard-to-reach groups (deafblind, culturally Deaf, and the Bangladeshi population of East London).
A routine service for genetic diagnosis of familial hypercholesterolaemia (FH) was developed and commissioned by the Northern Ireland Department of Health, based on the identification by the Queen's team of a series of mutations causing this condition. The team then developed novel diagnostic strategies that led to over 900 affected individuals being identified so that treatment could be delivered to them. Samples are received for diagnosis from the UK and Ireland and the work of the Centre helped to inform recent NICE guidance. The laboratory is recognised as an expert laboratory for the diagnosis of inherited lipid disorders by the International Federation for Clinical Chemistry and Laboratory Medicine.
Randomised placebo-controlled trials (RCTs) are the most robust way to demonstrate the effectiveness of medical therapies. The University of Glasgow's Robertson Centre for Biostatistics (RCB) is internationally renowned for its biostatistical input and leading roles on landmark RCTs of cardiovascular therapies. The findings of the BEAUTIFUL and SHIFT studies underpinned European and UK regulatory approval for a novel use of the heart-rate-lowering drug ivabradine, potentially preventing thousands of hospital admissions for heart failure every year. The IONA trial supported UK approval of generic versions of another heart drug (nicorandil), thereby enhancing cost-effectiveness for the NHS. The BEAUTIFUL, SHIFT, DOT-HF and CAPRICORN trials provided the evidence base for US, European and UK guideline recommendations, steering best practice for treatment of patients with heart disease worldwide.
Research at UCL into the genetics of neuronal ceroid lipofuscinoses (NCL) — also known as Batten Disease - has had a global impact on the diagnosis and understanding of this group of diseases. The identification of genes and mutations has led to new diagnostic tests, which inform clinical management in terms of expected disease course and choice of the most effective drugs; prenatal and pre-implantation diagnoses for prevention are also possible. The group has established a new classification of diseases according to gene-based nomenclature. Information about all genes that underlie NCL has been collated in the NCL Mutation Database, which is freely available on the NCL Resource website. The group has also engaged closely with professionals and affected families to maximise the reach and understanding of research.
Research conducted by Professor Tim Goodship and co-workers at Newcastle has had a profound effect on the prognosis for patients with atypical haemolytic uraemic syndrome (aHUS). By engaging in research on the genetic factors underlying the disease they developed an understanding of the molecular mechanisms responsible. Identifying that the majority of patients with aHUS have either acquired or inherited abnormalities of the regulation of complement (part of the immune system) led to the establishment of a UK national service for genetic screening and treatment with the complement inhibitor eculizumab. As eculizumab is now available to patients in England, the progression to end-stage renal failure can be prevented and patients already on dialysis will soon be successfully transplanted.