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Individuals with Xeroderma pigmentosum (XP) are extremely susceptible to sunlight-induced skin cancers and, in some cases, develop neurological problems. Alan Lehmann has developed a cellular diagnostic test for this disorder. This test is now conducted as an integral part of a multi-disciplinary XP specialist clinic in London, which was established as a direct result of Alan Lehmann's research in Sussex and which has led to the improved diagnosis and management of the disorder and an improved quality of life for affected individuals.
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 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.
The UCL Centre for Amyloidosis and Acute Phase Proteins has identified the cause and treatment for the prototypical cryopryin associated periodic syndrome (CAPS), and subsequently for a range of other hereditary and acquired autoinflammatory disorders. As a result of the research, canakinumab was licensed for this condition. In recognition, NHS Specialised Services commissioned the UK CAPS Treatment Service in 2010 to deliver life-changing IL-1 blocking therapy to the national caseload of CAPS patients at UCL.
Diagnostic tests have been successfully developed for identification of the cause of erythrocytosis, particularly in patients with unexplained forms of this rare disease. A diagnostic service with worldwide reach was developed for the genetic characterisation of patients that carry mutations identified by the Queens's group. It deals with approximately 100 samples per year referred for investigation for this rare disease from the UK, Europe and further afield. Proper diagnosis helps in management of patients with erythrocytosis where the problem is not mutation in one of the familiar causative genes. A pan-European web-based database has been established to collect information on long-term outcomes to inform patient management.
Neuroblastoma is a paediatric cancer that arises from the sympathetic nervous system. The average age at diagnosis is 18 months and the disease accounts for approximately 15% of all childhood cancer-related deaths. Determining optimal treatment for individual patients is crucial for increasing chances of survival and for reducing side effects of chemotherapy and radiotherapy. Newcastle-led research identified unbalanced 17q gain as the most common segmental chromosomal abnormality (SCA) in patients with neuroblastoma; this was present in more than 50% of patients. Gain of 17q is now one of the key SCAs used to determine treatment for patients in a European neuroblastoma trial and in UK treatment centres. Newcastle research also led to the development of a simple diagnostic test for the detection of the main SCAs in neuroblastoma.
Congenital myasthenic syndromes (CMS) are inherited neuromuscular disorders caused by defects at neuromuscular junctions, which are often a result of acetylcholine receptor gene mutations. A subset of CMS patients (around 14% in the US and Europe) have limb-girdle myasthenia (LGM). This disease can be highly disabling with symptoms including increasing weakness of skeletal muscles. As a result of collaborative work between Newcastle and Oxford, it was determined that many LGM patients have a mutation of the Dok-7 gene (unrelated to the acetylholine receptor), and do not, therefore, respond to standard CMS treatments. Since then, a number of additional mutations have been discovered, and genetic testing is now available for the majority of known LGM-causative genes. Crucially, Dok-7 patients, and those with other non-receptor related mutations, can now be diagnosed accurately and treated effectively, with ephedrine and salbutamol (in the US, albuterol). This significantly improves these patients' quality of life by enabling them to walk and breathe unassisted.
Research conducted by Professor TM Cox has led to several advances in the management of lysosomal storage disorders; i) development of miglustat (Zavesca®); now available throughout the world (EMA and FDA approved) for adult patients with Gaucher's disease and throughout the European Union and five other countries worldwide for adult and pediatric patients with Niemann- Pick type C disease, ii) development of the potential successor eliglustat; now in Phase 3 clinical trials, iii) identification of a biomarker for Gaucher's: CCL18/PARC, now incorporated into NHS standard operating procedures for monitoring therapeutic intervention. His pre-clinical research into gene therapy for Tay-Sachs disease also helped establish the NIH-funded Gene Therapy Consortium and gain the FDA's pre-IND approval for clinical trials in 2013, which together have raised public awareness of this disease.
Acute promyelocytic leukaemia (APL) is of interest because it is the first cancer that can be cured with drugs that target a unique molecular abnormality. KCL research has developed accurate molecular techniques which are essential to diagnose the disease, guide treatment, and monitor for relapse. Sub-microscopic levels of leukaemic cells remaining in the patient's bone marrow after treatment (referred to as `minimal residual disease') give an early warning of re-occurrence of the disease. Our laboratory has developed sensitive tests for these cells, allowing treatment to be tailored to individual patient needs. This has had a major impact on APL diagnosis and monitoring and has been incorporated in national and international disease-treatment guidelines.
University of Liverpool (UoL) research has characterised patients with pancreatitis at high risk of pancreatic cancer, defining strategies for their management now widespread globally. Clinical and genetic characterisation was conducted through the European Registry of Hereditary Pancreatitis and Familial Pancreas Cancer (EUROPAC), set up by the UoL in 1997 to pioneer secondary screening and trial appropriate management. As a result, it is now widely recommended that patients with a family history of pancreatitis should undergo genotyping and secondary screening, because of their risk of pancreatic cancer.