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Grant
Agency: Cordis | Branch: H2020 | Program: SGA-RIA | Phase: FETFLAGSHIP | Award Amount: 89.00M | Year: 2016

Understanding the human brain is one of the greatest scientific challenges of our time. Such an understanding can provide profound insights into our humanity, leading to fundamentally new computing technologies, and transforming the diagnosis and treatment of brain disorders. Modern ICT brings this prospect within reach. The HBP Flagship Initiative (HBP) thus proposes a unique strategy that uses ICT to integrate neuroscience data from around the world, to develop a unified multi-level understanding of the brain and diseases, and ultimately to emulate its computational capabilities. The goal is to catalyze a global collaborative effort. During the HBPs first Specific Grant Agreement (SGA1), the HBP Core Project will outline the basis for building and operating a tightly integrated Research Infrastructure, providing HBP researchers and the scientific Community with unique resources and capabilities. Partnering Projects will enable independent research groups to expand the capabilities of the HBP Platforms, in order to use them to address otherwise intractable problems in neuroscience, computing and medicine in the future. In addition, collaborations with other national, European and international initiatives will create synergies, maximizing returns on research investment. SGA1 covers the detailed steps that will be taken to move the HBP closer to achieving its ambitious Flagship Objectives.


Chronic aortic aneurysms are permanent and localized dilations of the aorta that remain asymptomatic for long periods of time but continue to increase in diameter before they eventually rupture. Left untreated, the patients prognosis is dismal, since the internal bleeding of the rupture brings about sudden death. Although successful treatment cures the disease, the risky procedures can result in paraplegia from spinal cord ischaemia or even death, particularly for aneurysms extending from the thoracic to the abdominal aorta and thus involving many segmental arteries to the spinal cord, i.e. thoracoabdominal aortic aneurysms of Crawford type II. Although various strategies have achieved a remarkable decrease in the incidence of paraplegia, it is still no less than 10 to 20%. However, it has been found that the deliberate occlusion of the segmental arteries to the paraspinous collateral network finally supplying the spinal cord does not increase rates of permanent paraplegia. A therapeutic option, minimally invasive segmental artery coil embolization has been devised which proceeds in a staged way to occlude groups of arteries under highly controlled conditions after which time must be allowed for arteriogenesis to build a robust collateral blood supply. PAPA-ARTiS is a phase II trial to demonstrate that a staged treatment approach can reduce paraplegia and mortality dramatically. It can be expected to have both a dramatic impact on the individual patients quality of life if saved from a wheelchair, and also upon financial systems through savings in; 1) lower costs in EU health care; 2) lower pay-outs in disability insurance (est. at 500k in Year 1), and; 3) loss of economic output from unemployment. Approx. 2500 patients a year in Europe undergo these high risk operations with a cumulative paraplegia rate of over 15%; therefore >100M per year in costs can be avoided and significantly more considering the expected elimination of type II endoleaks.


Grant
Agency: Cordis | Branch: H2020 | Program: RIA | Phase: PHC-09-2015 | Award Amount: 28.14M | Year: 2016

Many HIV vaccine concepts and several efficacy trials have been conducted in the prophylactic and therapeutic fields with limited success. There is an urgent need to develop better vaccines and tools predictive of immunogenicity and of correlates of protection at early stage of vaccine development to mitigate the risks of failure. To address these complex and challenging scientific issues, the European HIV Vaccine Alliance (EHVA) program will develop a Multidisciplinary Vaccine Platform (MVP) in the fields of prophylactic and therapeutic HIV vaccines. The Specific Objectives of the MVP are to build up: 1.Discovery Platform with the goal of generating novel vaccine candidates inducing potent neutralizing and non-neutralizing antibody responses and T-cell responses, 2. Immune Profiling Platform with the goal of ranking novel and existing (benchmark) vaccine candidates on the basis of the immune profile, 3. Data Management/Integration/Down-Selection Platform, with the goal of providing statistical tools for the analysis and interpretation of complex data and algorithms for the efficient selection of vaccines, and 4. Clinical Trials Platform with the goal of accelerating the clinical development of novel vaccines and the early prediction of vaccine failure. EHVA project has developed a global and innovative strategy which includes: a) the multidisciplinary expertise involving immunologists, virologists, structural biology experts, statisticians and computational scientists and clinicians; b) the most innovative technologies to profile immune response and virus reservoir; c) the access to large cohort studies bringing together top European clinical scientists/centres in the fields of prophylactic and therapeutic vaccines, d) the access to a panel of experimental HIV vaccines under clinical development that will be used as benchmark, and e) the liaison to a number of African leading scientists/programs which will foster the testing of future EHVA vaccines through EDCTP


Grant
Agency: Cordis | Branch: H2020 | Program: RIA | Phase: PHC-14-2015 | Award Amount: 6.00M | Year: 2016

The goal of BATCure is to advance the development of new therapeutic options for a group of rare lysosomal diseases - neuronal ceroid lipofuscinoses (NCL) or Batten disease. There are > thousand affected across Europe, with a combined incidence of c.1:100 000. The NCLs are devastating and debilitating genetic disorders that mainly affect children, who suffer progressive dementia and motor decline, visual failure and epilepsy, leading to a long period of complete dependence on others, and eventually a premature death. Existing palliative treatment can reduce, but does not eliminate, the burden of seizures and the progressively worsening effects on the whole body due to decreasing CNS influence and control. There are no curative treatments in the clinic for any type of NCL. We will follow a novel integrated strategy to identify specific gene and small molecule treatments for three genetic types of Batten disease that include the most prevalent world-wide, juvenile CLN3 disease, and in southern and mediterranean Europe, CLN6 and CLN7 diseases. To develop new therapies for these 3 types of Batten disease, BATCure will: 1. Create new models, tools and technologies for developing and testing therapies 2. Further delineate disease biology and gene function to identify new therapeutic target pathways utilising yeast and pluripotent stem cell models 3. Identify biochemical therapeutic target pathways, facilitate effective evaluation of preclinical therapies and improve diagnostics 4. Extend a comprehensive natural history beyond the brain to include cardiology, the spinal cord, PNS, psychiatric and metabolic changes 5. Identify new and repurpose existing small molecule therapy 6. Triage new compound treatments in zebrafish, a high-throughput small vertebrate model 7. Deliver and monitor new treatments using mouse models 8. Provide a novel mechanism to involve patients and their families to inform and fully contribute to therapy development and prepare for clinical trials

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