Severe ocular disorders are affecting the lives of more than 100Mill people world-wide and at least 25% of the population above 70 years of age, a growing demographic group in EU. More than 8 million people lose their lives to cancer every year, making cancer a leading cause of pre-mature mortality in the world. The main hallmarks of severe eye conditions (i.e angiogenesis, inflammation and vascular permeability) play also pivotal roles in cancer, being therapeutic targets to treat both kind of diseases. The overall goal of 3D-NEONET is the improvement of available treatments for cancer and ocular disease by enhancing drug discovery-development and delivery to targeted tissues, through advanced international co-operation between academic and non-academic partners. The interdisciplinary expertise provided by 18 partners in 7 countries encompasses among others: drug screens, ADME, toxicology, preclinical models, nanotechnology, biomaterials and clinical trials. After the success with ongoing FP7-IAPP project 3D-NET (Drug Discovery and Development of Novel Eye Therapeutics; (www.ucd.ie/3dnet), we are assembling 3D-NEONET, this enlarged European interdisciplinary consortium that will join forces and exchange skills to enhance current therapies in oncology and ophthalmology. The 3 global objectives of 3D-NEONET are: 1- Enhance the discovery and development of novel drugs, targets and biomarkers for ophthalmology and oncology. 2- Improve the Delivery of Therapeutics for Oncology and Ophthalmology 3- Enhancement of Research, Commercial and Clinical Trial Project Management Practices in these fields. Through participation in the program, 3D-NEONET is the vehicle for driving synergies between academic and non-academic participants leading to increased scientific and technological excellence as well as tangible innovative outputs that will strengthen the competitiveness of both the researchers and industries of the network even beyond the lifetime of the network.

Cancer remains the leading cause of disease-related death in children. For the ~25% of children who experience relapses of their malignant solid tumors, usually after very intensive first-line therapy, curative treatment options are scarce. Preclinical drug testing to identify promising treatment options that match the molecular make-up of the tumor is hampered by the facts that i) molecular genetic data on pediatric solid tumors from relapsed patients and thus our understanding of tumor evolution and therapy resistance are very limited to date and ii) for many of the high-risk entities no appropriate and molecularly well characterized patient-derived models and/or genetic mouse models are currently available. Thus, quality-assured upfront preclinical testing of novel molecularly targeted compounds in a (saturated) repertoire of well-characterized models will establish the basis to increase therapeutic successes of these drugs in children with solid malignancies. Since these tumors are overall genetically much less complex than their adult counterparts, it is anticipated that it will be easier to identify powerful predictive biomarkers to allow for accurate matching of targets and drugs. To address this high, as yet unmet clinical need, we have formed the ITCC-P4 consortium consisting of academic and commercial partners from 8 European countries and covering the full spectrum of qualifications needed for quality-assured preclinical drug development including expertise in patient derived models, histopathology, in vivo pharmacology, bioinformatics and data management, centralized testing capabilities, medical expertise regarding the entities in question, regulatory knowledge, and project management of large consortia. With this consortium in a public-private partnership with the participating pharma companies we strongly believe to be ideally positioned to greatly expedite the development of more precise and efficacious drugs for children with malignant solid tumors