key: cord-1035469-6y2pdkgi authors: Marson, Anthony G.; Bassetti, Claudio L. A. title: EAN congress highlights challenges — predict, prevent, repair date: 2020-06-26 journal: Nat Rev Neurol DOI: 10.1038/s41582-020-0384-9 sha: d04850fd405ee6767e7562c2ffa85657e2a88f0b doc_id: 1035469 cord_uid: 6y2pdkgi After going virtual, the European Academy of Neurology 2020 Congress became the biggest neurology meeting in history. The overarching theme was ‘Time for action: predict, prevent, repair’ — three upcoming Reviews in Nature Reviews Neurology, written by speakers at the congress, highlight the importance of the theme across neurology. In the opening session of the congress, president Claudio Bassetti outlined the strategic priorities of the EAN for the next 4 years 1 -science, education, membership and advocacy -and the actions taken by the EAN to foster international collaborations to promote knowledge, information and research about the COVID-19 pandemic 2 . The highlight of the session was the lecture from Yann LaCun, a world-renowned computer scientist who is considered to be a godfather of artificial intelligence and deep learning and who shared the 2019 Alan Turing prize 3 . He talked about how the organization of the visual cortex inspired his work on convolutional neural networks and went on to describe practical applications of artificial intelligence and computer vision, such as interpretation of medical images. The overarching theme of the Virtual Congress was 'Time for action: predict, prevent, repair' . This theme was intended as a 'call to arms' in light of the growing burden of neurological diseases, which are a leading cause of mortality and morbidity worldwide but are under-resourced with respect to clinical services and research investment 4 . To reduce this burden, we must be able to predict who is at risk of disease or adverse outcomes throughout the patient journey, we need better therapies and public health strategies for the prevention of disease and adverse outcomes, and we must develop therapies to repair the nervous system after injury and to halt and, hopefully in the future, reverse degenerative diseases. The resonance of these principals has increased in recent months as we apply them to the COVID-19 crisis as we must predict those at risk, prevent the spread through 'track and trace' programmes and repair our health and social care systems and our economies. Nature Reviews Neurology and the EAN have again collaborated to bring you three Reviews from speakers at the Virtual Congress, highlighting advances that align with the overarching theme. These Reviews will be published over the coming weeks and will be available in an online collection. The first of these Reviews, from Lubetzki et al. 5 , (in the same issue as this Comment) highlights how www.nature.com/nrneurol elucidation of fundamental neurobiology is key to improving our ability to prevent degeneration and promote repair in neurological conditions. Lubetzki et al. 5 focus on the nodes of Ranvier in multiple sclerosis (MS), which enable rapid conduction along myelinated axons. The functions of these nodes in the PNS have largely been identified, but their functions in the CNS are poorly understood. The research discussed in the Review means that the nodes of Ranvier are now known to have a role in fine-tuning conduction velocities through variation in their lengths and diameters, thereby strengthening and synchronizing circuits to meet information processing needs. They are also important sites of glialneuronal interactions, known as an 'axo-glial hub' . Our understanding of protein assembly at CNS nodes has increased substantially, as has our understanding of how these processes are affected by demyelinating diseases. Changes in gene expression and clustering of ion channels along axons might contribute to neurodegeneration, raising the possibility of treatments that target specific sodium or potassium channel subtypes to prevent the degeneration. The second Review, from Sun et al. 6 , focuses on inflammatory mechanisms. Inflammation is fundamental to primary inflammatory nervous system diseases and neurological infections, and is important in cerebrovascular, degenerative and other neurological diseases. For example, a lecture in the overarching theme plenary session of the Virtual Congress covered the importance of inflammation in atheromatous plaques 7 , how it increases the risk of stroke and how treatments that target inflammatory mechanisms could prevent stroke. However, Sun et al. discuss another area in which our understanding is advancing rapidly: the autoimmune CNS autoantibody-mediated diseases, including autoimmune encephalitis and neuromyelitis optica spectrum disorders. These conditions involve production of pathogenic autoantibodies to neuro-glial surface antigens. An ever-increasing number of such antibodies act as biomarkers of disease and can inform therapy. Delayed therapy is associated with poorer outcomes, so effective therapeutic strategies can prevent unnecessary deterioration. Sun et al. 6 review our rapidly advancing knowledge of B cell immunobiology, which is critical to our understanding of the pathogenesis of these conditions and to the development of new treatment paradigms. They describe elegant experiments that indicate a breakdown of immune tolerance checkpoints, resulting in pathogenic autoantibody-producing B cells that evade these checkpoints. They also describe how long-lived plasma cells migrate to the CNS, where they produce pathogenic autoantibodies, explaining high antibody titres in the CSF. They discuss new treatment targets to investigate, including B cell migration, differentiation and survival in the CSF milieu. In the third Review, Nabbout and Kuchenbuch 8 address predictive, preventative and precision medicine strategies in epilepsy. Though epilepsy is a common condition that affects 50 million people worldwide and a range of seizure types and syndromes are recognized, the underlying aetiology (genetic, metabolic and structural) and pathophysiology remains poorly understood. Through worldwide collaborative efforts 9 , we have made some progress in our understanding of the genetic aetiology of some epilepsies, particularly the severe childhood epilepsies for which monogenic causes have been found. This progress has resulted in targeted treatment, such as avoiding sodium channel blockers in SCN1A-associated Dravet syndrome, using sodium channel blockers in epilepsy associated with SCN2A gain-of-function mutations and avoiding them in epilepsy associated with loss-of-function mutations. The challenge is to turn these discoveries into new therapeutic options for these rare and catastrophic epilepsies, and to identify the genetic variants associated with the common epilepsies 10 , including the development of polygenic and multimodal risk scores. In switching to a virtual congress, the EAN has demonstrated itself to be a vibrant and adaptable organization and has delivered the largest neurology congress to date. We will now rise to the challenge of delivering hybrid physical and virtual meetings in future. Only by working together and addressing such challenges can we raise the profile of neurological diseases and tackle the grand challenges across neurological disciplines, illustrated in the Reviews -to predict, prevent and repair. The European Academy of Neurology is 6 years old: challenges, opportunities and strategic priorities for the future A call from the European Academy of Neurology on COVID-19 The 3 'Godfathers' of AI have won the prestigious $1 m Turing Prize The global burden of neurological disorders: translating evidence into policy Nodes of Ranvier during development and repair in the CNS The B cell immunobiology that underlies CNS autoantibody-mediated diseases A risk score including carotid plaque inflammation and stenosis severity improves identification of recurrent stroke Impact of predictive, preventative and precision medicine strategies in epilepsy Ultra-rare genetic variation in the epilepsies: a whole-exome sequencing study of 17,606 individuals Genome-wide mega-analysis identifies 16 loci and highlights diverse biological mechanisms in the common epilepsies The authors declare no competing interests.