%0 Journal Article %J J Alzheimers Dis %D 2018 %T Revolution of Alzheimer Precision Neurology. Passageway of Systems Biology and Neurophysiology. %A Hampel, Harald %A Toschi, Nicola %A Babiloni, Claudio %A Baldacci, Filippo %A Black, Keith L %A Bokde, Arun L W %A Bun, René S %A Cacciola, Francesco %A Cavedo, Enrica %A Chiesa, Patrizia A %A Colliot, Olivier %A Coman, Cristina-Maria %A Dubois, Bruno %A Duggento, Andrea %A Durrleman, Stanley %A Ferretti, Maria-Teresa %A George, Nathalie %A Genthon, Remy %A Habert, Marie-Odile %A Herholz, Karl %A Koronyo, Yosef %A Koronyo-Hamaoui, Maya %A Lamari, Foudil %A Langevin, Todd %A Lehéricy, Stéphane %A Lorenceau, Jean %A Neri, Christian %A Nisticò, Robert %A Nyasse-Messene, Francis %A Ritchie, Craig %A Rossi, Simone %A Santarnecchi, Emiliano %A Sporns, Olaf %A Verdooner, Steven R %A Vergallo, Andrea %A Villain, Nicolas %A Younesi, Erfan %A Garaci, Francesco %A Lista, Simone %K Alzheimer Disease %K Animals %K Brain %K Humans %K Neurology %K Neurophysiology %K Precision Medicine %K Systems Biology %K Translational Medical Research %X

The Precision Neurology development process implements systems theory with system biology and neurophysiology in a parallel, bidirectional research path: a combined hypothesis-driven investigation of systems dysfunction within distinct molecular, cellular, and large-scale neural network systems in both animal models as well as through tests for the usefulness of these candidate dynamic systems biomarkers in different diseases and subgroups at different stages of pathophysiological progression. This translational research path is paralleled by an "omics"-based, hypothesis-free, exploratory research pathway, which will collect multimodal data from progressing asymptomatic, preclinical, and clinical neurodegenerative disease (ND) populations, within the wide continuous biological and clinical spectrum of ND, applying high-throughput and high-content technologies combined with powerful computational and statistical modeling tools, aimed at identifying novel dysfunctional systems and predictive marker signatures associated with ND. The goals are to identify common biological denominators or differentiating classifiers across the continuum of ND during detectable stages of pathophysiological progression, characterize systems-based intermediate endophenotypes, validate multi-modal novel diagnostic systems biomarkers, and advance clinical intervention trial designs by utilizing systems-based intermediate endophenotypes and candidate surrogate markers. Achieving these goals is key to the ultimate development of early and effective individualized treatment of ND, such as Alzheimer's disease. The Alzheimer Precision Medicine Initiative (APMI) and cohort program (APMI-CP), as well as the Paris based core of the Sorbonne University Clinical Research Group "Alzheimer Precision Medicine" (GRC-APM) were recently launched to facilitate the passageway from conventional clinical diagnostic and drug development toward breakthrough innovation based on the investigation of the comprehensive biological nature of aging individuals. The APMI movement is gaining momentum to systematically apply both systems neurophysiology and systems biology in exploratory translational neuroscience research on ND.

%B J Alzheimers Dis %V 64 %P S47-S105 %8 2018 %G eng %U https://content.iospress.com/download/journal-of-alzheimers-disease/jad179932?id=journal-of-alzheimers-disease%2Fjad179932 %N s1 %1 http://www.ncbi.nlm.nih.gov/pubmed/29562524?dopt=Abstract %R 10.3233/JAD-179932 %0 Journal Article %J J Alzheimers Dis %D 2016 %T Functional Connectivity of Ventral and Dorsal Visual Streams in Posterior Cortical Atrophy. %A Migliaccio, Raffaella %A Gallea, Cécile %A Kas, Aurélie %A Perlbarg, Vincent %A Samri, Dalila %A Trotta, Laura %A Michon, Agnès %A Lacomblez, Lucette %A Dubois, Bruno %A Lehéricy, Stéphane %A Bartolomeo, Paolo %K Aged %K Alzheimer Disease %K Atrophy %K Case-Control Studies %K Cerebral Cortex %K Female %K Humans %K Image Processing, Computer-Assisted %K Magnetic Resonance Imaging %K Male %K Mental Status Schedule %K Middle Aged %K Neuropsychological Tests %K Oxygen %K Visual Pathways %X

BACKGROUND: Posterior cortical atrophy (PCA) induces progressive dysfunction of ventral and dorsal visual networks. Little is known, however, about corresponding changes in functional connectivity (FC).

OBJECTIVES: To investigate FC changes in the visual networks, their relationship with cortical atrophy, and the association with Alzheimer's disease (AD) pathology.

METHODS: Ten PCA patients and 28 age-matched controls participated in the study. Using resting state fMRI, we measured FC in ventral and dorsal cortical visual networks, defined on the basis of a priori knowledge of long-range white matter connections. To assess the relationships with AD, we determined AD biomarkers in cerebrospinal fluid and FC in the default mode network (DMN), which is vulnerable to AD pathology. Voxel-based morphometry analysis assessed the pattern of grey matter (GM) atrophy.

RESULTS: PCA patients showed GM atrophy in bilateral occipital and inferior parietal regions. PCA patients had lower FC levels in a ventral network than controls, but higher FC in inferior components of the dorsal network. In particular, the increased connectivity correlated with greater GM atrophy in occipital regions. All PCA patients had positive cerebrospinal fluid biomarkers for AD; however, FC in global DMN did not differ from controls.

CONCLUSIONS: FC in PCA reflects brain structure in a non-univocal way. Hyperconnectivity of dorsal networks may indicate aberrant communication in response to posterior brain atrophy or processes of neural resilience during the initial stage of brain dysfunction. The lack of difference from controls in global DMN FC highlights the atypical nature of PCA with respect to typical AD.

%B J Alzheimers Dis %V 51 %P 1119-30 %8 2016 %G eng %N 4 %1 http://www.ncbi.nlm.nih.gov/pubmed/26923019?dopt=Abstract %R 10.3233/JAD-150934