Matuszewski, JacekKossowski, BartoszBola, LukaszBanaszkiewicz, AnnaPaplinska, MalgorzataGyger, LucienKherif, FerathSzwed, MarcinFrackowiak, Richard S.Jednorog, KatarzynaDraganski, BogdanMarchewka, Artur2021-03-262021-03-262021-03-262021-02-1510.1016/j.neuroimage.2020.117613https://infoscience.epfl.ch/handle/20.500.14299/176792WOS:000617281900007A growing body of empirical evidence supports the notion of diverse neurobiological processes underlying learning-induced plasticity changes in the human brain. There are still open questions about how brain plasticity depends on cognitive task complexity, how it supports interactions between brain systems and with what temporal and spatial trajectory. We investigated brain and behavioural changes in sighted adults during 8-months training of tactile Braille reading whilst monitoring brain structure and function at 5 different time points. We adopted a novel multivariate approach that includes behavioural data and specific MRI protocols sensitive to tissue properties to assess local functional and structural and myelin changes over time. Our results show that while the reading network, located in the ventral occipitotemporal cortex, rapidly adapts to tactile input, sensory areas show changes in grey matter volume and intra-cortical myelin at different times. This approach has allowed us to examine and describe neuroplastic mechanisms underlying complex cognitive systems and their (sensory) inputs and (motor) outputs differentially, at a mesoscopic level.NeurosciencesNeuroimagingRadiology, Nuclear Medicine & Medical ImagingNeurosciences & NeurologyRadiology, Nuclear Medicine & Medical Imagingbrain plasticitylongitudinal designtactile braille readingintracortical myelinmultimodal mriquantitative mritext::journal::journal article::research article