Integrated Calendar

: I will review a set of biologically inspired NeuroImaging methods (i.e. methods that take into consideration the brain topography, neuronal adaptation and population receptive fields, brain functional connectivity and so on), that we developed and/or refined to shed light on maps and computations in the human brain. Starting from retinotopy, we used partial correlations resting-state functional connectivity analysis to show that the large-scale topographical biases in all 3 dimensions of retinotopy are preserved in individuals without any visual experience. I will discuss how this result challenges classical views of retinotopy as the key organizational principle for computations in the visual system, and further suggest plasticity principles beyond classical Hebbian learning. Next, we use virtual environments to show that key retinotopic regions (mainly in the dorsal visual stream) are recruited not only during vision-based navigation but even when early-blind and sighted-blindfolded learn to navigate these same environments using audition. I will then show how such approaches can be applied to study the whole-body somatosensory-motor system, and demonstrate that topographical gradients are far more widespread than previously known. These findings help to bridge gaps between animal and human studies, and have clinical relevance to improve and refine deep-brain-stimulation and imaging-based diagnostics. Finally, I will briefly present the development of crossmodal adaptation and multiphase spectral analysis to study topographical binding and crossmodal integration. Based on all of these results I will discuss the intriguing hypothesis that our brain is topographically organized for high-order cognitive functions as well, and discuss our plans to combine the aforementioned approaches with the use of the high-field imaging (7T) that is required to test it. I will conclude by summarizing the wide set of tools that enable us to investigate and gain novel insights into the nature of the Topographical Multisensory Human Brain mind.

(Most relevant papers for the talk: Striem-Amit et al. Neuron 2012; Cerbral Cortex 2012; Curr Biol 2014; Brain 2015; Zeharia et al. PNAS 2012; J Neurosci 2015; Saadon-Grosman et al. PNAS 2015; Murray, et al. Trends Neurosci 2016 (cond. accepted); Maidenbaum et al. (in preparation)); Siuda-Krzywicka et al. Elife 2016; Sabbah et al. NeuroImage 2016 (accepted).