Key word "conscious perception"
Aru J., Rutiku R., Wibral M., Singer W. & Melloni L. (2016) Early effects of previous experience on conscious perception. Neuroscience of Consciousness 1: 1–10.
Aru J., Rutiku R., Wibral M., Singer W. & Melloni L.
(
2016)
Early effects of previous experience on conscious perception.
Neuroscience of Consciousness 1: 1–10.
Constructive theories of brain function such as predictive coding posit that prior knowledge affects our experience of the world quickly and directly. However, it is yet unknown how swiftly prior knowledge impacts the neural processes giving rise to conscious experience. Here we used an experimental paradigm where prior knowledge augmented perception and measured the timing of this effect with magnetoencephalography (MEG). By correlating the perceptual benefits of prior knowledge with the MEG activity, we found that prior knowledge took effect in the time-window 80–95ms after stimulus onset, thus reflecting an early influence on conscious perception. The sources of this effect were localized to occipital and posterior parietal regions. These results are in line with the predictive coding framework.
Cosmelli D., David O., Lachaux J.-P., Martinerie J., Garnero L., Renault B. & Varela F. J. (2004) Waves of consciousness: Ongoing cortical patterns during binocular rivalry. Neuroimage 23: 128–140. https://cepa.info/7750
Cosmelli D., David O., Lachaux J.-P., Martinerie J., Garnero L., Renault B. & Varela F. J.
(
2004)
Waves of consciousness: Ongoing cortical patterns during binocular rivalry.
Neuroimage 23: 128–140.
Fulltext at https://cepa.info/7750
We present here ongoing patterns of distributed brain synchronous activity that correlate with the spontaneous flow of perceptual dominance during binocular rivalry. Specific modulation of the magnetoencephalographic (MEG) response evoked during conscious perception of a frequency-tagged stimulus was evidenced throughout rivalry. Estimation of the underlying cortical sources revealed, in addition to strong bilateral striate and extrastriate visual cortex activation, parietal, temporal pole and frontal contributions. Cortical activity was significantly modulated concomitantly to perceptual alternations in visual cortex, medial parietal and left frontal regions. Upon dominance, coactivation of occipital and frontal regions, including anterior cingulate and medial frontal areas, was established. This distributed cortical network, as measured by phase synchrony in the frequency tag band, was dynamically modulated in concert with the perceptual dominance of the tagged stimulus. While the anteroposterior pattern was recurrent through subjects, individual variations in the extension of the network were apparent.
Schwartzman D. J., Bor D., Rothen N. & Seth A. K. (2019) Neurophenomenology of induced and natural synaesthesia. Philosophical Transactions of the Royal Society B – Biological Sciences 374: 20190030. https://cepa.info/7755
Schwartzman D. J., Bor D., Rothen N. & Seth A. K.
(
2019)
Neurophenomenology of induced and natural synaesthesia.
Philosophical Transactions of the Royal Society B – Biological Sciences 374: 20190030.
Fulltext at https://cepa.info/7755
People with synaesthesia have additional perceptual experiences, which are automatically and consistently triggered by specific inducing stimuli. Synaesthesia therefore offers a unique window into the neurocognitive mechanisms underlying conscious perception. A long-standing question in synaesthesia research is whether it is possible to artificially induce non-synaesthetic individuals to have synaesthesia-like experiences. Although synaesthesia is widely considered a congenital condition, increasing evidence points to the potential of a variety of approaches to induce synaesthesia-like experiences, even in adulthood. Here, we summarize a range of methods for artificially inducing synaesthesia-like experiences, comparing the resulting experiences to the key hallmarks of natural synaesthesia which include consistency, automaticity and a lack of ‘perceptual presence’. We conclude that a number of aspects of synaesthesia can be artificially induced in non-synaesthetes. These data suggest the involvement of developmental and/or learning components in the acquisition of synaesthesia, and they extend previous reports of perceptual plasticity leading to dramatic changes in perceptual phenomenology in adults.
Export result page as:
·
·
·
·
·
·
·
·