Posterior cortical hot zone

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The term posterior cortical hot zone was coined by Christof Koch and colleagues to describe the part of the neocortex closely associated with the minimal neural substrate essential for conscious perception. [1] The posterior cortical hot zone includes sensory cortical areas in the parietal, temporal, and occipital lobes. It is the “sensory” cortex, much as the frontal cortex is the “action” cortex.

When parts of the posterior cortex are damaged, whole modalities of sensory experience disappear from both waking and dreaming. For example, individuals with a lesion in the Visual area V4 often do not perceive color and dream in black-and-white; those with a lesion in the Visual area V5/MT do not perceive motion and do not dream of motion; subjects with a lesion to fusiform gyrus are impaired in face perception and also do not dream of faces. [2] Compare that to lesions of the cerebellum or frontal cortex that have little effect on sensory experience.

Object encoding in the posterior cortical hot zone

The sensory component (shape, color, texture) of each object stored in memory is physically encoded by neurons of the posterior cortical hot zone in structures called neuronal ensembles (NEs), neuronal assemblies, [3] neural cliques, [4] or cognits. [5] When one recalls any object, the object-encoding neuronal ensemble (objectNE) in the posterior cortical hot zone activates into synchronous resonant activity that results in conscious perception of the object. The objectNE binding mechanism, based on the Hebbian principle “neurons that fire together, wire together,” came to be known as the Binding-by-Synchrony hypothesis. [6]

While the Hebbian principle explains how we perceive a familiar object, it does not explain the infinite number of novel objects that humans can imagine. To account for the limitless constructive imagination, it was proposed that synchronization of independent objectNEs is a general mechanism underlying any novel imaginary experience. [7] When the synchronization of independent objectNEs is driven from the front by the lateral prefrontal cortex, we refer to it as Prefrontal Synthesis; when the synchronization is driven from the back, we refer to it as dreaming or hallucination.

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Prefrontal synthesis is the conscious purposeful process of synthesizing novel mental images. PFS is neurologically different from the other types of imagination, such as simple memory recall and dreaming. Unlike dreaming, which is spontaneous and not controlled by the prefrontal cortex (PFC), PFS is controlled by and completely dependent on the intact lateral prefrontal cortex. Unlike simple memory recall that involves activation of a single neuronal ensemble (NE) encoded at some point in the past, PFS involves active combination of two or more object-encoding neuronal ensembles (objectNE). The mechanism of PFS is hypothesized to involve synchronization of several independent objectNEs. When objectNEs fire out-of-sync, the objects are perceived one at a time. However, once those objectNEs are time-shifted by the lateral PFC to fire in-phase with each other, they are consciously experienced as one unified object or scene.

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Posterior cortex usually means the posterior (back) part of the complete cerebral cortex and includes the occipital, parietal, and temporal cortices. In other words, the posterior cortex includes all the cerebral cortex without the frontal cortex.

References

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  3. Singer, Wolf; Engel, Andreas K.; Kreiter, Andreas K.; Munk, Matthias H.J.; Neuenschwander, Sergio; Roelfsema, Pieter R. (October 1997). "Neuronal assemblies: necessity, signature and detectability". Trends in Cognitive Sciences. 1 (7): 252–261. doi:10.1016/S1364-6613(97)01079-6. PMID   21223920. S2CID   8953173.
  4. Lin, Longnian; Osan, Remus; Tsien, Joe Z. (January 2006). "Organizing principles of real-time memory encoding: neural clique assemblies and universal neural codes". Trends in Neurosciences. 29 (1): 48–57. doi:10.1016/j.tins.2005.11.004. PMID   16325278. S2CID   53177323.
  5. Fuster, Joaquín M. (May 2006). "The cognit: A network model of cortical representation". International Journal of Psychophysiology. 60 (2): 125–132. doi:10.1016/j.ijpsycho.2005.12.015. PMID   16626831.
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  7. Vyshedskiy, Andrey; Dunn, Rita; Piryatinsky, Irene (18 April 2017). "Neurobiological mechanisms for nonverbal IQ tests: implications for instruction of nonverbal children with autism". Research Ideas and Outcomes. 3: e13239. doi: 10.3897/rio.3.e13239 .
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