Abstract
A major stumbling block to cracking the real-time neural code is neuronal variability - neurons discharge spikes with enormous variability not only across trials within the same experiments but also in resting states. Such variability is widely regarded as a noise which is often deliberately averaged out during data analyses. In contrast to such a dogma, we put forth the Neural Self-Information Theory that neural coding is operated based on the self-information principle under which variability in the time durations of inter-spike-intervals (ISI), or neuronal silence durations, is self-tagged with discrete information. As the self-information processor, each ISI carries a certain amount of information based on its variability-probability distribution; higher-probability ISIs which reflect the balanced excitation-inhibition ground state convey minimal information, whereas lower-probability ISIs which signify rare-occurrence surprisals in the form of extremely transient or prolonged silence carry most information. These variable silence durations are naturally coupled with intracellular biochemical cascades, energy equilibrium and dynamic regulation of protein and gene expression levels. As such, this silence variability-based self-information code is completely intrinsic to the neurons themselves, with no need for outside observers to set any reference point as typically used in the rate code, population code and temporal code models. Moreover, temporally coordinated ISI surprisals across cell population can inherently give rise to robust real-time cell-assembly codes which can be readily sensed by the downstream neural clique assemblies. One immediate utility of this self-information code is a general decoding strategy to uncover a variety of cell-assembly patterns underlying external and internal categorical or continuous variables in an unbiased manner.
Highlights
Reviewed by: Bailu Si, University of Chinese Academy of Sciences (UCAS), China Ju Lu, University of California, Santa Cruz, United States
Two hard problems lie at the heart of brain decoding research; namely, what is the basic wiring logic of the brain? And what is the basic operational rule for representing real-time information? With 86 billion neurons and 100 trillion synaptic connections in the human brain, it is conceivable that the understanding of the brain’s basic wiring logic is the foundation upon which dynamic coding of cognitive information can be meaningfully executed (Hebb, 1949; Brenner and Sejnowski, 2011; Tsien, 2015a,b)
Self-Information Based Neural Code framework under which neurons connect or organize themselves, merely reading out neural signals corresponding to external stimulus identity is very much like a fictional biologist who may discern a foreign message from a radio yet has no idea about how radios work
Summary
Reviewed by: Bailu Si, University of Chinese Academy of Sciences (UCAS), China Ju Lu, University of California, Santa Cruz, United States. This silence variability-based self-information code is completely intrinsic to the neurons themselves, with no need for outside observers to set any reference point as typically used in the rate code, population code and temporal code models.
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