Self-organized Cell Assembly Sequences in the Hippocampus

SUMMARYCell assembly is a hypothetical functional unit of information processing in the brain. While technologies for recording large-scale neural activity have been advanced, mathematical methods to analyze sequential activity patterns of cell-assembly are severely limited. Here, we propose a method to extract cell-assembly sequences repeated at multiple time scales and various precisions from irregular neural population activity. The key technology is to combine “edit similarity” in computer science with machine-learning clustering algorithms, where the former defines a “distance” between two strings as the minimal number of operations required to transform one string to the other. Our method requires no external references for pattern detection, and is tolerant of spike timing jitters and length irregularity in assembly sequences. These virtues enabled simultaneous automatic detections of hippocampal place-cell sequences during locomotion and their time-compressed replays during resting states. Furthermore, our method revealed previously undetected cell-assembly structure in the rat prefrontal cortex during goal-directed behavior. Thus, our method expands the horizon of cell-assembly analysis.

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Cell Assembly Sequences Arising from Spike Threshold Adaptation Keep Track of Time in the Hippocampus

Journal of Neuroscience ◽

10.1523/jneurosci.3773-10.2011 ◽

2011 ◽

Vol 31 (8) ◽

pp. 2828-2834 ◽

Cited By ~ 73

Author(s):

V. Itskov ◽

C. Curto ◽

E. Pastalkova ◽

G. Buzsaki

Keyword(s):

Cell Assembly ◽

Spike Threshold ◽

Assembly Sequences

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Internally Organized Cell Assembly Trajectories

The Brain from Inside Out ◽

10.1093/oso/9780190905385.003.0007 ◽

2019 ◽

pp. 165-198

Author(s):

György Buzsáki

Keyword(s):

Neuronal Activity ◽

Initial Conditions ◽

Cell Assembly ◽

Self Organized ◽

Brain Circuits ◽

Default State ◽

Neuronal Patterns ◽

State Of Affairs ◽

Transfer Of Information ◽

Enormous Number

Sequences of neuronal patterns are not always imposed on brain circuits in an outside-in manner by the sensory inputs. Internally organized processes can sustain self-organized and coordinated neuronal activity even without external inputs. A prerequisite of cognition is the availability of internally generated neuronal sentences. Self-generated, sequentially evolving activity is the default state of affairs in most neuronal circuits. Neuronal activity moves perpetually, and its trajectory depends only on initial conditions. Large recurrent networks can generate an enormous number of trajectories without prior experience. On the other hand, each is available to be matched by experience to “represent” something useful for the downstream reader mechanisms. The richness of the information depends not on the numbers of generated sequences but on the reader mechanisms. It is typically the reader structure that initiates the transfer of information, coordinating the onset of messages from multiple senders.

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Self-organized cell assembly formation

BMC Neuroscience ◽

10.1186/1471-2202-15-s1-p30 ◽

2014 ◽

Vol 15 (S1) ◽

Author(s):

Timo Nachstedt ◽

Florentin Wörgötter ◽

Christian Tetzlaff

Keyword(s):

Cell Assembly ◽

Self Organized

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Hippocampus: Network Physiology

Handbook of Brain Microcircuits ◽

10.1093/med/9780190636111.003.0018 ◽

2017 ◽

pp. 217-226

Author(s):

György Buzsáki ◽

Antonio Fernández-Ruiz

Keyword(s):

Temporal Integration ◽

Layer Transfer ◽

Require Time ◽

Oscillatory Dynamics ◽

Self Organized ◽

Assembly Sequences ◽

Theta Phase ◽

Iterative Integration ◽

Transfer Of Information ◽

High Frequency Oscillatory

Information in the entorhinal-hippocampal system is transferred through alternating layers of recurrent excitatory and largely parallel-organized networks, allowing the iterative integration and segregation of messages. Local computations require time, and the speed of layer-to-layer transfer of information is largely determined by the dynamics of network oscillations. Temporal integration within coherent theta oscillation sets constraints on the resolution of both spatial and nonspatial information. Theta and high-frequency oscillatory dynamics can generate self-organized assembly sequences that reflect a compressed version of experienced firing patterns during exploration and learning. The strength and theta phase preference of upstream drivers cooperate with local circuit mechanisms in controlling the timing of spikes in hippocampal circuits in the service of memory and spatial navigation.

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