Abstract
Neuronal firing in the hippocampal formation relative to the phase of local field potentials (LFP) has a key role in memory processing and spatial navigation. Firing can be in either tonic or burst mode. Although bursting neurons are common in the hippocampal formation, the characteristics of their locking to LFP phase are not completely understood. We investigated phase-locking properties of bursting neurons using simulations generated by a dual compartmental model of a pyramidal neuron adapted to match the bursting activity in the subiculum of a rat. The model was driven with stochastic input signals containing a power spectral profile consistent with physiologically relevant frequencies observed in LFP. The single spikes and spike bursts fired by the model were locked to a preferred phase of the predominant frequency band where there was a peak in the power of the driving signal. Moreover, the preferred phase of locking shifted with increasing burst size, providing evidence that LFP phase can be encoded by burst size. We also provide initial support for the model results by analysing example data of spontaneous LFP and spiking activity recorded from the subiculum of a single urethane-anaesthetised rat. Subicular neurons fired single spikes, two-spike bursts and larger bursts that locked to a preferred phase of either dominant slow oscillations or theta rhythms within the LFP, according to the model prediction. Both power-modulated phase-locking and gradual shift in the preferred phase of locking as a function of burst size suggest that neurons can use bursts to encode timing information contained in LFP phase into a spike-count code.
Highlights
Local field potentials (LFP) are fluctuating extracellular electrical signals that result from the sum of currents across all excitable membranes within a local volume (Logothetis, 2003; Buzsaki et al, 2012)
Out of a total of 26 units identified in the rat subiculum, we identified 13 bursting units firing at a rate of 1.96 ± 1.00 events/s in epochs when slow oscillations were dominant in the LFP
These were slow oscillations which are characteristic of slow-wave sleep or non-REM sleep (Wolansky et al, 2006; Clement et al, 2008) and theta rhythms which are present in the hippocampus during REM sleep (Harris et al, 2002) as well as during exploratory behaviour (O’Keefe and Recce, 1993; Skaggs et al, 1996), under urethane anaesthesia the theta peak at 4 Hz is lower than the theta peak at 7 Hz during REM sleep (Clement et al, 2008)
Summary
Local field potentials (LFP) are fluctuating extracellular electrical signals that result from the sum of currents across all excitable membranes within a local volume (Logothetis, 2003; Buzsaki et al, 2012). Neuronal firing relative to the phase of ongoing LFP oscillations in the hippocampal formation has been linked with spatial navigation (O’Keefe and Recce, 1993; Skaggs et al, 1996) and memory processing (Lisman and Idiart, 1995). Evidence from the monkey sensory cortices suggests that more information about stimuli can be transmitted if the LFP phase at which spikes are fired is taken into account (Montemurro et al, 2008; Kayser et al, 2009). Locking of neuronal firing during a preferred phase range can be a mechanism of transmitting information for cognitive processing. Pyramidal neurons in the hippocampal formation are known to lock their firing to LFP phase, the conditions of this phase-locking are not completely understood
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
