Effect of amplitude correlations on coherence in the local field potential

Abstract: Neural activity across the brain shows both spatial and temporal correlations at multiple scales, and understanding these correlations is a key step toward understanding cortical processing. Correlation in the local field potential (LFP) recorded from two brain areas is often characterized by computing the coherence, which is generally taken to reflect the degree of phase consistency across trials between two sites. Coherence, however, depends on two factors—phase consistency as well as amplitude covariation a… Show more

“…1). Other studies from the same dataset have been reported previously (Ray and Maunsell 2010, 2011a, b; Srinath and Ray 2014). …”

“…We recorded spike and LFP signals from two male rhesus monkeys using a 10 × 10 array (Blackrock Microsystems) implanted in the V1, while they attended to a Gabor stimulus presented in the opposite hemifield of the RFs of the recorded sites and performed an orientation-change detection task [same task as used in previous studies: Ray and Maunsell (2010, 2011a); Srinath and Ray (2014); see materials and methods for details]. To estimate the spatial spread, we first estimated the RF sizes by flashing a small Gabor stimulus in a random sequence at 81 ( Monkey 1 , 9 × 9 rectangular grid spanning 2 × 2° of visual space) or 121 ( Monkey 2 , 11 × 11 grid spanning 3 × 3° of visual space) locations spanning all of the RFs.…”

“…In the primary visual cortex (V1), the correlation in the network (as measured indirectly using field-field or spike-field coherence) during spontaneous activity, as well as the change in correlation upon stimulus presentation, is frequency dependent, with a greater change in correlation in alpha (8–12 Hz), gamma (30–60 Hz), and high-gamma (60–150 Hz) bands (Jia et al 2013a; Srinath and Ray 2014). However, whether the spatial spread is frequency dependent in V1 in a manner that depends on the correlation profile has not been studied in detail.…”

Spatial spread of local field potential is band-pass in the primary visual cortex

“…1). Other studies from the same dataset have been reported previously (Ray and Maunsell 2010, 2011a, b; Srinath and Ray 2014). …”

“…We recorded spike and LFP signals from two male rhesus monkeys using a 10 × 10 array (Blackrock Microsystems) implanted in the V1, while they attended to a Gabor stimulus presented in the opposite hemifield of the RFs of the recorded sites and performed an orientation-change detection task [same task as used in previous studies: Ray and Maunsell (2010, 2011a); Srinath and Ray (2014); see materials and methods for details]. To estimate the spatial spread, we first estimated the RF sizes by flashing a small Gabor stimulus in a random sequence at 81 ( Monkey 1 , 9 × 9 rectangular grid spanning 2 × 2° of visual space) or 121 ( Monkey 2 , 11 × 11 grid spanning 3 × 3° of visual space) locations spanning all of the RFs.…”

“…In the primary visual cortex (V1), the correlation in the network (as measured indirectly using field-field or spike-field coherence) during spontaneous activity, as well as the change in correlation upon stimulus presentation, is frequency dependent, with a greater change in correlation in alpha (8–12 Hz), gamma (30–60 Hz), and high-gamma (60–150 Hz) bands (Jia et al 2013a; Srinath and Ray 2014). However, whether the spatial spread is frequency dependent in V1 in a manner that depends on the correlation profile has not been studied in detail.…”

Spatial spread of local field potential is band-pass in the primary visual cortex

“…While principal cells in the superficial layers of neocortex are more electrotonically compact (Zador et al, 1995), which could perhaps enable cortical circuits to more effectively employ gamma synchronization as a mechanism for selective interregional communication (Singer, 1993; Fries, 2005), this hypothesis remains hotly debated (Shadlen and Movshon, 1999; Kopell et al, 2000; Fries, 2009; Ray and Maunsell, 2010; Fell and Axmacher, 2011; Bosman et al, 2012; Akam and Kullmann, 2012; Jia et al, 2013; Srinath and Ray, 2014). In our analysis, LFP-spike coupling between CA1 units and CA3 or EC3 LFP was mostly attributable to phase-locking of interneurons (Figure 6).…”

Theta Phase Segregation of Input-Specific Gamma Patterns in Entorhinal-Hippocampal Networks

“…Another spurious source of gamma coherence is amplitude covariations between signals in the same frequency band 65 . Given that power increases at gamma frequencies can also be brought about by both spiking activity and nonoscillatory transient events 66 , this is another artificial source of increased gamma coherence.…”

What does gamma coherence tell us about inter-regional neural communication?