Specifically, 80% of the variance was explained by the first 22 PCs for monkey M and the first 32 PCs for monkey B), while the first 77 PCs would be necessary to explain 80% of the variance with uniformly distributed eigenvalues. Thus, there was considerable structure in the spontaneous activity. Inspection of the PCs demonstrated a notable correspondence between several of the PCs computed using spontaneous activity and the CF map of
pure-tone responses (compare, for example, Figure 6B and Figure 3A). Therefore, we statistically evaluated whether each PC was correlated with either or both of the two variables that characterize each site, i.e., the CF and the area label (i.e., Sector 1, 2, 3, 4; see Experimental Procedures). We found that both monkeys had multiple PCs with significant (p < 0.05/96) main effects for the CF and/or the area label (Table S2). Interestingly, the PCs that were
significantly correlated with the features of the Selleck AT13387 map also explained the most variance in the spontaneous activity. Specifically, the first PCs in both monkeys were significantly correlated with the area label. In addition, for each monkey, the highest order PC that correlated with the CF map also ranked highly (second PC for monkey M, fourth PC for monkey B). By examining the PCs spatially, one can readily see that the first PCs resembled our stimulation-based estimation of the different auditory areas (Figure 6A). The other PCs closely resembled the CF maps themselves (Figure 6B). We also confirmed the relationship between the CF values and these PCs by calculating the correlation BMS-354825 in vitro coefficients between them for both monkeys: r = 0.5243 (p < 0.00001) for monkey M;
r = 0.3858 (p = 0.0023) for monkey B (Figure 6C). In this study, we chronically implanted μECoG arrays to record field potentials in intrasulcal auditory cortex of awake macaques. Based upon the responses to pure tone stimuli, and consistent with previous electrophysiological and fMRI studies, we first identified multiple, mirror symmetric tonotopic maps on the supratemporal plane (STP) using the high-gamma band of the evoked field potentials. We then demonstrated that, in the absence of stimulation, spontaneous activity Oxalosuccinic acid on the STP was spatiotemporally coordinated in a way that reflected two functional organizations of the auditory cortex: the characteristic frequency (CF) maps and the sectors delineated by the putative areal boundaries from the CF maps. In the next sections, we discuss each of these aspects of the study in turn, and speculate on the significance of the emergent spontaneous activity patterns. As in humans, the core and belt areas of the auditory cortex of the macaque monkey are embedded in the lateral sulcus on the STP, with additional auditory areas located along the lateral bank of the circular sulcus and on the superior temporal gyrus (Bolhuis et al., 2010 and Hackett, 2011).