Neuroscience Institute and Departments of Psychology and Ecology and Evolutionary Biology, Princeton University, Princeton, New Jersey 08540, USA.
J Neurosci. 2010 Oct 20;30(42):13919-31. doi: 10.1523/JNEUROSCI.3174-10.2010.
The efficient cortical encoding of natural scenes is essential for guiding adaptive behavior. Because natural scenes and network activity in cortical circuits share similar temporal scales, it is necessary to understand how the temporal structure of natural scenes influences network dynamics in cortical circuits and spiking output. We examined the relationship between the structure of natural acoustic scenes and its impact on network activity [as indexed by local field potentials (LFPs)] and spiking responses in macaque primary auditory cortex. Natural auditory scenes led to a change in the power of the LFP in the 2-9 and 16-30 Hz frequency ranges relative to the ongoing activity. In contrast, ongoing rhythmic activity in the 9-16 Hz range was essentially unaffected by the natural scene. Phase coherence analysis showed that scene-related changes in LFP power were at least partially attributable to the locking of the LFP and spiking activity to the temporal structure in the scene, with locking extending up to 25 Hz for some scenes and cortical sites. Consistent with distributed place and temporal coding schemes, a key predictor of phase locking and power changes was the overlap between the spectral selectivity of a cortical site and the spectral structure of the scene. Finally, during the processing of natural acoustic scenes, spikes were locked to LFP phase at frequencies up to 30 Hz. These results are consistent with an idea that the cortical representation of natural scenes emerges from an interaction between network activity and stimulus dynamics.
自然场景的高效皮层编码对于指导适应性行为至关重要。由于自然场景和皮层电路中的网络活动具有相似的时间尺度,因此有必要了解自然场景的时间结构如何影响皮层电路中的网络动态和尖峰输出。我们研究了自然声场景的结构与其对灵长类动物初级听觉皮层中的网络活动(以局部场电位 (LFP) 为指标)和尖峰反应的影响之间的关系。自然听觉场景导致 LFP 在 2-9 和 16-30 Hz 频率范围内的功率相对于持续活动发生变化。相比之下,9-16 Hz 范围内的持续有节奏活动基本上不受自然场景的影响。相位相干性分析表明,LFP 功率与场景相关的变化至少部分归因于 LFP 和尖峰活动与场景中的时间结构的锁定,对于某些场景和皮层位点,锁定可扩展至 25 Hz。与分布式位置和时间编码方案一致,相位锁定和功率变化的一个关键预测因子是皮质位点的频谱选择性与场景的频谱结构之间的重叠。最后,在处理自然声场景时,尖峰被锁定在 LFP 相位上,频率高达 30 Hz。这些结果与这样一种观点一致,即自然场景的皮层表示源自网络活动和刺激动态之间的相互作用。