Max-Planck-Institute for Dynamics and Self-Organization, Am Faß berg 17, Göttingen, Germany.
Bernstein-Center for Computational Neuroscience, Göttingen, Germany.
Cereb Cortex. 2019 Jun 1;29(6):2759-2770. doi: 10.1093/cercor/bhz049.
Knowledge about the collective dynamics of cortical spiking is very informative about the underlying coding principles. However, even most basic properties are not known with certainty, because their assessment is hampered by spatial subsampling, i.e., the limitation that only a tiny fraction of all neurons can be recorded simultaneously with millisecond precision. Building on a novel, subsampling-invariant estimator, we fit and carefully validate a minimal model for cortical spike propagation. The model interpolates between two prominent states: asynchronous and critical. We find neither of them in cortical spike recordings across various species, but instead identify a narrow "reverberating" regime. This approach enables us to predict yet unknown properties from very short recordings and for every circuit individually, including responses to minimal perturbations, intrinsic network timescales, and the strength of external input compared to recurrent activation "thereby informing about the underlying coding principles for each circuit, area, state and task.
关于皮质尖峰的集体动力学的知识对于潜在的编码原则非常有启发性。然而,即使是最基本的特性也不能确定,因为它们的评估受到空间抽样的阻碍,即只有一小部分神经元可以同时以毫秒级的精度进行记录。基于一种新颖的、不受抽样影响的估计器,我们拟合并仔细验证了一个用于皮质尖峰传播的最小模型。该模型在两种突出的状态之间进行插值:异步和临界。我们在各种物种的皮质尖峰记录中都没有发现这两种状态,而是发现了一个狭窄的“回荡”状态。这种方法使我们能够从非常短的记录中预测未知的特性,并且可以为每个电路单独预测,包括对最小扰动的响应、内在网络时间尺度以及与递归激活相比的外部输入的强度,从而为每个电路、区域、状态和任务提供潜在的编码原则的信息。