Department of Neurobiology & Howard Hughes Medical Institute, Harvard Medical School, Boston, Massachusetts, United States of America.
PLoS Biol. 2011 Apr;9(4):e1000610. doi: 10.1371/journal.pbio.1000610. Epub 2011 Apr 12.
During cognitive tasks electrical activity in the brain shows changes in power in specific frequency ranges, such as the alpha (8-12 Hz) or gamma (30-80 Hz) bands, as well as in a broad range above ∼80 Hz, called the high-gamma band. The role or significance of this broadband high-gamma activity is unclear. One hypothesis states that high-gamma oscillations serve just like gamma oscillations, operating at a higher frequency and consequently at a faster timescale. Another hypothesis states that high-gamma power is related to spiking activity. Because gamma power and spiking activity tend to co-vary during most stimulus manipulations (such as contrast modulations) or cognitive tasks (such as attentional modulation), it is difficult to dissociate these two hypotheses. We studied the relationship between high-gamma power, gamma rhythm, and spiking activity in the primary visual cortex (V1) of awake monkeys while varying the stimulus size, which increased the gamma power but decreased the firing rate, permitting a dissociation. We found that gamma power became anti-correlated with the high-gamma power, suggesting that the two phenomena are distinct and have different origins. On the other hand, high-gamma power remained tightly correlated with spiking activity under a wide range of stimulus manipulations. We studied this relationship using a signal processing technique called Matching Pursuit and found that action potentials are associated with sharp transients in the LFP with broadband power, which is visible at frequencies as low as ∼50 Hz. These results distinguish broadband high-gamma activity from gamma rhythms as an easily obtained and reliable electrophysiological index of neuronal firing near the microelectrode. Further, they highlight the importance of making a careful dissociation between gamma rhythms and spike-related transients that could be incorrectly decomposed as rhythms using traditional signal processing methods.
在认知任务中,大脑的电活动会显示特定频率范围内的功率变化,例如α(8-12 Hz)或γ(30-80 Hz)频段,以及约 80 Hz 以上的宽频带,称为高γ频段。这种宽带高γ活动的作用或意义尚不清楚。一种假设认为,高γ振荡与γ振荡一样,以更高的频率运行,因此在更快的时间尺度上运行。另一种假设认为,高γ功率与尖峰活动有关。由于在大多数刺激操作(例如对比度调制)或认知任务(例如注意力调制)期间,γ功率和尖峰活动往往会共同变化,因此很难将这两种假设分开。我们研究了在刺激大小变化时,清醒猴子的初级视觉皮层(V1)中高γ功率、γ节律和尖峰活动之间的关系,这增加了γ功率但降低了放电率,从而可以将它们分开。我们发现,γ功率与高γ功率呈负相关,这表明这两种现象是不同的,具有不同的起源。另一方面,在广泛的刺激操作下,高γ功率仍然与尖峰活动紧密相关。我们使用一种称为匹配追踪的信号处理技术研究了这种关系,发现动作电位与具有宽带功率的 LFP 中的尖锐瞬态相关,其在低至约 50 Hz 的频率下可见。这些结果将宽带高γ活动与γ节律区分开来,作为接近微电极的神经元放电的一种容易获得且可靠的电生理指标。此外,它们强调了仔细区分γ节律和与尖峰相关的瞬态的重要性,这些瞬态可能会被传统的信号处理方法错误地分解为节律。
