School of Biological Sciences, Whiteknights, University of Reading, Reading, UK.
Centre for Integrative Neuroscience and Neurodynamics (CINN), University of Reading, Reading, UK.
J Physiol. 2024 Feb;602(4):713-736. doi: 10.1113/JP284587. Epub 2024 Jan 31.
In the resting state, cortical neurons can fire action potentials spontaneously but synchronously (Up state), followed by a quiescent period (Down state) before the cycle repeats. Extracellular recordings in the infragranular layer of cortex with a micro-electrode display a negative deflection (depth-negative) during Up states and a positive deflection (depth-positive) during Down states. The resulting slow wave oscillation (SWO) has been studied extensively during sleep and under anaesthesia. However, recent research on the balanced nature of synaptic excitation and inhibition has highlighted our limited understanding of its genesis. Specifically, are excitation and inhibition balanced during SWOs? We analyse spontaneous local field potentials (LFPs) during SWOs recorded from anaesthetised rats via a multi-channel laminar micro-electrode and show that the Down state consists of two distinct synaptic states: a Dynamic Down state associated with depth-positive LFPs and a prominent dipole in the extracellular field, and a Static Down state with negligible ( ) LFPs and a lack of dipoles extracellularly. We demonstrate that depth-negative and -positive LFPs are generated by a shift in the balance of synaptic excitation and inhibition from excitation dominance (depth-negative) to inhibition dominance (depth-positive) in the infragranular layer neurons. Thus, although excitation and inhibition co-tune overall, differences in their timing lead to an alternation of dominance, manifesting as SWOs. We further show that Up state initiation is significantly faster if the preceding Down state is dynamic rather than static. Our findings provide a coherent picture of the dependence of SWOs on synaptic activity. KEY POINTS: Cortical neurons can exhibit repeated cycles of spontaneous activity interleaved with periods of relative silence, a phenomenon known as 'slow wave oscillation' (SWO). During SWOs, recordings of local field potentials (LFPs) in the neocortex show depth-negative deflection during the active period (Up state) and depth-positive deflection during the silent period (Down state). Here we further classified the Down state into a dynamic phase and a static phase based on a novel method of classification and revealed non-random, stereotypical sequences of the three states occurring with significantly different transitional kinetics. Our results suggest that the positive and negative deflections in the LFP reflect the shift of the instantaneous balance between excitatory and inhibitory synaptic activity of the local cortical neurons. The differences in transitional kinetics may imply distinct synaptic mechanisms for Up state initiation. The study may provide a new approach for investigating spontaneous brain rhythms.
在静息状态下,皮质神经元可以自发但同步地发射动作电位(上状态),然后在循环重复之前进入静止期(下状态)。用微电极在皮层下颗粒层进行的细胞外记录显示,在上状态期间出现负偏移(深度负),在下状态期间出现正偏移(深度正)。这种慢波振荡(SWO)在睡眠和麻醉期间已经得到了广泛的研究。然而,最近关于突触兴奋和抑制的平衡性质的研究突出表明,我们对其产生的理解有限。具体来说,在 SWO 期间,兴奋和抑制是否平衡?我们通过多通道层状微电极分析麻醉大鼠记录的 SWO 期间的自发局部场电位(LFPs),并表明下状态由两个不同的突触状态组成:与深度正 LFPs 和细胞外场中的明显偶极子相关联的动态下状态,以及具有可忽略的()LFPs 和细胞外无偶极子的静态下状态。我们证明,深度负和正 LFPs 是由下颗粒层神经元中突触兴奋和抑制的平衡从兴奋优势(深度负)转变为抑制优势(深度正)引起的。因此,尽管兴奋和抑制共同调节整体,但它们的时间差异导致优势的交替,表现为 SWO。我们进一步表明,如果前一个下状态是动态的而不是静态的,那么上状态的起始速度会显著加快。我们的研究结果提供了一个连贯的画面,说明了 SWO 对突触活动的依赖性。关键点:皮质神经元可以表现出反复的自发活动循环,其间穿插着相对静止的时期,这种现象称为“慢波振荡”(SWO)。在 SWO 期间,记录新皮层的局部场电位(LFPs)显示,在活跃期(上状态)期间出现深度负向偏转,在静止期(下状态)期间出现深度正向偏转。在这里,我们根据一种新的分类方法进一步将下状态分为动态相和静态相,并揭示了具有显著不同过渡动力学的三种状态的非随机、刻板序列的发生。我们的结果表明,LFP 中的正负偏移反映了局部皮质神经元的兴奋性和抑制性突触活动的瞬时平衡的变化。过渡动力学的差异可能暗示了上状态起始的不同突触机制。该研究可能为研究自发脑节律提供一种新方法。
