Ana Maria Ichim, Harald Barzan, Vasile Vlad Moca, Adriana Nagy-Dabacan, Andrei Ciuparu, Adela Hapca, Koen Vervaeke, Raul Cristian Muresan
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引用次数: 0
摘要
对大脑活动中伽马振荡(30-150 赫兹)的研究已有 80 多年的历史。尽管在过去的三十年里,人们在试图理解伽马振荡的功能作用方面取得了重大进展,但关于伽马振荡在感知、认知和行为中的因果关系,我们仍未得到明确的答案。在这里,我们首先回顾了产生伽马振荡的基本神经机制,然后重点探讨两大支柱。第一部分探讨了有关伽马振荡在大脑信息处理过程中的功能作用的主要理论,并强调了一些重要观点。第二部分回顾了提出伽马振荡治疗作用的新研究方向,即使用感官刺激的伽马诱导(GENUS)。我们广泛讨论了GENUS的积极发现和可重复性问题。除了伽马振荡的功能和治疗作用之外,我们还提出了第三个探索方向,即由大脑皮层回路内生的伽马振荡对于维持健康的回路功能至关重要。我们提出,四类中间神经元,即那些表达副阀素(PV)、血管收缩肽(VIP)、体生长抑素(SST)和一氧化氮合酶(NOS)的中间神经元,利用内源性伽马来执行主动的血管运动控制,从而维持神经元组织的平衡。根据我们称之为 GAMER(GAmma MEdiated ciRcuit maintenance)的这一假说,γ 振荡作为一种 "服务 "节律,能够将神经活动有效地转化为血管反应,而血管反应对于优化神经代谢过程至关重要。GAMER 是 GENUS 的延伸,在 GENUS 中,内源性伽马振荡而不是夹带伽马振荡起着根本性的作用。最后,我们提出了几个关键实验来验证伽马假说。
Gamma oscillations in brain activity (30-150 Hz) have been studied for over 80 years. Although in the past three decades significant progress has been made to try to understand their functional role, a definitive answer regarding their causal implication in perception, cognition, and behavior still lies ahead of us. Here, we first review the basic neural mechanisms that give rise to gamma oscillations and then focus on two main pillars of exploration. The first pillar examines the major theories regarding their functional role in information processing in the brain, also highlighting critical viewpoints. The second pillar reviews a novel research direction that proposes a therapeutic role for gamma oscillations, namely the gamma entrainment using sensory stimulation (GENUS). We extensively discuss both the positive findings and the issues regarding reproducibility of GENUS. Going beyond the functional and therapeutic role of gamma, we propose a third pillar of exploration, where gamma, generated endogenously by cortical circuits, is essential for maintenance of healthy circuit function. We propose that four classes of interneurons, namely those expressing parvalbumin (PV), vasointestinal peptide (VIP), somatostatin (SST), and nitric oxide synthase (NOS) take advantage of endogenous gamma to perform active vasomotor control that maintains homeostasis in the neuronal tissue. According to this hypothesis, which we call GAMER (GAmma MEdiated ciRcuit maintenance), gamma oscillations act as a 'servicing' rhythm that enables efficient translation of neural activity into vascular responses that are essential for optimal neurometabolic processes. GAMER is an extension of GENUS, where endogenous rather than entrained gamma plays a fundamental role. Finally, we propose several critical experiments to test the GAMER hypothesis.
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