The oscillating mystery: The effects of forty-hertz entrainment in treating Alzheimer's disease

Brain-X Pub Date : 2023-05-30 DOI:10.1002/brx2.14
Chuanliang Han
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This improvement is attributed to the reduction of accumulated amyloid-β (Aβ) proteins and the enhancement of microglial function, both of which are associated with the disease. However, these findings have been challenged by recent research<span><sup>2</sup></span> conducted by Prof. Buzsáki and published in <i>Nature Neuroscience</i>. In this study, the research team utilized two AD mouse models, specifically APP/PS1 and 5xFAD, to explore the effects of both acute and chronic 40-Hz light stimulation on Aβ, microglia, and gamma oscillations. Firstly, they discovered that 40-Hz light stimulation had no effect on the level of Aβ deposition or the morphology of microglia, whether tested in vitro or in vivo. Subsequently, they demonstrated that the entrainment does not activate native gamma oscillations in the targeted brain regions (visual cortex, hippocampus, and entorhinal cortex). Furthermore, they observed that 40-Hz light stimulation induced aversion and avoidance behavior in mice. This was evident from the duration the mice spent in the compartment with 40-Hz light compared to the one with continuous light. Given the absence of experiments assessing cognitive functions before and after 40-Hz entrainment, the observed inconsistencies in pathological changes in AD following acute or chronic exposure should be considered with caution. For example, the inability to replicate the beneficial effects of flickering light stimulation on Aβ and microglia may be attributed to variations in the experimental parameters. Although both animal models and human subjects have shown improvements in cognitive functions (such as memory) after 40-Hz entrainment, the underlying mechanisms driving these changes remain elusive. Nevertheless, this study successfully eliminated one potential mechanism for reducing AD symptoms—namely, the entrainment of natural gamma-band oscillations. The search for alternative mechanisms continues.</p><p>Given the notable behavioral improvement resulting from 40-Hz stimulation, it is indisputable that the underlying mechanism must have a significant association with gamma-band activity (30–100 Hz). The broad frequency band comprises multiple sub-gamma oscillations, each playing distinct roles. Another study<span><sup>3</sup></span> from Prof. Buzsáki's laboratory provides direct evidence of the role of distinct gamma rhythms in cognitive function, specifically focusing on learning. During the spatial learning process, high-frequency gamma oscillations were found to synchronize the medial entorhinal cortex (MEC) and dentate gyrus (DG), thereby entraining the granule cells. Conversely, low-frequency gamma oscillations were observed to synchronize the lateral entorhinal cortex (LEC) and DG while engaging in object learning. Another study published in the same year<span><sup>4</sup></span> reinforced the theory of multiple gamma oscillations, each playing distinct roles. However, this time, the research focused on the visual system—specifically the primary visual cortex (V1) and LGN—rather than the limbic system. These distinct gamma oscillations appear capable of simultaneously carrying different spatial frequency information, demonstrating the phenomenon of multiplexing in the brain. The hypothesis of multiple gamma rhythms could potentially offer future insights into entrainment stimulation (Figure 1). 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Abstract

Imagine standing at crossroads unable to find your way home or gazing into the eyes of your loved one without remembering their name. For some, this is not merely imagination but the reality of Alzheimer's disease (AD). AD is a neurodegenerative disease that predominantly affects the elderly and stands as the leading cause of dementia. However, its etiology and pathogenesis remain poorly understood. One hallmark of AD is the accumulation of abnormal proteins in the brain, including amyloid-beta (Aβ) and tau. These proteins can disrupt the normal functioning of neurons and lead to their eventual death.

Since 2016, a series of studies1 have demonstrated that 40-Hz stimulation effectively improves the cognitive abilities of AD model mice. This improvement is attributed to the reduction of accumulated amyloid-β (Aβ) proteins and the enhancement of microglial function, both of which are associated with the disease. However, these findings have been challenged by recent research2 conducted by Prof. Buzsáki and published in Nature Neuroscience. In this study, the research team utilized two AD mouse models, specifically APP/PS1 and 5xFAD, to explore the effects of both acute and chronic 40-Hz light stimulation on Aβ, microglia, and gamma oscillations. Firstly, they discovered that 40-Hz light stimulation had no effect on the level of Aβ deposition or the morphology of microglia, whether tested in vitro or in vivo. Subsequently, they demonstrated that the entrainment does not activate native gamma oscillations in the targeted brain regions (visual cortex, hippocampus, and entorhinal cortex). Furthermore, they observed that 40-Hz light stimulation induced aversion and avoidance behavior in mice. This was evident from the duration the mice spent in the compartment with 40-Hz light compared to the one with continuous light. Given the absence of experiments assessing cognitive functions before and after 40-Hz entrainment, the observed inconsistencies in pathological changes in AD following acute or chronic exposure should be considered with caution. For example, the inability to replicate the beneficial effects of flickering light stimulation on Aβ and microglia may be attributed to variations in the experimental parameters. Although both animal models and human subjects have shown improvements in cognitive functions (such as memory) after 40-Hz entrainment, the underlying mechanisms driving these changes remain elusive. Nevertheless, this study successfully eliminated one potential mechanism for reducing AD symptoms—namely, the entrainment of natural gamma-band oscillations. The search for alternative mechanisms continues.

Given the notable behavioral improvement resulting from 40-Hz stimulation, it is indisputable that the underlying mechanism must have a significant association with gamma-band activity (30–100 Hz). The broad frequency band comprises multiple sub-gamma oscillations, each playing distinct roles. Another study3 from Prof. Buzsáki's laboratory provides direct evidence of the role of distinct gamma rhythms in cognitive function, specifically focusing on learning. During the spatial learning process, high-frequency gamma oscillations were found to synchronize the medial entorhinal cortex (MEC) and dentate gyrus (DG), thereby entraining the granule cells. Conversely, low-frequency gamma oscillations were observed to synchronize the lateral entorhinal cortex (LEC) and DG while engaging in object learning. Another study published in the same year4 reinforced the theory of multiple gamma oscillations, each playing distinct roles. However, this time, the research focused on the visual system—specifically the primary visual cortex (V1) and LGN—rather than the limbic system. These distinct gamma oscillations appear capable of simultaneously carrying different spatial frequency information, demonstrating the phenomenon of multiplexing in the brain. The hypothesis of multiple gamma rhythms could potentially offer future insights into entrainment stimulation (Figure 1). While gamma oscillations may not provide a fundamental cure for Alzheimer's disease, they do appear to help preserve memory function.5 Additional research is necessary to identify the optimal target for inducing internal gamma waves that can traverse the entire brain.

Further research addressing the neural mechanisms of 40-Hz entrainment in AD treatment is essential given the multitude of unresolved questions. One significant question is whether various types and processes of AD would benefit equally from the same entrainment method. There is also uncertainty about how different experimental conditions, including the use of varied experimental equipment and light types, could influence the dispute. Furthermore, the potential side effects of 40-Hz stimulation, such as the risk of inducing epilepsy, are still not clearly understood.

In summary, despite the current disagreement surrounding the use of entrainment, efforts to understand the underlying mechanisms continue. Just as new species emerge at the boundaries of diverse ecosystems, novel scientific insights arise at the intersections of various disciplines. We must possess keen discernment to recognize these emerging opportunities and be prepared to persuade others of their potential.

Chuanliang Han: Conceptualization; Funding Acquisition; Writing – original draft; Writing – review & editing.

The author declares no conflicts of interest.

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振荡之谜:40赫兹夹带在治疗阿尔茨海默病中的作用
想象一下,站在十字路口找不到回家的路,或者凝视着你所爱的人的眼睛却不记得他们的名字。对一些人来说,这不仅仅是想象,而是阿尔茨海默病(AD)的现实。AD是一种主要影响老年人的神经退行性疾病,是痴呆症的主要原因。然而,其病因和发病机制仍知之甚少。AD的一个标志是大脑中异常蛋白质的积累,包括淀粉样蛋白β(Aβ)和tau。这些蛋白质会破坏神经元的正常功能,最终导致神经元死亡。自2016年以来,一系列研究1表明,40Hz的刺激有效提高了AD模型小鼠的认知能力。这种改善归因于积累的淀粉样蛋白-β(Aβ)蛋白的减少和小胶质细胞功能的增强,这两者都与该疾病有关。然而,这些发现受到了Buzsáki教授最近进行的研究2的挑战,该研究发表在《自然神经科学》杂志上。在这项研究中,研究团队使用了两种AD小鼠模型,特别是APP/PS1和5xFAD,来探索急性和慢性40Hz光刺激对Aβ、小胶质细胞和伽马振荡的影响。首先,他们发现,无论是在体外还是体内测试,40Hz的光刺激对Aβ沉积水平或小胶质细胞的形态都没有影响。随后,他们证明了夹带不会激活目标大脑区域(视觉皮层、海马体和内嗅皮层)的固有伽马振荡。此外,他们观察到40赫兹的光刺激诱导了小鼠的厌恶和回避行为。这一点从小鼠在具有40Hz光的隔间中度过的时间与具有连续光的隔间相比是显而易见的。鉴于缺乏评估40 Hz夹带前后认知功能的实验,应谨慎考虑急性或慢性暴露后AD病理变化的不一致性。例如,无法复制闪烁光刺激对Aβ和小胶质细胞的有益影响可能归因于实验参数的变化。尽管动物模型和人类受试者在40赫兹的刺激后都表现出认知功能(如记忆)的改善,但驱动这些变化的潜在机制仍然难以捉摸。然而,这项研究成功地消除了减少AD症状的一个潜在机制,即自然伽马带振荡的夹带。寻找替代机制的工作仍在继续。考虑到40赫兹刺激导致的显著行为改善,无可争议的是,潜在机制一定与伽马能带活动(30–100赫兹)有显著关联。宽频带包括多个亚伽马振荡,每个亚伽马振荡起着不同的作用。Buzsáki教授实验室的另一项研究3直接证明了不同的伽马节律在认知功能中的作用,特别是在学习方面。在空间学习过程中,发现高频伽马振荡使内侧内嗅皮层(MEC)和齿状回(DG)同步,从而夹带颗粒细胞。相反,在进行对象学习时,观察到低频伽马振荡使外侧内嗅皮层(LEC)和DG同步。同年发表的另一项研究4强化了多重伽马振荡的理论,每种振荡都扮演着不同的角色。然而,这一次,研究的重点是视觉系统,特别是初级视觉皮层(V1)和LGN,而不是边缘系统。这些不同的伽马振荡似乎能够同时携带不同的空间频率信息,证明了大脑中的多路复用现象。多重伽马节律的假设可能为夹带刺激提供未来的见解(图1)。虽然伽马振荡可能不能从根本上治愈阿尔茨海默氏症,但它们似乎有助于保持记忆功能。5需要进行额外的研究,以确定诱导可穿过整个大脑的内部伽马波的最佳目标。鉴于许多尚未解决的问题,进一步研究AD治疗中40 Hz夹带的神经机制至关重要。一个重要的问题是,不同类型和过程的AD是否会从相同的夹带方法中同等受益。不同的实验条件,包括使用不同的实验设备和光类型,会对争议产生怎样的影响,也存在不确定性。此外,40Hz刺激的潜在副作用,如诱发癫痫的风险,仍不清楚。 总之,尽管目前对夹带的使用存在分歧,但了解潜在机制的努力仍在继续。正如新物种出现在不同生态系统的边界上一样,新的科学见解也出现在不同学科的交叉点上。我们必须有敏锐的洞察力来认识到这些新出现的机会,并准备说服其他人相信它们的潜力。韩:概念化;融资收购;写作——初稿;写作-复习&amp;编辑。提交人声明没有利益冲突。
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