Bioelectronic Zeitgebers: targeted neuromodulation to re-establish circadian rhythms.

Alceste Deli, Mayela Zamora, John E Fleming, Amir Divanbeighi Zand, Moaad Benjaber, Alexander L Green, Timothy Denison
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Abstract

Existing neurostimulation systems implanted for the treatment of neurodegenerative disorders generally deliver invariable therapy parameters, regardless of phase of the sleep/wake cycle. However, there is considerable evidence that brain activity in these conditions varies according to this cycle, with discrete patterns of dysfunction linked to loss of circadian rhythmicity, worse clinical outcomes and impaired patient quality of life. We present a targeted concept of circadian neuromodulation using a novel device platform. This system utilises stimulation of circuits important in sleep and wake regulation, delivering bioelectronic cues (Zeitgebers) aimed at entraining rhythms to more physiological patterns in a personalised and fully configurable manner. Preliminary evidence from its first use in a clinical trial setting, with brainstem arousal circuits as a surgical target, further supports its promising impact on sleep/wake pathology. Data included in this paper highlight its versatility and effectiveness on two different patient phenotypes. In addition to exploring acute and long-term electrophysiological and behavioural effects, we also discuss current caveats and future feature improvements of our proposed system, as well as its potential applicability in modifying disease progression in future therapies.

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生物电子昼夜节律器:重建昼夜节律的定向神经调节。
为治疗神经退行性疾病而植入的现有神经刺激系统通常提供不变的治疗参数,不受睡眠/觉醒周期阶段的影响。然而,有大量证据表明,这些病症的大脑活动会随着这一周期而变化,其离散的功能障碍模式与昼夜节律丧失、临床疗效恶化和患者生活质量下降有关。我们提出了一种利用新型设备平台进行昼夜节律神经调节的针对性概念。该系统利用刺激睡眠和觉醒调节中的重要回路,提供生物电子提示(Zeitgebers),旨在以个性化和完全可配置的方式将节律调整为更符合生理规律的模式。它首次用于临床试验,以脑干唤醒回路为手术目标,初步证据进一步证明了它对睡眠/觉醒病理的良好影响。本文中的数据强调了它的多功能性和对两种不同患者表型的有效性。除了探讨急性和长期的电生理和行为效应外,我们还讨论了我们提出的系统目前的注意事项和未来的功能改进,以及它在未来疗法中改变疾病进展的潜在适用性。
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