Driving brain functions with information-based neuromodulation

通过基于信息的神经调节驱动大脑功能

• 批准号: RGPIN-2019-06162
• 负责人: Albouy, Philippe
• 金额: $ 2.4万
• 依托单位: Université Laval
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2021
• 资助国家: 加拿大
• 起止时间: 2021-01-01 至 2022-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=738749
• 关键词: Driving; brain; functions; information; based

The principal goal of this research program is to investigate the functional role of brain oscillations in cognitive functions. To do so, we propose to combine neuroimaging approaches and information-based non-invasive brain stimulation (NIBS), a method that allows causal inference. Recently, we have demonstrated the existence of a causal relationship between brain oscillatory markers (rhythmic fluctuation of brain activity) and cognitive functions, by showing that rhythmic brain stimulation promotes endogenous brain oscillations, and results in specific and causal enhancement of participants' executive functions. This research program aims to release the full potential of such optimized brain stimulation methods with two complementary research axes. In Axis I we aim to develop experimental approaches to define fine-grained oscillatory markers related to cognitive functions and to evaluate their causal roles in brain networks. Our model of interest is working memory, a cognitive ability that is essential for everyday life simple task realisation. With two studies (intra-cranial EEG in humans, simultaneous EEG/fMRI) we will characterize fine-grained oscillatory dynamics (notably complex cross-frequency interactions) supporting encoding, maintenance, manipulation and retrieval of auditory information. The brain oscillatory markers and brain networks identified in this axis will then inform the parameters of the NIBS studies developed in Axis II. Axis II aims to test in healthy individuals the potential of modulating the oscillatory markers defined in Axis I to support brain communication and functions during learning. We aim to identify the plastic changes associated to longitudinal training combined with optimized brain stimulation. We will use NIBS (combined with neuroimaging and EEG) to target specific brain dynamics during learning to induce long-term benefits on cognitive functions. Through two complementary studies, we will investigate A) how the modulation of a simple frequency band boosts brain plasticity during training to accelerate and optimize learning; B) how the modulation of more complex/fine-grained frequency patterns (cross-frequency interactions identified in Axis I) can show specific and long term effects on learning. Through these two research axes, this research program provides the opportunity to elucidate the mechanisms of brain plasticity that underlie memory functions, and enhancements by the delivery of optimized brain stimulation. This program will improve our understanding of network dynamics supporting memory functions in humans; establish brain oscillations as appropriate targets for controlled interventions into brain activity and functions; and open a new window of transfer to clinical neuroscience of individual, information-based interventions.

本研究计划的主要目标是研究脑振荡在认知功能中的功能作用。为此，我们建议结合联合收割机神经成像方法和基于信息的非侵入性脑刺激（NIBS），一种允许因果推理的方法。最近，我们已经证明了脑振荡标记物（脑活动的节律性波动）和认知功能之间存在因果关系，通过显示节律性脑刺激促进内源性脑振荡，并导致参与者的执行功能的特定和因果增强。该研究计划旨在通过两个互补的研究轴释放这种优化的脑刺激方法的全部潜力。在轴I，我们的目标是开发实验方法来定义细粒度的振荡标记相关的认知功能，并评估其因果关系的作用，在大脑网络。我们感兴趣的模型是工作记忆，这是一种认知能力，对日常生活中的简单任务实现至关重要。通过两项研究（人类颅内EEG，同步EEG/fMRI），我们将表征支持听觉信息编码，维护，操纵和检索的细粒度振荡动力学（特别是复杂的交叉频率相互作用）。在此轴中识别的脑振荡标记物和脑网络将为轴II中开发的NIBS研究的参数提供信息。轴II旨在测试在健康个体中调节轴I中定义的振荡标记以支持学习期间的大脑通信和功能的潜力。我们的目标是确定与纵向训练结合优化脑刺激相关的可塑性变化。我们将使用NIBS（结合神经影像学和EEG）在学习期间针对特定的大脑动力学，以诱导对认知功能的长期益处。通过两项互补的研究，我们将研究A）简单频带的调制如何在训练过程中增强大脑可塑性，以加速和优化学习; B）更复杂/细粒度的频率模式（轴I中确定的交叉频率相互作用）的调制如何对学习产生特定和长期的影响。 通过这两个研究轴，该研究计划提供了阐明大脑可塑性机制的机会，这些机制是记忆功能的基础，并通过提供优化的大脑刺激来增强。该计划将提高我们对支持人类记忆功能的网络动力学的理解;建立脑振荡作为控制干预大脑活动和功能的适当目标;并打开一个新的窗口转移到个人，基于信息的干预临床神经科学。