Multi-parametric vascular and metabolic MRI for the study of cerebral plasticity

用于脑可塑性研究的多参数血管和代谢 MRI

• 批准号: RGPIN-2015-04665
• 负责人: Gauthier, Claudine
• 金额: $ 1.6万
• 依托单位: Concordia University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=708107
• 关键词: Multi; parametric; vascular; metabolic; MRI

The brain is known to be a highly plastic organ, meaning that it has the lifelong ability to alter its structure and function following training to learn a new task and in response to physiological changes such as injury and lifestyle (e.g. diet or exercise). For example, it has been shown using magnetic resonance imaging (MRI) that learning a motor task such as juggling can lead to changes in brain structure and function. But while we know that the brain changes, the extent of these changes, their biological nature, whether these changes are maintained in the long term and whether they can be harnessed for disease recovery are all the subject of ongoing debate. This is because brain plasticity involves multiple subtle structural, vascular and metabolic changes. These changes are notoriously difficult to study in humans using single MRI techniques and small sample sizes. Most MRI research in Canada is done using 3 tesla (T) magnets, and many techniques exist at this field strength to study brain structure and function. Unfortunately, many of the techniques commonly used in research provide only limited information about the biological mechanisms that underlie the MRI signals. While less common, new and advanced techniques exist to look at more specific information such cerebral blood flow, blood volume, oxygen metabolism, veins and grey matter microstructure. Furthermore, higher magnetic fields (7T) can also be used, in combination with these advanced techniques, to help us understand the biological mechanisms at play with greater specificity and higher resolution. Here, we propose to use these advanced techniques at 3T and 7T to better understand the plasticity process. In this program, we will continue to develop the existing advanced vascular and metabolic techniques by extending models we have developed in the past. Also, we will combine advanced MRI techniques measuring brain structure, blood vessel anatomy and function, and metabolism to create novel metrics that better capture the biological plasticity process. These new metrics will be used, along with more established techniques, to study the complex patterns that characterize brain plasticity during motor learning tasks. These studies will involve bimanual piano playing and a finger pinching task, and will help establish the validity and sensitivity of the techniques developed here at 7T and at 3T. In the future, these techniques will also be used to study age-related and exercise-induced plasticity. Given that plasticity is an essential process of normal and abnormal brain function, and given the increasing interest in neuroimaging, the technical work developed here is expected to lead to highly cited publications. Furthermore, by training young scientists to have versatile and novel expertise in these fields, this program will promote their careers by making them in high demand and contribute to fostering innovative science in Canada.

众所周知，大脑是一个高度可塑性的器官，这意味着它具有终身的能力，可以在训练后改变其结构和功能，以学习新的任务，并响应生理变化，如受伤和生活方式（例如饮食或运动）。例如，磁共振成像（MRI）显示，学习杂耍等运动任务可能会导致大脑结构和功能的变化。但是，虽然我们知道大脑会发生变化，但这些变化的程度，它们的生物学性质，这些变化是否会长期保持，以及它们是否可以用于疾病康复，都是正在进行的辩论的主题。这是因为大脑可塑性涉及多种微妙的结构、血管和代谢变化。众所周知，使用单一MRI技术和小样本量在人类中研究这些变化是非常困难的。 加拿大的大多数MRI研究都是使用3特斯拉（T）磁铁进行的，在这个磁场强度下存在许多技术来研究大脑结构和功能。不幸的是，许多研究中常用的技术只能提供有关MRI信号背后的生物机制的有限信息。虽然不太常见，但存在新的和先进的技术来查看更具体的信息，如脑血流量，血容量，氧代谢，静脉和灰质微结构。此外，还可以使用更高的磁场（7T），结合这些先进的技术，帮助我们以更高的特异性和更高的分辨率了解生物学机制。 在这里，我们建议在3T和7T下使用这些先进的技术，以更好地理解塑性过程。在这个项目中，我们将通过扩展我们过去开发的模型来继续开发现有的先进血管和代谢技术。此外，我们将结合联合收割机先进的MRI技术测量大脑结构，血管解剖和功能，以及新陈代谢，以创建新的指标，更好地捕捉生物可塑性过程。这些新的指标将与更成熟的技术一起沿着用于研究运动学习任务中表征大脑可塑性的复杂模式。这些研究将涉及双手钢琴演奏和手指捏任务，并将有助于建立在这里开发的技术在7T和3T的有效性和敏感性。将来，这些技术也将用于研究年龄相关和运动诱导的可塑性。鉴于可塑性是正常和异常脑功能的一个重要过程，并鉴于对神经成像的兴趣日益增加，这里开发的技术工作预计将导致高引用的出版物。此外，通过培训年轻科学家在这些领域拥有多功能和新颖的专业知识，该计划将促进他们的职业生涯，使他们在高需求，并有助于促进加拿大的创新科学。