The scope, cause and consequences of age-related decline in neural distinctiveness and brain signal variability in healthy and pathological aging

健康和病理衰老中与年龄相关的神经独特性和大脑信号变异性下降的范围、原因和后果

• 批准号: 10045722
• 负责人: Poortata Shirish Lalwani
• 金额: $ 4.32万
• 依托单位: UNIVERSITY OF MICHIGAN AT ANN ARBOR
• 依托单位国家: 美国
• 财政年份: 2020
• 资助国家: 美国
• 起止时间: 2020-09-01 至 2022-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/10045722
• 关键词: Address; Adult; Age; Age-associated memory impairment; Aging; Alzheimer' s Disease; Amyloid; Animal Experimentation; Auditory area; Behavior; Behavioral; Biological Markers; Brain; Categories; Clinical; Cognitive; Computer Models; Data; Data Set; Development; Elderly; Functional Magnetic Resonance Imaging; Functional disorder; Future; Glutamates; Glutamine; Hippocampus (Brain); Human; Impaired cognition; Impairment; Individual Differences; Intervention; Lead; Life; Liquid substance; Magnetic Resonance Spectroscopy; Measures; Memory; Memory impairment; Modality; Motor; Motor Cortex; Nerve Degeneration; Neurotransmitters; Participant; Pathologic; Pathology; Patients; Pattern; Performance; Pharmacologic Substance; Pharmacology; Phase; Play; Population; Positron-Emission Tomography; Research; Research Project Grants; Rest; Role; Sensory; Signal Transduction; Spectrum Analysis; Standardization; Stimulus; Task Performances; Testing; Training; Visual Cortex; Work; age related; base; behavior test; behavioral impairment; cognitive function; cognitive task; design; experience; gamma-Aminobutyric Acid; healthy aging; mild cognitive impairment; neurochemistry; neurotransmission; normal aging; pathological aging; pre-clinical; pre-doctoral; preclinical development; relating to nervous system; response; tau Proteins; visual stimulus; young adult

Normal aging is typically associated with pervasive declines in cognitive, motor and sensory function; however, there are substantial individual differences: some older adults experience mild impairments while others experience severe cognitive declines. Understanding the neural bases of individual differences during aging is imperative in designing future interventions to address age-related cognitive impairments. Using behavioral testing, functional MRI, spectroscopy and pharmacological manipulations in human adults, I propose to investigate the scope, cause and consequences of age-related decline in two neural factors that may play a role in these individual differences: (1) neural distinctiveness (how similar/confusable neural activation patterns are in response to different stimulus categories) and (2) brain signal variability (moment-to-moment change in neural activity independent of task). Both these measures have been found to decline with age and both have been associated with individual differences in behavior. During the predoctoral (F99) phase of the training, my research will focus on healthy aging: 1) investigating the scope and cause (specifically role of GABA levels) of age-related decline in neural distinctiveness in sensory regions, 2) the cause of age-related declines in brain signal variability, and 3) the behavioral consequences of age-related declines in these two neural measures. During the postdoctoral (K00) phase, I will extend my previous research to again study neural distinctiveness and brain signal variability, but now in the context of memory and hippocampal dysfunction, and in a clinical population (patients with mild cognitive impairment, MCI). I will use task-based fMRI to measure neural distinctiveness, resting-state fMRI to measure brain signal variability, and MR spectroscopy to measure levels of various neurotransmitters (including glutamine, glutamate, NAA, and GABA), all in the hippocampus, in healthy younger and older adults as well as MCI patients. I will also collect behavioral data from the same participants during the mnemonic similarity task (MST), a highly sensitive measure of hippocampal dysfunction. I propose to investigate a) age-related changes in neural distinctiveness and resting state variability in the hippocampus, b) the neurochemical basis of these neural changes, and c) the behavioral and pathological consequences of these neural changes. For the MCI patients, I will also have access to a rich dataset of other biomarkers (e.g., longitudinal measures of CSF and PET-based amyloid and tau) collected at UCI’s Alzheimer’s disease research center (ADRC). I will therefore be able to examine neural distinctiveness and brain signal variability in the context of the amyloid tau neurodegeneration (biomarker profiling) framework. Together, this research could lead to the development of preclinical markers for Alzheimer’s disease (AD) and open new avenues for early pharmacological interventions to treat cognitive decline in healthy and pathological aging.

正常衰老通常与认知、运动和感觉功能的普遍下降有关;然而，个体差异很大：一些老年人会出现轻度障碍，而另一些人会出现严重的认知下降。了解衰老过程中个体差异的神经基础对于设计未来的干预措施以解决与年龄相关的认知障碍至关重要。在成年人中使用行为测试，功能性MRI，光谱学和药理学操作，我建议调查两种神经因素中与年龄相关的衰退的范围，原因和后果，这些因素可能在这些个体差异中发挥作用：（1）神经特异性（2）大脑信号的可变性（响应于不同刺激类别的神经激活模式的相似性/易混淆性）（与任务无关的神经活动的瞬间变化）。这两项指标都随着年龄的增长而下降，并且都与行为的个体差异有关。在博士前（F99）阶段的培训，我的研究将集中在健康老龄化：1）调查的范围和原因（特别是GABA水平的作用）与年龄相关的下降在感觉区域的神经特异性，2）的原因与年龄相关的下降在大脑信号变异性，和3）与年龄相关的下降在这两个神经措施的行为后果。在博士后（K 00）阶段，我将扩展我以前的研究，再次研究神经的独特性和大脑信号的变异性，但现在在记忆和海马功能障碍的背景下，并在临床人群（轻度认知障碍患者，MCI）。我将使用基于任务的功能性磁共振成像来测量神经的独特性，静息状态功能性磁共振成像来测量大脑信号的变异性，磁共振波谱来测量各种神经递质（包括谷氨酰胺，谷氨酸，NAA和GABA）的水平，所有这些都在健康的年轻人和老年人以及MCI患者的海马体中。我还将在记忆相似性任务（MST）中收集相同参与者的行为数据，这是一种高度敏感的海马功能障碍测量方法。我建议调查a）海马神经特异性和静息状态变异性的年龄相关变化，B）这些神经变化的神经化学基础，以及c）这些神经变化的行为和病理后果。对于MCI患者，我还可以访问其他生物标志物的丰富数据集（例如，基于CSF和PET的淀粉样蛋白和tau的纵向测量），其在UCI的阿尔茨海默病研究中心（ADRC）收集。因此，我将能够在淀粉样蛋白tau神经变性（生物标志物分析）框架的背景下检查神经特异性和脑信号变异性。总之，这项研究可能会导致阿尔茨海默病（AD）的临床前标志物的开发，并为早期药物干预开辟新的途径，以治疗健康和病理性衰老中的认知下降。