Yu Qian, Kong Zhaowei, Zou Liye, Herold Fabian, Ludyga Sebastian, Zhang Zhihao, Hou Meijun, Kramer Arthur F, Erickson Kirk I, Taubert Marco, Hillman Charles H, Mullen Sean P, Gerber Markus, Müller Notger G, Kamijo Keita, Ishihara Toru, Schinke Robert, Cheval Boris, McMorris Terry, Wong Ka Kit, Shi Qingde, Nie Jinlei
Faculty of Education, University of Macau, Macao, 999078, China.
Body-Brain-Mind Laboratory, School of Psychology, Shenzhen University, Shenzhen, 518060, China.
Int J Clin Health Psychol. 2024 Jul-Sep;24(3):100498. doi: 10.1016/j.ijchp.2024.100498. Epub 2024 Sep 7.
There is evidence that complex relationships exist between motor functions, brain structure, and cognitive functions, particularly in the aging population. However, whether such relationships observed in older adults could extend to other age groups (e.g., younger adults) remains to be elucidated. Thus, the current study addressed this gap in the literature by investigating potential associations between motor functions, brain structure, and cognitive functions in a large cohort of young adults.
In the current study, data from 910 participants (22-35 yr) were retrieved from the Human Connectome Project. Interactions between motor functions (i.e., cardiorespiratory fitness, gait speed, hand dexterity, and handgrip strength), brain structure (i.e., cortical thickness, surface area, and subcortical volumes), and cognitive functions were examined using linear mixed-effects models and mediation analyses. The performance of different machine-learning classifiers to discriminate young adults at three different levels (related to each motor function) was compared.
Cardiorespiratory fitness and hand dexterity were positively associated with fluid and crystallized intelligence in young adults, whereas gait speed and handgrip strength were correlated with specific measures of fluid intelligence (e.g., inhibitory control, flexibility, sustained attention, and spatial orientation; false discovery rate [FDR] corrected, < 0.05). The relationships between cardiorespiratory fitness and domains of cognitive function were mediated by surface area and cortical volume in regions involved in the default mode, sensorimotor, and limbic networks (FDR corrected, < 0.05). Associations between handgrip strength and fluid intelligence were mediated by surface area and volume in regions involved in the salience and limbic networks (FDR corrected, < 0.05). Four machine-learning classifiers with feature importance ranking were built to discriminate young adults with different levels of cardiorespiratory fitness (random forest), gait speed, hand dexterity (support vector machine with the radial kernel), and handgrip strength (artificial neural network).
In summary, similar to observations in older adults, the current study provides empirical evidence (i) that motor functions in young adults are positively related to specific measures of cognitive functions, and (ii) that such relationships are at least partially mediated by distinct brain structures. Furthermore, our analyses suggest that machine-learning classifier has a promising potential to be used as a classification tool and decision support for identifying populations with below-average motor and cognitive functions.
有证据表明运动功能、脑结构和认知功能之间存在复杂关系,尤其是在老年人群体中。然而,在老年人中观察到的这种关系是否能扩展到其他年龄组(如年轻人)仍有待阐明。因此,本研究通过调查一大群年轻人的运动功能、脑结构和认知功能之间的潜在关联,填补了文献中的这一空白。
在本研究中,从人类连接体项目中检索了910名参与者(22 - 35岁)的数据。使用线性混合效应模型和中介分析,研究了运动功能(即心肺适能、步速、手部灵活性和握力)、脑结构(即皮质厚度、表面积和皮质下体积)和认知功能之间的相互作用。比较了不同机器学习分类器在三个不同水平(与每种运动功能相关)上区分年轻人的性能。
心肺适能和手部灵活性与年轻人的流体智力和晶体智力呈正相关,而步速和握力与流体智力的特定指标相关(如抑制控制、灵活性、持续注意力和空间定向;错误发现率[FDR]校正,<0.05)。心肺适能与认知功能领域之间的关系由默认模式、感觉运动和边缘网络相关区域的表面积和皮质体积介导(FDR校正,<0.05)。握力与流体智力之间的关联由突显和边缘网络相关区域的表面积和体积介导(FDR校正,<0.05)。构建了四个具有特征重要性排名的机器学习分类器,以区分不同心肺适能水平(随机森林)、步速、手部灵活性(径向核支持向量机)和握力(人工神经网络)的年轻人。
总之,与在老年人中的观察结果类似,本研究提供了实证证据:(i)年轻人的运动功能与认知功能的特定指标呈正相关;(ii)这种关系至少部分由不同的脑结构介导。此外,我们的分析表明,机器学习分类器有潜力作为一种分类工具和决策支持,用于识别运动和认知功能低于平均水平的人群。
