Children's neural responses to a novel mathematics concept

IF 3.4 Q2 NEUROSCIENCES

Trends in Neuroscience and Education Pub Date : 2020-09-01 DOI:10.1016/j.tine.2020.100128

Caron A.C. Clark, Ryan H. Hudnall, Sam Pérez-González

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引用次数: 2

Abstract

Background

Functional MRI studies have suggested a ‘frontoparietal shift’ over the course of development, whereby children tend to engage prefrontal neural regions to a greater extent than adults when completing mathematics tasks. Although this literature hints that lateral prefrontal regions may be involved in acquiring mathematics knowledge, a key limitation of existing studies is that they have included mathematics content that children already are familiar with as opposed to examining the dynamic learning process. We aimed to address this gap by examining children's neural responses when exposed to a new, unfamiliar mathematics concept.

Method

Eighteen 8–11 year old children viewed blocked demonstrations of base-2/binary (unfamiliar) and base-10/decimal (familiar) number systems while undergoing functional MRI (fMRI). Children's behavioral understanding of binary numbers was measured between fMRI runs.

Results

Counter to hypotheses, there were no overall differences in prefrontal activity for binary relative to decimal blocks. However, children with higher levels of behavioral understanding of the novel, binary concept showed enhanced neural activity in the left rostral middle frontal gyrus specifically during binary concept exposure. They also showed enhanced connectivity between this region and pre-and post-central gyri and left parahippocampal regions.

Conclusions

Individual differences in children's behavioral grasp of a new mathematics concept correlate with prefrontal activity and functional connectivity during exposure to the concept, suggesting that rostral prefrontal cortex may play a role in mathematics learning.

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儿童对新数学概念的神经反应

功能性核磁共振研究表明，在发育过程中存在“额顶叶转移”，即儿童在完成数学任务时比成人更倾向于使用前额叶神经区域。尽管这些文献暗示前额叶外侧区域可能参与了数学知识的获取，但现有研究的一个关键局限性是，它们包括了儿童已经熟悉的数学内容，而不是检查动态学习过程。我们的目的是解决这一差距，通过检查儿童的神经反应时，暴露于一个新的，不熟悉的数学概念。方法18名8-11岁的儿童在接受功能磁共振成像(fMRI)时观看了以2为基数/二进制(不熟悉)和以10为基数/十进制(熟悉)的数字系统的封锁演示。儿童对二进制数的行为理解在fMRI运行之间被测量。结果与假设相反，相对于十进制块，二进制块的前额叶活动没有总体差异。然而，对新奇的二元概念有较高行为理解水平的儿童，其左吻侧额叶中回的神经活动增强，特别是在二元概念暴露期间。他们还显示，该区域与中央前、后回和左海马旁区域之间的连通性增强。结论儿童对数学新概念行为掌握的个体差异与接触新概念时前额叶活动和功能连通性有关，提示前额叶吻侧皮层可能在数学学习中起作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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