An fMRI intervention study of creative mathematical reasoning: behavioral and brain effects across different levels of cognitive ability

IF 3.4 Q2 NEUROSCIENCES

Trends in Neuroscience and Education Pub Date : 2022-12-01 DOI:10.1016/j.tine.2022.100193

Linnea Karlsson Wirebring , Carola Wiklund-Hörnqvist , Sara Stillesjö , Carina Granberg , Johan Lithner , Micael Andersson , Lars Nyberg , Bert Jonsson

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引用次数: 2

Abstract

Background

Many learning methods of mathematical reasoning encourage imitative procedures (algorithmic reasoning, AR) instead of more constructive reasoning processes (creative mathematical reasoning, CMR). Recent research suggest that learning with CMR compared to AR leads to better performance and differential brain activity during a subsequent test. Here, we considered the role of individual differences in cognitive ability in relation to effects of CMR.

Methods

We employed a within-subject intervention (N=72, M_Age=18.0) followed by a brain-imaging session (fMRI) one week later. A battery of cognitive tests preceded the intervention. Participants were divided into three cognitive ability groups based on their cognitive score (low, intermediate and high).

Results

On mathematical tasks previously practiced with CMR compared to AR we observed better performance, and higher brain activity in key regions for mathematical cognition such as left angular gyrus and left inferior/middle frontal gyrus. The CMR-effects did not interact with cognitive ability, albeit the effects on performance were driven by the intermediate and high cognitive ability groups.

Conclusions

Encouraging pupils to engage in constructive processes when learning mathematical reasoning confers lasting learning effects on brain activation, independent of cognitive ability. However, the lack of a CMR-effect on performance for the low cognitive ability group suggest future studies should focus on individualized learning interventions, allowing more opportunities for effortful struggle with CMR.

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创造性数学推理的功能磁共振干预研究:不同认知能力水平的行为和大脑效应

许多数学推理的学习方法鼓励模仿过程(算法推理，AR)，而不是更具建设性的推理过程(创造性数学推理，CMR)。最近的研究表明，与AR相比，使用CMR学习可以在随后的测试中获得更好的表现和不同的大脑活动。在这里，我们考虑了认知能力的个体差异在CMR效果中的作用。方法采用受试者内干预(N=72, MAge=18.0)，一周后进行脑成像(fMRI)检查。在干预之前进行了一系列认知测试。参与者根据他们的认知得分分为三个认知能力组(低、中、高)。结果与AR相比，CMR在先前的数学任务中表现更好，并且在数学认知的关键区域(如左角回和左额下回/中回)的大脑活动更高。cmr效应与认知能力没有相互作用，尽管对表现的影响是由中等和高认知能力组驱动的。结论:鼓励学生在学习数学推理时进行建设性的过程，可以对大脑激活产生持久的学习效果，而不依赖于认知能力。然而，缺乏CMR对低认知能力组表现的影响表明，未来的研究应侧重于个性化的学习干预，让更多的机会努力与CMR斗争。

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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来源期刊

Trends in Neuroscience and Education NEUROSCIENCES-

CiteScore

6.30

自引率

6.10%

发文量

审稿时长

65 days