Department of Psychology, University of Illinois Urbana-Champaign, Champaign, Illinois, USA.
Educational Neuroscience Program, Gallaudet University, Washington, DC, USA.
Dev Sci. 2024 Nov;27(6):e13556. doi: 10.1111/desc.13556. Epub 2024 Aug 6.
Symbolic numeracy first emerges as children learn the meanings of number words and how to use them to precisely count sets of objects. This development starts before children enter school and forms a foundation for lifelong mathematics achievement. Despite its importance, exactly how children acquire this basic knowledge is unclear. Here we test competing theories of early number learning by measuring event-related brain potentials during a novel number word-quantity comparison task in 3-4-year-old preschool children (N = 128). We find several qualitative differences in neural processing of number by conceptual stage of development. Specifically, we find differences in early attention-related parietal electrophysiology (N1), suggesting that less conceptually advanced children process arrays as individual objects and more advanced children distribute attention over the entire set. Subsequently, we find that only more conceptually advanced children show later-going frontal (N2) sensitivity to the numerical-distance relationship between the number word and visual quantity. The nature of this response suggested that exact rather than approximate numerical meanings were being associated with number words over frontal sites. No evidence of numerical distance effects was observed over posterior scalp sites. Together these results suggest that children may engage parallel individuation of objects to learn the meanings of the first few number words, but, ultimately, create new exact cardinal value representations for number words that cannot be defined in terms of core, nonverbal number systems. More broadly, these results document an interaction between attentional and general cognitive mechanisms in cognitive development. RESEARCH HIGHLIGHTS: Conceptual development in numeracy is associated with a shift in attention from objects to sets. Children acquire meanings of the first few number words through associations with parallel attentional individuation of objects. Understanding of cardinality is associated with attentional processing of sets rather than individuals. Brain signatures suggest children attribute exact rather than approximate numerical meanings to the first few number words. Number-quantity relationship processing for the first few number words is evident in frontal but not parietal scalp electrophysiology of young children.
符号计算能力首先出现在儿童学习数字单词的含义并学习如何使用它们精确地计数物体集合的时候。这种发展始于儿童入学之前,是终身数学成就的基础。尽管它很重要,但儿童究竟如何获得这种基本知识还不清楚。在这里,我们通过在 3-4 岁学龄前儿童(N=128)的一项新的数字单词-数量比较任务中测量事件相关脑电位,来测试早期数字学习的竞争理论。我们发现,在发展的概念阶段,神经处理数字的方式存在几种质的差异。具体来说,我们发现早期与注意力相关的顶叶电生理学(N1)存在差异,这表明概念上较不成熟的儿童将数组视为单个物体,而较成熟的儿童则将注意力分配到整个集合上。随后,我们发现只有概念上更先进的儿童在大脑额叶(N2)上对数字单词与视觉数量之间的数值距离关系表现出后续的敏感性。这种反应的性质表明,在额叶部位,与数字单词相关联的是确切的而不是近似的数值意义。在后头部头皮部位没有观察到数值距离效应的证据。总的来说,这些结果表明,儿童可能通过将物体个体化来学习前几个数字单词的含义,但最终会为数字单词创建无法用核心非言语数字系统来定义的新的精确基数值表示。更广泛地说,这些结果记录了认知发展中注意力和一般认知机制之间的相互作用。研究亮点: 计算能力的概念发展与从物体到集合的注意力转移有关。儿童通过将物体的平行个体化与数字单词的含义联系起来,从而获得前几个数字单词的含义。对基数的理解与对集合而不是个体的注意力处理有关。大脑特征表明,儿童将确切的而不是近似的数值意义归因于前几个数字单词。对于前几个数字单词,数量关系的处理在幼儿的额叶而不是顶叶头皮电生理学中可见。
