This book explores and critiques topical debates in educational sciences, philosophy, social work and cognitive neuroscience. It examines constructions of children, parents and the welfare state in relation to neurosciences and its vocabulary of brain architecture, critical periods and toxic stress. The authors provide insight into the historical roots of the relationship between early childhood education policy and practice and sciences. The book argues that the neurophilia in the early childhood education field is not a coincidence, but relates to larger societal changes that value economic arguments over ethical, social and eminently pedagogical concerns. It affects the image of the child, the parent and the very meaning of education in general. Constructions of Neuroscience in Early Childhood Education discusses what neuroscience has to offer, what its limitations are, and how to gain a more nuanced view on its benefits and challenges. The debates in this book will support early childhood researchers, students and practitioners in the field to make their own judgements about new evolutions in the scientific discourse.

This book explores and critiques topical debates in educational sciences, philosophy, social work and cognitive neuroscience. It examines constructions of children, parents and the welfare state in relation to neurosciences and its vocabulary of brain architecture, critical periods and toxic stress. The authors provide insight into the historical roots of the relationship between early childhood education policy and practice and sciences. The book argues that the neurophilia in the early childhood education field is not a coincidence, but relates to larger societal changes that value economic arguments over ethical, social and eminently pedagogical concerns. It affects the image of the child, the parent and the very meaning of education in general. Constructions of Neuroscience in Early Childhood Education discusses what neuroscience has to offer, what its limitations are, and how to gain a more nuanced view on its benefits and challenges. The debates in this book will support early childhood researchers, students and practitioners in the field to make their own judgements about new evolutions in the scientific discourse.

The Mathematical Brain Across the Lifespan is the latest volume in the Progress in Brain Research series that focuses on new trends and developments. This established international series examines major areas of basic and clinical research within the neurosciences, as well as popular and emerging subfields.

Arithmetic disability stems from deficits in neurodevelopment, with great individual differences in development or function of an individual at neuroanatomical, neuropsychological, behavioral, and interactional levels. Heterogeneous Contributions to Numerical Cognition: Learning and Education in Mathematical Cognition examines research in mathematical education methods and their neurodevelopmental basis, focusing on the underlying neurodevelopmental features that must be taken into account when teaching and learning mathematics. Cognitive domains and functions such as executive functions, memory, attention, and language contribute to numerical cognition and are essential for its proper development. These lines of research and thinking in neuroscience are discussed in this book to further the understanding of the neurodevelopmental and cognitive basis of more complex forms of mathematics - and how to best teach them. By unravelling the basic building blocks of numerical thinking and the developmental basis of human capacity for arithmetic, this book and the discussions within are important for the achievement of a comprehensive understanding of numerical cognition, its brain basis, development, breakdown in brain-injured individuals, and failures to master mathematical skills.

Heterogeneity of Function in Numerical Cognition presents the latest updates on ongoing research and discussions regarding numerical cognition. With great individual differences in the development or function of numerical cognition at neuroanatomical, neuropsychological, behavioral, and interactional levels, these issues are important for the achievement of a comprehensive understanding of numerical cognition, hence its brain basis, development, breakdown in brain-injured individuals, and failures to master mathematical skills. These functions are essential for the proper development of numerical cognition.