Neuroscience Of Reading Chapter 5 PDF

Summary

This document focuses on the neuroscience of reading, discussing the brain regions and processes involved in this complex skill. It also covers neuroimaging studies and examines the links between brain development and literacy. The emphasis is on the science behind reading.

Full Transcript

NEUROSCIENCE OF
READING
CHAPTER 5
1. BRAIN REGIONS INVOLVED IN READING

The brain has three main parts: the cerebrum, cerebellum and brainstem. Cerebrum: is the largest part
of the brain and is composed of right and left hemispheres. It performs higher functions like
interpreting touch, vision and hearing, as well as speech, reasoning, emotions, learning, and fine control
of movement.
1. BRAIN REGIONS INVOLVED IN READING
1. BRAIN REGIONS INVOLVED IN READING

A number of brain regions are involved in reading and comprehension. Among them are
the temporal lobe, which is responsible for phonological awareness and for decoding and
discriminating sounds; Broca’s area in the frontal lobe, which governs speech production
and language comprehension; and the angular and supramarginal gyrus, which link
different parts of the brain so that letter shapes can be put together to form words.

2. NEUROIMAGING STUDIES AND READING RESEARCH

Neuroimaging is a branch of medical imaging that focuses on the brain. In addition to diagnosing
disease and assessing brain health, neuroimaging also studies:
How the brain works
How various activities impact the brain
2. NEUROIMAGING STUDIES AND READING RESEARCH

Converging evidence from a number of neuroimaging studies suggest that fluent word
identification in reading is related to the functional integrity of two left hemisphere posterior
systems: a temporo-parietal system and a ventral occipito-temporal system. These posterior
systems are functionally disrupted in developmental dyslexia. Reading disabled, relative to
nonimpaired, readers demonstrate heightened reliance on both inferior frontal and right
hemisphere posterior regions, presumably in compensation for the left hemisphere posterior
difficulties. The authors propose a neurobiological account suggesting that for normally
developing readers the temporo-parietal system predominates at first, and is associated with
aspects of processing critical in learning to integrate orthography with phonological and lexical-
semantic features of printed words. The occipito-temporal system, by contrast, constitutes a
fast, late-developing, word identification system that underlies fluent word recognition in skilled
readers. (PsycINFO Database Record (c) 2016 APA, all rights reserved)
2. NEUROIMAGING STUDIES AND READING RESEARCH

In this position paper, we advocate that advancements made in other disciplinary areas
such as neurolinguistics should be included into contemporary reading comprehension
courses and programs. We present findings from neurobiology of reading that suggest
explanation of certain reading behaviors: (1) the differences between reading disability
and typically developing readers; (2) an inverted U-shaped function that reflects the fact
that learning to read is associated with increased activation (the rising part of the inverted
U) and activation decreases are associated with familiarity, experience, and expertise (the
falling part of the inverted U); (3) and, the identification of reading networks. As potential
pedagogical implications of neuroimaging studies to reading, a list of sentence structures
is proposed as an example to further relate reading comprehension to cognitive capacity
limits.
2. NEUROIMAGING STUDIES AND READING RESEARCH

This editorial provides a summary of the highlights from 11 new papers that have been published in a
special issue of Brain and Language on the neurobiology of reading. The topics investigate reading
mechanisms in both adults and children. Several of the findings illustrate how responses in the left
ventral occipito-temporal cortex, and other reading areas, change with learning, expertise and the task:
In the early stages of reading acquisition, learning/expertise increases activation in reading areas as well
as in an attentionally-controlled, learning circuit. In later stages, expertise and efficiency decrease
activation within the reading network and increase anatomical connectivity. Special interest is given to a
white matter tract (the vertical occipital fasciculus) that projects dorsally from the left occipito-temporal
cortex to the posterior parietal lobe. This observation fits with a magnetoencephalography study
showing how activity in the angular gyrus is influenced by early occipito-temporal activity; with angular
gyrus activity contributing to inferior frontal activity. Overall, the papers within the special issue
illustrate the wide range of different techniques that can be used to reveal the functional anatomy of
reading and the time course of activity within the different reading pathways.
3. LINKS BETWEEN BRAIN DEVELOPMENT AND
LITERACY
Reading is a learned skill that is likely influenced by both brain maturation and experience. Functional
imaging studies have identified brain regions important for skilled reading, but the structural brain
changes that co-occur with reading acquisition remain largely unknown. We investigated maturational
volume changes in brain reading regions and their association with performance on reading measures.
Sixteen typically developing children (5-15 years old, 8 male, mean age of sample=10.06 ±3.29) received
two magnetic resonance imaging (MRI) scans, (mean inter-scan interval =2.19 years), and were
administered a battery of cognitive measures. Volume changes between time points in five bilateral
cortical regions of interest were measured, and assessed for relationships to three measures of reading.
Better baseline performances on measures of word reading, fluency and rapid naming, independent of
age and total cortical gray matter volume change, were associated with volume decrease in the left
inferior parietal cortex. Better baseline performance on a rapid naming measure was associated with
volume decrease in the left inferior frontal region. These results suggest that children who are better
readers, and who perhaps read more than less skilled readers, exhibit different development trajectories
in brain reading regions. Understanding relationships between reading performance, reading experience
and brain maturation trajectories may help with the development and evaluation of targeted
interventions.
3. LINKS BETWEEN BRAIN DEVELOPMENT AND
LITERACY

Emergent reading emphasizes the developmental continuum aspect of learning to read and advocates
the importance of reading-related behaviors occurring before school. Brain imaging evidence has
suggested high plasticity of young children’s brains, and emergent reading experience can shape the
brain development supporting fluent reading. The brain imaging evidence elucidates our understanding
of the importance of emergent reading from a neurobiological point of view. Future studies are needed
to understand how emergent reading experience can become protective factor for children at risk for
reading impairments. Future studies need to design early interventions to improve emergent reading
experience which is a crucial period.
3. LINKS BETWEEN BRAIN DEVELOPMENT AND
LITERACY
 https://psycnet.apa.org/record/2002-02360-006
https://www.ojed.org/index.php/jise/article/view/649
https://www.sciencedirect.com/science/article/pii/S0093934X13000382
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4128180/
https://www.intechopen.com/chapters/64663
https://wyominginstructionalnetwork.com/wp-content/uploads/2021/02/Neuroscience-and-
Reading_2-12-21.pdf
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https://hms.harvard.edu/news-events/publications-archive/brain/reading-
brain#:~:text=Among%20them%20are%20the%20temporal,the%20brain%20so%20that%20letter

https://medicine.utah.edu/psychiatry/research/labs/diagnostic-
neuroimaging/neuroimaging#:~:text=Neuroimaging%20is%20a%20branch%20of,How%20the%20brain%20works