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Abstract | Summary
| Original Article
Cortical activation and synchronization during sentence comprehension in high-functioning autism: Evidence of underconnectivity
Just MA, Cherkassky VL, Keller TA, Minshew NJ
Brain 2004; 127(8): 1811-1821
Bottom Line
Can the results from this
study of connections between
different areas of the brain
help explain some of the learning
and perceptual differences
in people with high functioning
autism?
- Some studies of brain
differences in people with
autism have found an abnormal
accumulation of white matter
(the cells of the brain making
connections).
- This study looked at how the increased amount of white matter in the brains of persons with autism could explain both their weaknesses and strengths.
- The findings of this study show that the excess white matter might cause slowing of signals or even absence of connections between different parts of the brain that usually work together to allow higher level functioning.
- The results of this study add another piece to the puzzle of what goes wrong to produce the social, language, and behavioural problems, as well as the talents, seen in people with autism.
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Question: Can the functional magnetic resonance imaging (fMRI) results from this study showing brain variations help explain some of the learning and perceptual differences in people with high functioning autism?
Background: Over the past several years, more and more
studies have demonstrated that the brains of children with autism
spectrum disorders (ASDs) differ from those of typically developing
children. The usual finding is that the brain is larger, with increases
in both white matter (the fibres that provide connections between
brain cells) and grey matter (the brain cells that are involved
in processing).
At the same time, there has been research that looked
at the abnormal psychological (mental processing) features that
are specific to people with ASDs. One of these, weak central coherence,
refers to the inability to ?see the forest for the trees.? People
with autism seem to focus on minor details while being unable to
perceive or understand the larger picture. This dysfunction is
partly explained by the inability to hold a single piece of information
in the mind while relating it to another.
The authors of the current
study relate their findings from functional MRI studies of people
with high functioning autism to the psychological deficits
(such as weak central coherence) and talents seen in people with
autism.
Participants: The participants were 17 persons with a diagnosis
of high functioning autism (that is, both verbal and full scale
IQ above 80). The 17 control participants were community volunteers.
The participants with autism were matched to their controls on
the basis of age, IQ, gender, race and their family’s socioeconomic
status. All were screened for genetic and medical disorders, as
well as for psychiatric or neurological disorders.
Method(s): The participants were asked to read a sentence and then respond to questions about it. Functional magnetic resonance imaging (fMRI) was done to see which portions of the brain were activated during the performance of the tasks.
Main Results: There were significant differences between
the two groups in the activation of language areas in the brain.
Broca’s area and Wernicke’s area, portions of the brain
that are associated with language functions, “lit up” on
the fMRI scans in different ways. Wernicke’s area is important
to the ability to identify individual words, while Broca’s
area acts to integrate a number of functions associated with language
comprehension and use. In the people with autism, there was greater
activation of Wernicke’s area and less activation of Broca’s
area than in the control group. In the participants with autism,
there was a reduction in the speed and intensity of communication
between the two areas, that is, the activation of the two areas
should have been synchronized, but was not in the participants
with autism.
Conclusions: There were significant differences between
the fMRI findings in the group with high functioning autism and
the typically developing group. The two language areas activated
at different rates in the participants with autism, rather than
lighting up simultaneously during a task, as in the typical controls.
This finding may help to explain why people with autism seem to
get stuck on single words, (i.e., single details), rather than
being able to comprehend the meaning of a sentence. It is possible
that the signal diminishes when traveling from Wernicke’s
area, the brain site in which there is an initial recognition of
words and subsequently meaning attached to them, before it reaches
Broca’s area, in which it can be transformed into spoken
or written language. It is possible that the “underconnectivity” is
related to the excessive white matter accumulation in the brains
of people with autism, which, rather than doing its job of creating
connections between processing parts of the brain, actually interferes
with the connections because it inhibits transmission of the signals
from one area to another.
Further studies are necessary, but the
authors present an entirely plausible picture of why people with
autism have the deficits they
have, and the “islands of genius” that some have. The
findings offer an explanation, too, for hyperlexia, a condition
in which people are able to read complex text without understandings
its meaning. Taking part in social relationships requires that
connections be made between brain areas responsible for the recognition
of facial expressions, tone of voice, and expressions of emotion.
It may be that these connections are slowed or even lacking in
people with autism.
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