Epilepsy linked to brain volume, thickness differences: Study
Epilepsy, a disorder in which nerve cell activity in the
brain is disturbed, is linked to brain volume and thickness differences,
according to a study.
Epilepsy is a neurological disorder that affects 0.6-1.5% of
the global population, comprising many different syndromes and conditions, and
defined by a tendency for seizures.
The research was led by UCL and the Keck School of Medicineof USC.
The largest-ever neuroimaging study of people with epilepsy
shows that epilepsy involves more widespread physical differences than
previously assumed, even in types of epilepsy that are typically considered to
be more benign if seizures are under control.
The brain abnormalities the researchers identified were
subtle, and have not yet been implicated in any loss of function.
"We found differences in brain matter even in common
epilepsies that are often considered to be comparatively benign. While we
haven't yet assessed the impact of these differences, our findings suggest
there's more to epilepsy than we realise, and now we need to do more research
to understand the causes of these differences," said the study's lead
author, Professor Sanjay Sisodiya.
The study was conducted by the global ENIGMA-Epilepsyconsortium, part of ENIGMA which is headquartered at the Keck School of
Medicine of USC, and pooled data from 24 research centres across Europe, North
and South America, Asia and Australia. Structural brain measures were extracted
from MRI brain scans of 2,149 people with epilepsy, and compared with 1,727
healthy controls. The epilepsy group was analysed together for common patterns,
and divided into four subgroups to identify differences.
The team found reduced grey matter thickness in parts of the
brain's outer layer (cortex) and reduced volume in subcortical brain regions in
all epilepsy groups when compared to the control group. Reduced volume and
thickness were associated with longer duration of epilepsy.
Notably, people with epilepsy exhibited lower volume in theright thalamus - a region which relays sensory and motor signals, and haspreviously only been associated with certain epilepsies - and reduced thickness
in the motor cortex, which controls the body's movement.
These patterns were even present among people with
idiopathic generalised epilepsies, a type of epilepsy characterised by a lack
of any noticeable changes in the brain, such that typically an experienced
neuroradiologist would not be able to see anything unusual in their brain
scans.
"Some of the differences we found were so subtle they
could only be detected due to the large sample size that provided us with very
robust, detailed data," said the study's first author, Dr ChristopherWhelan.
The researchers also identified differences between the
subgroups, which they say must reflect differences in underlying biology, as
suggested by recent genetic studies.
"We have identified a common neuroanatomical signature
of epilepsy, across multiple epilepsy types. We found that structural changes
are present in multiple brain regions, which informs our understanding of
epilepsy as a network disorder," Dr Whelan said.
The authors say their findings need to be followed up by
longitudinal and genetic studies which could clarify the cause of the
structural differences.
"From our study, we cannot tell whether the structural
brain differences are caused by seizures, or perhaps an initial insult to the
brain, or other consequences of seizures - nor do we know how this might
progress over time. But by identifying these patterns, we are developing a
neuroanatomical map showing which brain measures are key for further studies that
could improve our understanding and treatment of the epilepsies," said
Professor Sisodiya.
The findings have been published in the journal Brain.
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