The speed of information traveling within a child’s brain may signal who needs the most help after a head injury.
Children with delayed visual perception as a result of serious head injuries may end up with structural changes in their brains that interrupt normal development, a new Keck School of Medicine of the University of Southern California (USC) study shows.
The USC scientists said that the finding is the first step to creating targeted treatments for a subpopulation of children with traumatic brain injuries, the leading cause of disability among the young. The goal is to save their brains from further deterioration as a consequence of an initial hard bump, blow or jolt to the head.
USC researchers and their colleagues examined the brain scans of 21 children in Los Angeles County who fell from skateboards, scooters and bikes, or were hit by a car either as a passenger or as a pedestrian. Study participants were eight to 18 years of age when they visited a paediatric intensive care unit for moderate-to-severe traumatic brain injury. 20 healthy children who had not had a brain injury served as the control group.
‘We found that children who had delayed information transfer times between the two brain hemispheres had widespread regions of white matter disorganisation and progressive loss of white matter volume,’ said Emily Dennis, lead author of the study, and a post-doctoral scholar at the Keck School of Medicine.
‘In children, this disruption to myelin – the insulation that facilitates information transfer – is compounded because the brain is still maturing. Myelination typically continues beyond age 30.’
The preliminary study, published in Neurology, the medical journal of the American Academy of Neurology, found that children who took more than 18 milliseconds to transfer information between the brain hemispheres did not recover as well from traumatic brain injury compared to their similarly injured counterparts.
More than 55 per cent of traumatic brain injuries among children 0 to 14 years of age are caused by falls, according to the Centres for Disease Control and Prevention.
‘Finding this potential biomarker may help us identify patients who are at risk for a more prolonged recovery,’ explained Dennis, post-doctoral scholar at the Imaging Genetics Centre.
‘If we can identify the children who will take longer to recover from traumatic brain injury, we may be able to develop interventions that can be used after they leave the hospital but before their continued loss of white matter.’
Scientists took diffusion-weighted MRI scans of the young study participants two to five months after their injury and again about a year later. The children took thinking and memory skills tests. They also had electroencephalograms (EEGs) done while they completed a computerised pattern-matching task, enabling researchers to examine how quickly information was transferred from one brain hemisphere to the other.
Researchers tracked brain activity as it transferred information through the hemispheres via the corpus callosum, a bridge resembling a mohawk in the middle of the brain with extensions into both hemispheres.
During the initial evaluation, half of the injured kids had a transfer time of more than 18 milliseconds, while the other half were in the normal range between seven to 10 milliseconds – more than 30 times the speed of the blink of an eye.
About a year later, the group of children whose information transfers took the longest also experienced a loss in white matter and disorganisation in the wiring that connects the different regions of the brain. However, the group whose information traveled at a normal speed showed no significant difference from the healthy control group when tested for their memory-processing speed and their ability to control inhibition.
‘The slow-transfer group started off with worse white matter integrity and had poorer cognitive function across a range of domains, whether it was on the brain processing speed or self-control,’ Dennis said.
‘The problems get worse as these kids age.’