Abstract
Traumatic brain injury (TBI) from a blow to the head is often associated with complex patterns of brain abnormalities that accompany deficits in cognitive and motor function. Previously we reported that a long-term consequence of TBI, induced with a closed-head injury method modelling human car and sporting accidents, is neuronal hyper-excitation in the rat sensory barrel cortex that receives tactile input from the face whiskers. Hyper-excitation occurred only in supra-granular layers and was stronger to complex than simple stimuli. We now examine changes in the immediate aftermath of TBI induced with same injury method. At 24 hours post-trauma significant sensorimotor deficits were observed and characterisation of the cortical population neuronal responses at that time revealed a depth-dependent suppression of neuronal responses, with reduced responses from supragranular layers through to input layer IV, but not in infragranular layers. In addition, increased spontaneous firing rate was recorded in cortical layers IV and V. We postulate that this early post-injury suppression of cortical processing of sensory input accounts for immediate post-trauma sensory morbidity and sets into train events that resolve into long-term cortical hyper-excitability in upper sensory cortex layers that may account for long-term sensory hyper-sensitivity in humans with TBI.
Highlights
Traumatic brain injury (TBI) results when an external force damages the brain
Method exhibited significant behavioural deficits 24 hours after the treatment. For both the rotarod and beam walk tasks there were no difference in performance between sham and TBI groups pretrauma, but at 24 hours post-surgery these 7 TBI animals showed a significant decrease in rotarod scores (Fig. 2A, TBI = 54616%, n = 7; Sham = 9861%, n = 6; Student’s two-tailed t test, p,0.05) and in beam walk scores (Fig. 2B, TBI = 1.4260.57, n = 4; Sham = 0.0060.00, n = 6; Student’s two-tailed t test, p,0.05)
Absence of Changes in Temporal Metrics Following TBI In contrast to these TBI-induced changes in firing rate, we found that there were no systematic changes in any temporal measures of neuronal responses to any of the three stimuli
Summary
Traumatic brain injury (TBI) results when an external force damages the brain. But include glutamatergic excitotoxicity [4,5,6], metabolic perturbations [7,8], ion imbalance [9,10], inflammation [11,12] and oxidative stress [13,14]. These short-term changes in the cerebral environment appear to induce cortical plasticity and remodelling which can manifest as long-term behavioural derangements [15]
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