Oligodendrocyte vulnerability following traumatic brain injury in rats.

Experimental and clinical findings demonstrate that traumatic brain injury (TBI) results in injury to both gray and white matter structures. The purpose of this study was to document patterns of oligodendrocyte vulnerability to TBI. Sprague Dawley rats underwent sham operated procedures or moderate fluid percussion brain injury. Quantitative immunohistochemical analysis was performed on animals perfusion-fixed at 3 (n=9) or 7 (n=9) days post-surgery. Within the ipsilateral external capsule and corpus callosum, numbers of APC-CC1 immunoreactive oligodendrocytes were significantly decreased at 3 or 7 days post-TBI compared to sham rats (p<0.03). At both posttraumatic survival periods, double-labeling studies indicated that oligodendrocytes showed increased Caspase 3 activation compared to sham. These data demonstrate regional patterns of oligodendrocyte vulnerability after TBI and that oligodendrocyte cell loss may be due to Caspase 3-mediated cell death mechanisms. Further studies are needed to test therapeutic interventions that prevent trauma-induced oligodendrocyte cell death, subsequent demyelination and circuit dysfunction.

OLIGODENDROCYTE VULNERABILITY FOLLOWING TRAUMATIC BRAIN INJURY IN RATS: EFFECT OF MODERATE HYPOTHERMIA.

The purpose of this study was to document patterns of oligodendrocyte vulnerability to TBI and determine whether posttraumatic hypothermia prevents oligodendrocyte cell loss. Sprague Dawley rats underwent moderate fluid percussion brain injury. Thirty minutes after TBI, brain temperature was reduced to 33°C for 4 hrs or maintained at normothermic levels (37°C). Animals were perfusion-fixed for quantitative immunohistochemical analysis at 3 (n=9) or 7 (n=9) days post-TBI. Within the cerebral cortex, external capsule and corpus callosum, numbers of APC-CC1 immunoreactive oligodendrocytes at 3 and 7 days following TBI were significantly decreased compared to sham operated rats (p<0.02). Double-labeling studies showed that vulnerable oligodendrocytes expressed increased Caspase 3 activation compared to sham. Posttraumatic hypothermia significantly reduced the number of CC1 positive oligodendrocytes lost after normothermia TBI in white matter tracts (p<0.01). This model of TBI leads to quantifiable regional patterns of oligodendrocyte vulnerability. Posttraumatic hypothermia protects oligodendrocytes by interfering with Caspase 3-mediated cell death mechanisms. Therapeutic hypothermia may improve functional outcome by attenuating trauma-induced oligodendrocyte cell death, subsequent demyelination and circuit dysfunction.