Apoptotic neurodegeneration following trauma is markedly enhanced in the immature brain.

Age dependency of apoptotic neurodegeneration was studied in the developing rat brain after percussion head trauma. In 7-day-old rats, mechanical trauma, applied by means of a weight drop device, was shown to trigger widespread cell death in the hemisphere ipsilateral to the trauma site, which first appeared at 6 hours, peaked at 24 hours, and subsided by 5 days after trauma. Ultrastructurally, degenerating neurons displayed features consistent with apoptosis. A decrease of bcl-2 in conjunction with an increase of c-jun mRNA levels, which were evident at 1 hour after trauma and were accompanied by elevation of CPP 32-like proteolytic activity and oligonucleosomes in vulnerable brain regions, confirmed the apoptotic nature of this process. Severity of trauma-triggered apoptosis in the brains of 3- to 30-day-old rats was age dependent, was highest in 3- and 7-day-old animals, and demonstrated a subsequent rapid decline. Adjusting the mechanical force in accordance with age-specific brain weights revealed a similar vulnerability profile. Thus, apoptotic neurodegeneration contributes in an age-dependent fashion to neuropathological outcome after head trauma, with the immature brain being exceedingly vulnerable. These results help explain unfavorable outcomes of very young pediatric head trauma patients and imply that, in this group, an antiapoptotic regimen may constitute a successful neuroprotective approach.

N-Methyl-D-aspartate antagonists and apoptotic cell death triggered by head trauma in developing rat brain.

Morbidity and mortality from head trauma is highest among children. No animal model mimicking traumatic brain injury in children has yet been established, and the mechanisms of neuronal degeneration after traumatic injury to the developing brain are not understood. In infant rats subjected to percussion head trauma, two types of brain damage could be characterized. The first type or primary damage evolved within 4 hr and occurred by an excitotoxic mechanism. The second type or secondary damage evolved within 6-24 hr and occurred by an apoptotic mechanism. Primary damage remained localized to the parietal cortex at the site of impact. Secondary damage affected distant sites such as the cingulate/retrosplenial cortex, subiculum, frontal cortex, thalamus and striatum. Secondary apoptotic damage was more severe than primary excitotoxic damage. Morphometric analysis demonstrated that the N-methyl-D-aspartate receptor antagonists 3-(2-carboxypiperazin-4-yl)-propyl-1-phosphonate and dizocilpine protected against primary excitotoxic damage but increased severity of secondary apoptotic damage. 2-Sulfo-alpha-phenyl-N-tert-butyl-nitrone, a free radical scavenger, did not affect primary excitotoxic damage but mitigated apoptotic damage. These observations demonstrate that apoptosis and not excitotoxicity determine neuropathologic outcome after traumatic injury to the developing brain. Whereas free radical scavengers may prove useful in therapy of head trauma in children, N-methyl-D-aspartate antagonists should be avoided because of their propensity to increase severity of apoptotic damage.

Modeling pediatric head trauma: mechanisms of degeneration and potential strategies for neuroprotection.

We have developed a model for head trauma in infant rats in an attempt to study mechanisms of neurodegeneration in the developing brain and were able to morphologically characterize two distinct types of brain damage. The first type or primary damage evolved within 4 hrs after trauma and occurred by an excitotoxic mechanism. The second type or secondary damage evolved within 6-24 hrs and occurred by an apoptotic mechanism. Primary damage remained localized to the parietal cortex at the site of impact. Secondary damage affected distant sites such as the cingulate/retrosplenial cortex, subiculum, frontal cortex, thalamus, hippocampal dentate gyrus and striatum. Histological evidence of delayed cell death was preceded by decrease of bcl-2- in conjunction with increase of c-jun-mRNA-levels, already evident at 1 hr after trauma. Increase of CPP32-like activity and elevated concentrations of oligonucleosomes in affected brain regions represented additional findings to indicate that this secondary disseminated degenerative reaction is apoptotic in nature. At the age of 7 days, secondary apoptotic damage was more severe than primary excitotoxic damage, but its severity declined with increasing age. In 7-days-old rats, NMDA antagonists protected against primary excitotoxic damage but increased severity of secondary apoptotic damage whereas the free radical scavenger SPBN, the tumor necrosis factor (TNF) inhibitor pentoxifylline and the antioxidant N-acetylcystein mitigated apoptotic damage. These findings demonstrate that in the developing rat brain apoptosis and not excitotoxicity determines neuropathologic outcome following head trauma. Whereas radical scavengers and TNF-inhibitors may prove useful in treatment of pediatric head trauma, great caution should be applied in regards to the use of NMDA antagonists because of the inherent risk of apoptosis promotion.