Effect of normabaric hyperoxia treatment on neuronal damage following fluid percussion injury in the striatum of mice: A morphological approach.

Traumatic brain injury (TBI) causes significant mortality in most developing countries worldwide. At present, it is imperative to identify a treatment to address the devastating post-TBI consequences. Therefore, the present study has been performed to assess the specific effect of immediate exposure to normabaric hyperoxia (NBO) after fluid percussion injury (FPI) in the striatum of mice. To execute FPI, mice were anesthetised and sorted into (i) a TBI group, (ii) a sham group without injury and (iii) a TBI group treated with immediate exposure to NBO for 3 h. Afterwards, brains were harvested for morphological assessment. The results revealed no changes in morphological and neuronal damage in the sham group as compared to the TBI group. Conversely, the TBI group showed severe morphological changes as well as neuronal damage as compared to the TBI group exposed to NBO for 3 h. Interestingly, our findings also suggested that NBO treatment could diminish the neuronal damage in the striatum of mice after FPI. Neuronal damage was evaluated at different points of injury and the neighbouring areas using morphology, neuronal apoptotic cell death and pan-neuronal markers to determine the complete neuronal structure. In conclusion, immediate exposure to NBO following FPI could be a potential therapeutic approach to reduce neuronal damage in the TBI model.

Effects of fluid percussion injury on survival and differentiation of human embryonic neural stem cells in rats / 中国康复理论与实践

@#ObjectiveTo investigate the effects of fluid percussion injury(FPI) on survival and differentiation of transplanted human embryonic neural stem cells (HNSCs) in rats. MethodsThe HNSCs were separated from the cerebral cortex of the 8-week-old fetal and were cultured in DMEM/F12 combinated with EGF, bFGF and LIF. The rat models of FPI were made with fluid percussion system. The HNSCs labeled with BrdU were transplanted into the injured zone 24 hours after brain injury, then the rats were killed at the 1st and 4th week post-transplanted stages, and the brain slices were stained with immunocytochemistry. The GFAP, MAP-2, and BrdU positive cells were investigated.ResultsThe transplanted HNSCs migrated to the whole brain, and differentiated into GFAP and MAP-2 positive cells. MAP-2 positive cells were observed at 1 week post-transplanted stage, on the contrary, more GFAP positive cells were discovered 4 weeks after transplantation. Part of the HNSCs migrated to the choroids plexus of the lateral ventricle and microvessels. ConclusionThe transplanted HNSCs survive in the injured zone, and differentiate into astrocytes gradually during the recovery. The host devours part of the HNSCs.

Laser Doppler Estimated Cortical Hemodynamic Changes of Modified Fluid-Percussion Injury Model for Head Trauma Including Hyperosmolar Agent Infusion

A study of cortical blood flow changes using laser Doppler was conducted in seven head injuried rats with subsequent intravenous administration of mannitol. Cortical blood flow after head trauma by the fluid-percussion model was decreased in 6 cases and initially increased and then decreased in 1 case. Cortical blood flows were dramatically increased about three to six times after intravenous administration of mannitol. These results suggest that the modified fluid-percussion cortical injury system is more stable and consistent than the old fluid-percussion injury model. It, therefore, seems applicable to be used as experimental models for head trauma.