Propofol (2,6-diisopropylphenol) is one of the most popular agents used for induction of anesthesia and long-term sedation, owing to its favorable pharmacokinetic profile, which ensures a rapid recovery even after prolonged administration. A neuroprotective effect, beyond that related to the decrease in cerebral metabolic rate for oxygen, has been shown to be present in many in vitro and in vivo established experimental models of mild/moderate acute cerebral ischemia. Experimental studies on traumatic brain injury are limited and less encouraging. Despite the experimental results and the positive effects on cerebral physiology (propofol reduces cerebral blood flow but maintains coupling with cerebral metabolic rate for oxygen and decreases intracranial pressure, allowing optimal intraoperative conditions during neurosurgical operations), no clinical study has yet indicated that propofol may be superior to other anesthetics in improving the neurological outcome following acute cerebral injury. Therefore, propofol cannot be indicated as an established clinical neuroprotectant per se, but it might play an important role in the so-called multimodal neuroprotection, a global strategy for the treatment of acute injury of the brain that includes preservation of cerebral perfusion, temperature control, prevention of infections, and tight glycemic control.
These results show that propofol, at clinically relevant concentrations, is neuroprotective in models of cerebral ischemia in vitro and in vivo and that it may act by preventing the increase in neuronal mitochondrial swelling.
Recent experimental evidence indicates that erythropoietin (Epo), in addition to its hormonal role in regulating red cell production, operates as a neuroprotective agent. So far, the neuroprotective effect of human recombinant Epo (rhEpo) has been mainly demonstrated in models of cerebral ischemia/hypoxia and in selected in vivo studies of traumatic neuronal injury. To further investigate the potential role of this multifunctional trophic factor in post-traumatic cell death, we examined the protective effects of rhEpo in a newly developed model of mechanical trauma in organotypic hippocampal slices. Organotypic rat hippocampal slices were subjected to traumatic injury by allowing a stylus to impact on the CA1 area with an energy of 6 microJ. Hippocampal damage was identified and measured 24 and 48 h later with the fluorescent dye propidium iodide (PI). In untreated slices, the impact induced a significant increase in the mean hippocampal PI fluorescence, co-localized with the area of impact at 24 h (primary post-traumatic injury) and progressively spread to the whole slice between 24 and 48 h (secondary post-traumatic injury). Addition of rhEpo (1-100 UI/mL) or of the NMDA antagonist MK-801 (30 microM) immediately after the traumatic injury reduced hippocampal damage by approximately 30% when observed 24 h later. At 48 h after trauma, the protective effect of rhEpo was greater (by about 47%) and significantly more pronounced than that of MK-801 (28%). Our results suggest that the neuroprotective activity of rhEpo is particularly effective against delayed, secondary post-traumatic damage. This well tolerated agent could provide a therapeutic benefit in pathologies involving post-traumatic neurodegeneration.
The development of sepsis in patient suffering from traumatic brain injury (TBI) represents a frequent complication that has been associated with worsened global and neurological outcome. In an effort to better characterize the influence of sepsis following TBI, we developed an in vivo model of combined TBI and sepsis in the rat by coupling two validated models: (1) Controlled Cortical Impact (CCI) and (2) Cecal Ligation and Puncture (CLP). Possible contributing effects of sepsis on post-traumatic outcome were evaluated as mortality rate, body weight change, neurological motor (beam balance), cognitive (Morris water maze [MWM] for memory and learning) function, histopathological damage (lesion volume, cell counts in the CA1 and CA3 hippocampal areas), and morphological indices of inflammation (activated microglia and astrocytes) for the 14-day study period. In this study, we produced a mild TBI characterized by a low mortality rate, a transient delay in weight gain, and a transient impairment in motor and cognitive functions. The histological counterpart was represented by a cortical lesion in the area of impact at 14 days post-injury, associated with cell loss in the CA1 and CA3 hippocampal regions, and scarce infiltration of microglia. The superimposition of sepsis on this mild TBI model resulted in worsening of post-injury mortality and weight loss, significant exacerbation of post-injury motor deficit and cognitive impairments, and further exacerbation of neuronal cell death in the CA3 area together with over-expression and activation of microglial cells in the peri-lesional area. Altogether, our findings indicate that sepsis, when superimposed on TBI, exerts a negative effect on the evolution of post-traumatic damage.
The development of sepsis in patient suffering from traumatic brain injury (TBI) represents a frequent complication that has been associated with worsened global and neurological outcome. In an effort to better characterize the influence of sepsis following TBI, we developed an in vivo model of combined TBI and sepsis in the rat by coupling two validated models: (1) Controlled Cortical Impact (CCI) and (2) Cecal Ligation and Puncture (CLP). Possible contributing effects of sepsis on post-traumatic outcome were evaluated as mortality rate, body weight change, neurological motor (beam balance), cognitive (Morris water maze [MWM] for memory and learning) function, histopathological damage (lesion volume, cell counts in the CA1 and CA3 hippocampal areas), and morphological indices of inflammation (activated microglia and astrocytes) for the 14-day study period. In this study, we produced a mild TBI characterized by a low mortality rate, a transient delay in weight gain, and a transient impairment in motor and cognitive functions. The histological counterpart was represented by a cortical lesion in the area of impact at 14 days post-injury, associated with cell loss in the CA1 and CA3 hippocampal regions, and scarce infiltration of microglia. The superimposition of sepsis on this mild TBI model resulted in worsening of post-injury mortality and weight loss, significant exacerbation of post-injury motor deficit and cognitive impairments, and further exacerbation of neuronal cell death in the CA3 area together with over-expression and activation of microglial cells in the peri-lesional area. Altogether, our findings indicate that sepsis, when superimposed on TBI, exerts a negative effect on the evolution of post-traumatic damage.
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