Caspase activation is the first committed step in the programmed-cell death cascade, a tightly regulated sequence of cellular and molecular events that systematically leads to the death of a cell. Increasing evidence suggests that activation of caspases produces secondary neuronal death after traumatic brain injury in experimental models. Importantly, pharmacologic and molecular inhibitors of the caspases attenuate programmed cell-death after cerebral ischemia and traumatic brain injury in rodents, although reports are limited. Our hypothesis is that activation of caspases after traumatic brain injury contributes to neuronal death and that inhibiting induction and/or activity of caspases reduces secondary neuropathologic injury after traumatic brain injury.
Specific aims to address this hypothesis will: 1) characterize the temporal, regional, cellular, and subcellular expression and activity of Caspase-3 using a rat model that mimics severe human traumatic brain injury, 2) examine the upstream regulation the upstream regulation of caspases by cytosolic cytochrome c and nitric oxide after severe traumatic brain injury in rats and mice, 3) test the effects of several pharmacologic caspase inhibitors on neuropathologic and functional outcome after severe traumatic brain injury in rats, 4) examine the expression of other caspases (Caspases-2 and -9) after severe traumatic brain injury in rats, and 5) examine the expression of currently identified caspase (Caspases -2 -9) after severe traumatic brain injury in rats, and 5) examine the expression of currently identified caspases (Caspases 1-10) after severe traumatic brain injury in humans. Traumatic brain injury is a major cause of mortality and morbidity in adults and children in the United States. Secondary brain injury contributes to mortality and morbidity in adults and children in the United States. Secondary rain injury contributes to mortality and morbidity and currently only few, non-specific therapies are available. Caspase-mediated programmed-cell death may contribute to secondary neuronal death after traumatic brain injury in experimental models and in humans as well. Pharmacologic treatment strategies aimed at reducing caspase induction and/or activation to subsequently reduce secondary neuronal death will be tested in models of traumatic brain injury in vivo. If caspase inhibitors reduce programmed-cell death and improve neurologic outcome after severe traumatic brain injury in vivo, a novel, clinically relevant treatment strategy for victims of severe head injury will be available.
Wallisch, Jessica S; Simon, Dennis W; Bay?r, Hülya et al. (2017) Cerebrospinal Fluid NLRP3 is Increased After Severe Traumatic Brain Injury in Infants and Children. Neurocrit Care 27:44-50 |
Newell, Elizabeth; Shellington, David K; Simon, Dennis W et al. (2015) Cerebrospinal Fluid Markers of Macrophage and Lymphocyte Activation After Traumatic Brain Injury in Children. Pediatr Crit Care Med 16:549-57 |
Manole, Mioara D; Tehranian-DePasquale, Roya; Du, Lina et al. (2011) Unmasking sex-based disparity in neuronal metabolism. Curr Pharm Des 17:3854-60 |
Smith, Craig M; Chen, Yaming; Sullivan, Mara L et al. (2011) Autophagy in acute brain injury: feast, famine, or folly? Neurobiol Dis 43:52-9 |
Au, Alicia K; Bayir, Hülya; Kochanek, Patrick M et al. (2010) Evaluation of autophagy using mouse models of brain injury. Biochim Biophys Acta 1802:918-23 |
Chu, Charleen T; Plowey, Edward D; Dagda, Ruben K et al. (2009) Autophagy in neurite injury and neurodegeneration: in vitro and in vivo models. Methods Enzymol 453:217-49 |
Du, Lina; Hickey, Robert W; Bayir, Hülya et al. (2009) Starving neurons show sex difference in autophagy. J Biol Chem 284:2383-96 |
Fink, Ericka L; Lai, Yichen; Zhang, Xiaopeng et al. (2008) Quantification of poly(ADP-ribose)-modified proteins in cerebrospinal fluid from infants and children after traumatic brain injury. J Cereb Blood Flow Metab 28:1523-9 |
Lai, Yichen; Hickey, Robert W; Chen, Yaming et al. (2008) Autophagy is increased after traumatic brain injury in mice and is partially inhibited by the antioxidant gamma-glutamylcysteinyl ethyl ester. J Cereb Blood Flow Metab 28:540-50 |
Clark, Robert S B; Bayir, Hulya; Chu, Charleen T et al. (2008) Autophagy is increased in mice after traumatic brain injury and is detectable in human brain after trauma and critical illness. Autophagy 4:88-90 |
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