Heme Regulation in Traumatic Brain Injury: Relevance to the Adult and Developing Brain

Chang, Edward F.; Claus, Catherine P.; Vreman, Hendrik J.; Wong, Ronald J.; Noble-Haeusslein, Linda J.

doi:10.1038/sj.jcbfm.9600147

“…119 Iron reacts with hydrogen peroxide to form hydroxyl radicals ( Figure 1) and with lipids to generate alkoxy and peroxy radicals. As discussed in the previous section, the immature brain may be especially vulnerable to the adverse effects of oxidative stress, making iron a potential target for therapy after trauma to the immature brain.…”

Section: Iron Accumulation In the Injured Brainmentioning

confidence: 99%

“…124 Iron accumulation after injury to the developing brain. Iron accumulates in the developing brain after TBI 119 (Figure 2). However, it is unclear how such accumulation may modulate pathogenesis.…”

Section: Iron Accumulation In the Injured Brainmentioning

confidence: 99%

Traumatic injury to the immature brain: Inflammation, oxidative injury, and iron-mediated damage as potential therapeutic targets

Potts

¹

,

Koh

²

,

Whetstone

³

et al. 2006

NeuroRX

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Summary: Traumatic brain injury (TBI) is the leading cause of morbidity and mortality among children and both clinical and experimental data reveal that the immature brain is unique in its response and vulnerability to TBI compared to the adult brain. Current therapies for pediatric TBI focus on physiologic derangements and are based primarily on adult data. However, it is now evident that secondary biochemical perturbations play an important role in the pathobiology of pediatric TBI and may provide specific therapeutic targets for the treatment of the head-injured child. In this review, we discuss three specific components of the secondary pathogenesis of pediatric TBIinflammation, oxidative injury, and iron-induced damage -and potential therapeutic strategies associated with each. The inflammatory response in the immature brain is more robust than in the adult and characterized by greater disruption of the blood-brain barrier and elaboration of cytokines. The immature brain also has a muted response to oxidative stress compared to the adult due to inadequate expression of certain antioxidant molecules. In addition, the developing brain is less able to detoxify free iron after TBI-induced hemorrhage and cell death. These processes thus provide potential therapeutic targets that may be tailored to pediatric TBI, including anti-inflammatory agents such as minocycline, antioxidants such as glutathione peroxidase, and the iron chelator deferoxamine.

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“…Iron accumulates in the developing brain after TBI 119 ( Figure 2). However, it is unclear how such accumulation may modulate pathogenesis.…”

mentioning

confidence: 99%

Traumatic injury to the immature brain: Inflammation, oxidative injury, and iron-mediated damage as potential therapeutic targets

Potts

¹

,

Koh

²

,

Whetstone

³

et al. 2006

View full text Add to dashboard Cite

Summary: Traumatic brain injury (TBI) is the leading cause of morbidity and mortality among children and both clinical and experimental data reveal that the immature brain is unique in its response and vulnerability to TBI compared to the adult brain. Current therapies for pediatric TBI focus on physiologic derangements and are based primarily on adult data. However, it is now evident that secondary biochemical perturbations play an important role in the pathobiology of pediatric TBI and may provide specific therapeutic targets for the treatment of the head-injured child. In this review, we discuss three specific components of the secondary pathogenesis of pediatric TBIinflammation, oxidative injury, and iron-induced damage -and potential therapeutic strategies associated with each. The inflammatory response in the immature brain is more robust than in the adult and characterized by greater disruption of the blood-brain barrier and elaboration of cytokines. The immature brain also has a muted response to oxidative stress compared to the adult due to inadequate expression of certain antioxidant molecules. In addition, the developing brain is less able to detoxify free iron after TBI-induced hemorrhage and cell death. These processes thus provide potential therapeutic targets that may be tailored to pediatric TBI, including anti-inflammatory agents such as minocycline, antioxidants such as glutathione peroxidase, and the iron chelator deferoxamine.

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“…Potential pathways for an ROS-induced alteration of the glutathione homeostasis include direct oxidation of GSH by different (possibly secondarily formed) ROS and an increased formation of hydrogen peroxide that is degraded via the GSH-consuming enzyme glutathione peroxidase [27] . Pathophysiological mechanisms that may be responsible for increased cellular ROS formation include augmented leakage of superoxide from the mitochondrial electron transport chain, enhanced activity of xanthine or NADPH oxidase, release of redox-active iron via breakdown of hemoglobin, and activation of the arachidonic acid cascade [28][29][30] . ROS sources, however, may vary over the posttraumatic period.…”

Section: Discussionmentioning

confidence: 99%

Screening for the Formation of Reactive Oxygen Species and of NO in Muscle Tissue and Remote Organs upon Mechanical Trauma to the Mouse Hind Limb

Kerkweg

¹

,

Schmitz²,

Groot³

2006

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Background: Until now, no systematic surveys exist in the literature on the early local and systemic generation of reactive oxygen species and of nitric oxide in response to muscle crush injury. Therefore, this study aims to evaluate the formation of reactive oxygen species and nitric oxide in different tissues (injured and contralateral muscle, liver, kidney, spleen and blood) that is induced by closed muscle trauma. Methods: 5, 45 and 180 min after induction of blunt trauma to the mouse gastrocnemius muscle, animals were sacrificed, tissues harvested and homogenized, and analyzed for their content of glutathione, nitrate and thiobarbituric acid-reactive substances. Results: The local formation of reactive oxygen species in the injured muscle started immediately upon induction of the mechanical trauma as indicated by changes in the glutathione redox balance. Liver and kidney did not show any response to trauma; however, a marked and immediate increase in the splenic nitrate content was detected, thus suggesting a specific nitric oxide-dependent response of splenic cells to injury. Conclusion: We conclude that immediately after the induction of trauma a formation of reactive oxygen species takes place at the site of crush injury. This might constitute the basis of further damage to the injured tissue by free radical-dependent mechanisms. The immediate formation of nitric oxide within the spleen upon muscle crush appears to represent a specific signalling mechanism of the body in response to distant organ injury.

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Heme Regulation in Traumatic Brain Injury: Relevance to the Adult and Developing Brain

Cited by 57 publications

References 180 publications

Traumatic injury to the immature brain: Inflammation, oxidative injury, and iron-mediated damage as potential therapeutic targets

Traumatic injury to the immature brain: Inflammation, oxidative injury, and iron-mediated damage as potential therapeutic targets

Traumatic injury to the immature brain: Inflammation, oxidative injury, and iron-mediated damage as potential therapeutic targets

Screening for the Formation of Reactive Oxygen Species and of NO in Muscle Tissue and Remote Organs upon Mechanical Trauma to the Mouse Hind Limb

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