C. P. Lee scite author profile

Traumatic brain injury (TBI) is associated with primary and secondary injury. A thorough understanding of secondary injury will help to develop effective treatments and improve patient outcome. In this study, the GM model of controlled cortical impact injury (CCII) of Lighthall (1988) was used with modification to induce lateral TBI in rats. Forebrain mitochondria isolated from ipsilateral (IH) and contralateral (CH) hemispheres to impact showed a distinct difference. With glutamate + malate as substrates, mitochondria from the IH showed a significant decrease in State 3 respiratory rates, respiratory control indices (RCI), and P/O ratios. This decrease occurred as early as 1 h and persisted for at least 14 days following TBI. The State 3 respiratory rates, RCI, and P/O ratios could be restored to sham values by the addition of EGTA to the assay mixture. A significant amount of Ca2+ was found to be adsorbed to the mitochondria of both the IH and the CH with higher values seen in the IH. The rate of energy-linked Ca2+ transport in the IH was significantly decreased at 6 and 12 h. These data indicate that CCII-induced TBI perturbs cellular Ca2+ homeostasis and results in excessive Ca2+ adsorption to the mitochondrial membrane, which subsequently inhibits the respiratory chain-linked electron transfer and energy transduction.

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Amelioration of Mitochondrial Function by a Novel Antioxidant U-10103 3E Following Traumatic Brain Injury in Rats

Xiong

Peterson

Muizelaar

et al. 1997

Journal of Neurotrauma

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In the present study, a severe traumatic brain injury (TBI) was produced over the right parietal cortex of rats using the controlled cortical impact injury (CCII) model. TBI perturbed calcium homeostasis and impaired electron transfer and energy coupling activities of forebrain mitochondria isolated from injured hemispheres with a maximal injury at 12-72 h. Efficacy of the blood-brain barrier penetrating antioxidant U-101033E on TBI-induced mitochondrial impairment was evaluated. In the dose-response experiment, two i.v. boluses (vehicle or 1-10 mg/kg of U-101033E) were administered at 5 min and 2h post-TBI. Forebrain mitochondria from each hemisphere were examined at 12 h post-injury. With respect to forebrain mitochondrial dysfunction, the drug showed a bell-shaped dose-response curve with an optimal dose of 3 mg/kg (n = 5, p < 0.05 vs. vehicle). In the time-course experiment, two i.v. boluses of 3 mg U-101033E/kg (the optimal dose) were given at 5 min and 2 h post-injury and forebrain mitochondria were examined at 6 h-14 days post-injury. U-101033E significantly restored electron transfer, energy coupling capacity, and Ca2+ transport capacity during 6 h to 14 days post-injury. Our data indicate that the antioxidant U-101033E administered post-injury at proper dosage can effectively restore TBI-induced mitochondrial dysfunction and support the contention that oxidative stress plays an important role in the pathogenesis of TBI.

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Kearns‐sayre syndrome: Biochemical studies of mitochondrial metabolism

Martens

Peterson

Lee

et al. 1988

Annals of Neurology

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Examination of oxidative metabolism in mitochondria isolated from quadriceps skeletal muscle biopsy specimens of 4 patients with Kearns-Sayre syndrome has shown that the mitochondria were tightly coupled, with maximal respiratory rates depending on the presence of adenosine diphosphate (ADP), Ca2+, or uncoupler. The state 3 respiratory rates with nicotinamide adenine dinucleotide (NAD)-linked substrates and succinate were much lower than those of control subjects. The cytochrome oxidase activities (measured with ascorbate + phenazine methosulfate as substrates) were also decreased, but this segment of the respiratory chain was not rate-limiting for succinate or NAD-linked substrate oxidation. Analyses of the steady-state reduction kinetics of the respiratory chain carriers revealed that the rate-limiting step of the impaired respiration with succinate or NAD-linked substrates lies between the c cytochromes and cytochrome oxidase. Measurement of the total substrate-reducible (at anaerobiosis) and chemically reducible levels of the cytochromes in mitochondria from 3 patients showed a severe deficiency of cytochrome a + a3 and an excess of the c cytochromes. To our knowledge, this is the first instance in which a mitochondrial electron transfer defect and cytochrome oxidase deficiency has been shown to be associated with an excess of the c cytochromes.

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Defective oxidative metabolism of myodystrophic skeletal muscle mitochondria

et al. 1979

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A small-scale procedure for preparing tightly coupled intact skeletal muscle mitochondria from myodystrophic (myd/myd) mice is described. Mitochondrial preparations derived from heart, liver, and skeletal muscle of myd/myd and their littermate (+/?) controls are characterized with respect to their cytochrome content and their oxidative and phosphorylative capacities. Our data indicate that there is an impairment in the NADH CoQ region of the respiratory chain of myodystrophic skeletal muscle mitochondria. Both heart and liver mitochondria of myd/myd exhibited normal activities of respiratory chain-linked oxidative phosphorylation.

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Mitochondrial dysfunction after experimental and human brain injury and its possible reversal with a selective N-type calcium channel antagonist (SNX-lll)

Verweij

Muizelaar

Viñas

et al. 1997

Neurological Research

133

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C. P. Lee

Mitochondrial Dysfunction and Calcium Perturbation Induced by Traumatic Brain Injury

Amelioration of Mitochondrial Function by a Novel Antioxidant U-10103 3E Following Traumatic Brain Injury in Rats

Kearns‐sayre syndrome: Biochemical studies of mitochondrial metabolism

Defective oxidative metabolism of myodystrophic skeletal muscle mitochondria

Mitochondrial dysfunction after experimental and human brain injury and its possible reversal with a selective N-type calcium channel antagonist (SNX-lll)

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