Mitochondrial metabolism following traumatic brain injury in rats

Although a number of studies of traumatic brain injury have implicated mitochondrial dysfunction as a cause of altered posttraumatic energy metabolism, no studies to date have isolated mitochondria and measured their respiratory capacity following trauma. The present study sought to determine whether mitochondrial capacity for oxidative phosphorylation is adversely affected by fluid-percussion-induced traumatic brain injury in rats. Prior to brain injury, the mitochondrial respiratory control ratio was 4.3 +/- 0.2 and the ratio of nmoles of ADP phosphorylated per natom oxygen consumed (ADP/O ratio) was 2.66 +/- 0.09. After injury (2.8 atm; t = 4 h), there were slight but not significant alterations in ADP/O ratio (2.41 +/- 0.07) and state 3 respiratory rate (ADP stimulated); however, there were no changes in the respiratory control ratio. These data suggest that traumatic brain injury, unlike ischemia, does not cause uncoupling of ATP synthesis from respiration, and that brain mitochondria are quite resistant to trauma-induced injury.     

Local mitochondrial function following traumatic brain injury in rats

The effect of lateral fluid percussion injury on mitochondrial function in the rat brain was investigated by quantitative imaging of changes in the regional activity of succinate dehydrogenase (SDH), a mitochondrial enzyme of the tricarboxylic acid cycle for adenosine triphosphate production. Regional SDH was measured in the frontal, parietal, temporal, and occipital cortices, CA1 and CA2-3 of the hippocampus, thalamus, corpus callosum, caudate/putamen, and cerebellum 1 hour and 72 hours after low, medium, and high pressure injury. No regional difference between the hemispheres in the activity of SDH was observed in the sham group. The hippocampus showed high SDH activity. The CA2-3 regions showed the highest activity among the regions examined. The corpus callosum, which is white matter, showed the lowest. One hour after low pressure fluid percussion injury, only the frontal lobe showed significantly lower SDH activity than the sham control in the ipsilateral hemisphere, whereas after 72 hours SDH activity was significantly lower in the frontal, parietal, and temporal lobes. SDH activity was significantly lower in the frontal, parietal, and temporal lobes in the medium and high pressure injury groups than in the sham control 1 hour after injury, and SDH activity in the CA1 and CA2-3 of the hippocampus was significantly decreased 72 hours after injury. No decrease in SDH activity was observed in any region of the contralateral hemisphere either 1 hour or 72 hours after injury. Mitochondrial dysfunction of the ipsilateral cortex and hippocampus following fluid percussion injury is correlated with the severity of injury and advances with time after injury. The results suggest that progression of mitochondrial dysfunction is associated with secondary bioenergetic deterioration.     

Effect of Xingnaojing injection on cerebral edema and blood-brain barrier in rats following traumatic brain injury

Objective：To explore the effects of Xingnaojing injection on cerebral edema and blood-brain barrier （BBB） in rats following traumatic brain injury （TBI）.Methods： A total of 108 adult male Sprague-Dawley rats were used as subjects and randomly assigned to three groups：sham-operation,TBI and Xingnaojing injection was set up by the improved device of Feeney＇s weightcontent and BBB permeability expressed as Evans blue content were measured at 1, 3, 5 and 7 days after surgery.Results： In sham-operation group, brain water content and Evans blue content in brain tissue were 78.97%±1.22%and 5.13μg±0.71μg. Following TBI, water content in brain tissue was increased significantly at 1, 3, 5 and 7 days （83.49%±0.54%, 82.74%±0.72%, 80.22%±0.68%, 79.21%±0.60%）, being significantly higher than that in sham operation group （P〈0.05）. Evans blue content was increased in TBI group （16.54 μg±0.60 μg, 14.92μg±0.71μg, 12.44 μg ±0.92μg, 10.14μg±0.52 μg） as compared with sham-operation group（P〈0.05）. After treatment with Xingnaojing injection, brain water content decreased as compared with TBI group （81.91%±1.04%, 80.38%±0.72%, 79.54%±0.58%,78.60%±0.77%, P〈0.05）. Xingnaojing injection also reduced the leakage of BBB as compared with TBI group （15.11 μg± 0.63 μg, 13.62 μg±0.85μg, 10.06 μg±0.67 μg, 9.54 μg±0.41 μg,P〈0.05）.Conclusion： Xingnaojing injection could alleviate cerebral edema following TBI via reducing permeability ofBBB.     

Effect of Xingnaojing injection on cerebral edema and blood-brain barrier in rats following traumatic brain injury

Objective:To explore the effects of Xingnaojing injection on cerebral edema and blood-brain barrier (BBB) in rats following traumatic brain injury (TBI).Methods: A total of 108 adult male Sprague-Dawley rats were used as subjects and randomly assigned to three groups:sham-operation,TBI and Xingnaojing injection was set up by the improved device of Feeney's weightcontent and BBB permeability expressed as Evans blue content were measured at 1, 3, 5 and 7 days after surgery.Results: In sham-operation group, brain water content and Evans blue content in brain tissue were 78.97%±1.22%and 5.13μg±0.71μg. Following TBI, water content in brain tissue was increased significantly at 1, 3, 5 and 7 days (83.49%±0.54%, 82.74%±0.72%, 80.22%±0.68%, 79.21%±0.60%), being significantly higher than that in sham operation group (P<0.05). Evans blue content was increased in TBI group (16.54 μg±0.60 μg, 14.92μg±0.71μg, 12.44 μg ±0.92μg, 10.14μg±0.52 μg) as compared with sham-operation group(P<0.05). After treatment with Xingnaojing injection, brain water content decreased as compared with TBI group (81.91%±1.04%, 80.38%±0.72%, 79.54%±0.58%,78.60%±0.77%, P<0.05). Xingnaojing injection also reduced the leakage of BBB as compared with TBI group (15.11 μg± 0.63 μg, 13.62 μg±0.85μg, 10.06 μg±0.67 μg, 9.54 μg±0.41 μg,P<0.05).Conclusion: Xingnaojing injection could alleviate cerebral edema following TBI via reducing permeability ofBBB.     

Effect of Xingnaojing injection on cerebral edema and blood-brain barrier in rats following traumatic brain injury

Objective:To explore the effects of Xingnaojing injection on cerebral edema and blood-brain barrier (BBB) in rats following traumatic brain injury (TBI).Methods: A total of 108 adult male Sprague-Dawley rats were used as subjects and randomly assigned to three groups:sham-operation,TBI and Xingnaojing injection was set up by the improved device of Feeney's weightcontent and BBB permeability expressed as Evans blue content were measured at 1, 3, 5 and 7 days after surgery.Results: In sham-operation group, brain water content and Evans blue content in brain tissue were 78.97%±1.22%and 5.13μg±0.71μg. Following TBI, water content in brain tissue was increased significantly at 1, 3, 5 and 7 days (83.49%±0.54%, 82.74%±0.72%, 80.22%±0.68%, 79.21%±0.60%), being significantly higher than that in sham operation group (P<0.05). Evans blue content was increased in TBI group (16.54 μg±0.60 μg, 14.92μg±0.71μg, 12.44 μg ±0.92μg, 10.14μg±0.52 μg) as compared with sham-operation group(P<0.05). After treatment with Xingnaojing injection, brain water content decreased as compared with TBI group (81.91%±1.04%, 80.38%±0.72%, 79.54%±0.58%,78.60%±0.77%, P<0.05). Xingnaojing injection also reduced the leakage of BBB as compared with TBI group (15.11 μg± 0.63 μg, 13.62 μg±0.85μg, 10.06 μg±0.67 μg, 9.54 μg±0.41 μg,P<0.05).Conclusion: Xingnaojing injection could alleviate cerebral edema following TBI via reducing permeability ofBBB.     

Bcl-2 family gene products in cerebral ischemia and traumatic brain injury

The proto-oncogene bcl-2 plays a key role in regulating programmed cell death in neurons. The present review discusses the mechanisms by which bcl-2 family genes regulate programmed cell death, and their role in controlling cell death in cerebral ischemia and traumatic brain. Expression of several bcl-2 family members is altered in brain tissues after ischemia and trauma, suggesting that bcl-2 family genes could play a role in determining the fate of injured neurons. Furthermore, alteration of expression of bcl-2 family genes using transgenic approaches, viral vectors, or anti-sense oligonucleotides modifies neuronal cell death and neurological outcome after injury. These data suggest that the activity of bcl-2 family gene products participates in determining cellular and neurologic outcomes in ischemia and trauma. Strategies that either mimic the death-suppressor effects or inhibit the death-promoter effects of bcl-2 family gene products may improve outcome after ischemia and trauma.     

Bcl-2 gene therapy for apoptosis following traumatic brain injury

Objective: Toinvestigatethetherapeuticeffect of Bcl-2 fusion protein on apoptosis in brain following traumatic brain injury. Methods: Bcl-2 gene was cloned by RT-PCR. Bcl-2 and EGFP genes were linked together and inserted into pAdeno-X vector. This recombinant vector was packaged into infectious adenovirus in HEK293 cells. Ninety Wistar rats were assigned randomly into experimental group (n=45) and control group (n=45). All rats were subjected to traumatic brain injury. Then recombinant adenovirus (for experimental group) or saline (for control group) was injected into the traumatic brain. The expression of Bcl-2 fusion protein was investigated by Western blotting, immunohistochemistry and fluorescence microscopy. Apoptosis in the injured brain was studied by TUNEL. Animals' behavior capacity was evaluated by tiltboard test. Results: In the experimental group, many fluorescent cells were found around the traumatic locus, which were also proven to be Bcl-2-positive by immunohistochemistry. On the contrary, few Bcl-2-positive cells and no fluorescent cell were detected in the control group. Bcl-2 expression of experimental group was much higher than that of control group, which was illustrated by Western blotting. The apoptosis index of experimental group was 0. 027±0. 005, and that of control group was 0.141±0.025 (P <0.01). Two weeks after injury, animals of the experimental group behaved better than those of the control group. Conclusions: A recombinant adenovirus vector expressing Bcl-2 fusion protein has been constructed. Bcl-2 fusion protein can suppress apoptosis and promote cell survival. Moreover, the behavior recovery of the injured animal is promoted. Bcl-2 fusion protein provides a way to track the target cells in vivo.     

Recognition of emotion from facial expression following traumatic brain injury

Primary Objective: To assess three domains of emotion recognition in people with traumatic brain injury (TBI).

Research design: A between group comparison.

Procedures: Twenty-four participants with severe TBI and 15 matched participants without brain damage were asked to label and match facial expressions with and without context. The participants with TBI were also interviewed regarding changes in subjective experience of emotion.

Main outcomes and results: Participants with TBI were found to be significantly impaired on expression labelling and matching, but experienced some improvement when provided with context. Negative emotions were particularly affected. Affective semantic knowledge and face perception appeared to be relatively intact in this group. The majority of participants with TBI reported some change in the post-injury experience of everyday emotion, although the pattern of changes differed greatly between individuals. Reduced subjective experience, especially of sadness and fear, was associated with poor emotion matching but not emotion labelling.     

Lesional expression of RhoA and RhoB following traumatic brain injury in humans

Inhibition of the small GTPase Rho or of its downstream target Rho-associated kinase (ROCK) has been shown to promote axon regeneration and to improve functional recovery following traumatic CNS lesions in the adult rat. In order to determine the expression pattern of RhoA and RhoB following human traumatic brain injury (TBI) and to assess whether Rho is a possible target for pharmacological intervention in humans, we investigated expression patterns of RhoA and RhoB in brain specimens from 25 patients who died after closed TBI in comparison to brain tissue derived from four neuropathologically unaffected control patients by immunohistochemistry. A highly significant lesional upregulation of both RhoA and RhoB was observed beginning several hours after the traumatic event and continuing for months after TBI. The cellular sources of both molecules included polymorphonuclear granulocytes, monocytes/macrophages, and reactive astrocytes. Additionally, expression of RhoA was also detected in neuronal cells in some of the cases. From our data, we conclude that inhibition of Rho is a promising mechanism for the development of new pharmacological interventions in human TBI. As the observed upregulation of RhoA and RhoB was still detectable months after TBI, we speculate that even delayed treatment with Rho inhibitors might be a therapeutic option.     

Changes in local cerebral blood flow, glucose utilization, and mitochondrial function following traumatic brain injury in rats

The pathophysiology of secondary brain damage following experimental traumatic brain injury was investigated by measuring local cerebral blood flow (lCBF), local cerebral glucose utilization (lCGU), and activity of succinate dehydrogenase (SDH), which is a mitochondrial enzyme of the tricarboxylic acid cycle, in the rat brain after moderate lateral fluid percussion injury. Measurements used autoradiography for lCBF and lCGU with [14C]iodoantipyrine and [14C]2-deoxyglucose, respectively. Regional SDH activity was determined using quantitative imaging of formazan produced from 2,3,5-triphenyl tetrazolium chloride by SDH. lCBF decreased at 1 hour after injury and was significantly lower than the preinjury level in almost all regions of both hemispheres at 6 and 24 hours, and remained low at 2 weeks. lCGU increased 1 hour after injury but was significantly decreased at 6 and 24 hours, and at 2 weeks in most regions of both hemispheres. The ipsilateral hemisphere showed a significant decrease in the activity of SDH in the cortices, hippocampus, thalamus, and caudate/putamen, most conspicuously 72 hours after injury, whereas no significant decrease was observed in the contralateral hemisphere at any time. Necrosis in the injured cortex and reduction of the number of neurons in the ipsilateral hippocampus were observed 2 weeks after injury. The present study showed that a decrease in lCBF and mitochondrial dysfunction occur with glucose hypermetabolism around 1 hour after lateral fluid percussion injury, and that lCBF, lCGU, and mitochondrial function all deteriorate after 6 hours. This suggests that lCBF and cellular metabolism may change dynamically during the several hours following traumatic brain injury, and afterwards neuronal damage may result in an irreversible change in the areas with depressed glucose hypermetabolism in the early period after injury in combination with mitochondrial dysfunction.     

Psychiatric comorbidity following traumatic brain injury

Primary objective: Survivors of traumatic brain injury (TBI) are at increased risk for development of severe, long-term psychiatric disorders. However, the aetiology of these disorders remains unclear. This article systematically reviews the most current prevalence rates and evidence for causality, in terms of established criteria.

Main outcome and results: Psychiatric syndromes are consistently present at an elevated rate following TBI. Survivors of TBI are particularly susceptible to major depression, generalized anxiety disorder and post-traumatic stress disorder. Evidence for a biological gradient is generally lacking, although this criterion may not be appropriate in the case of TBI. The temporal pattern of onset is variable and reliable critical periods for the post-injury development of a psychiatric disorder remain to be identified; however, individuals appear to remain at risk for years following injury.

Conclusions: Non-organic factors, including pre-morbid personality traits and post-injury psychological reactions to disability and trauma, are implicated in the generation and maintenance of post-TBI psychiatric disorder. There remains insufficient evidence to conclude what role the neuropathological consequences of TBI play in the development of post-TBI psychiatric disorder.     

The effect of age on outcome following traumatic brain injury in rats

Age of the patient is one of the most important predictors of outcome following human traumatic brain injury. This study employs the fluid-percussion model to investigate the effects of aging on outcome following traumatic brain injury in rats. The results revealed that there was an age-associated increase in mortality rate following both low (1.7 to 1.8 atm) and moderate (2.00 to 2.25 atm) levels of traumatic brain injury. Age-related changes in systemic physiological, neurological, and histopathological indexes of brain injury were also examined following a low level of traumatic brain injury. Traumatic brain injury produced equivalent acute hypertension and increased plasma glucose levels in both young adult and aging rats. Injury produced an acute increase in heart rate in the young adult rat group, while the heart rate decreased in the aged rats. At low levels of brain injury, no significant gross histopathological alterations were produced in either age group. Neurological outcome was assessed by measuring the duration of suppression of a number of nonpostural and postural reflexes and more complex somatomotor functions (righting, escape, head support). Except for head support, there was a significant age-related increase in the duration of the suppression of these reflexes following brain injury. These data demonstrate that aging is associated with an increased mortality rate and greater acute neurological deficits following traumatic brain injury. These data also demonstrate the usefulness of the fluid-percussion model for studying the mechanisms responsible for the age-related increase in vulnerability to brain injury.     

Everyday memory following traumatic brain injury

Residual memory deficits may represent a problem to the everyday functioning of a large number of people, including those who have sustained traumatic brain injury (TBI). The present exploratory study sought to investigate the interrelationships between subjective memory reports, performance on traditional memory tests, and performance on tests of prospective memory. These interrelationships were contrasted between a group of 24 adults who had sustained TBI and a group of 24 matched control subjects. Prospective memory was hypothesized to be indicative of everyday memory functioning. The results provided preliminary evidence that prospective memory tests are sensitive to TBIrelated neurological impairment and, in comparison to traditional tests, may be better indicators of functional memory capacity. This pattern was particularly true for control subjects, possibly because TBI subjects had difficulties in evaluating their memory functioning.     

Neuroplasticity following non-penetrating traumatic brain injury

The primary objective of this review is to examine the methodology and evidence for neuroplasticity operating in recovery from traumatic brain injury (TBI), as compared with previous findings in patients sustaining perinatal and infantile focal vascular lesions. The evidence to date indicates that the traditional view of enhanced reorganization of function after early focal brain lesions might apply to early focal brain lesions, but does not conform with studies of early severe diffuse brain injury. In contrast to early focal vascular lesions, young age confers no advantage in the outcome of severe diffuse brain injury. Disruption of myelination could potentially alter connectivity, a suggestion which could be confirmed through diffusion tensor imaging (DTI). Initial reports of DTI in TBI patients support the possibility that this technique can demonstrate alterations in white matter connections which are not seen on conventional magnetic resonance imaging (MRI) and might change over time or with interventions. Preliminary functional MRI studies of TBI patients indicate alterations in the pattern of brain activation, suggesting recruitment of more extensive cortical regions to perform tasks which stress computational resources. Functional MRI, coupled with DTI and possibly other imaging modalities holds the promise of elucidating mechanisms of neuroplasticity and repair following TBI.