Potential therapeutic implications of ergogenic compounds on pathophysiology induced by traumatic brain injury: A narrative review.

Traumatic brain injury (TBI) is a devastating condition that often triggers a sequel of neurological disorders that can last throughout lifespan. From a metabolic viewpoint, the compromising of the energy metabolism of the brain has produced evidence linking the severity of brain injury to the extent of disturbances in the cerebral metabolism. The cerebral metabolic crisis, however, displays that regional heterogeneity varies temporally post-injury. It is important to note that energy generation and mitochondrial function are closely related and interconnected with delayed secondary manifestations of brain injury, including early neuromotor dysfunction, cognitive impairment, and post-traumatic epilepsy (PTE). Given the extent of post-traumatic changes in neuronal function and the possibility of amplifying secondary cascades, different therapies designed to minimize damage and retain/restore cellular function after TBI are currently being studied. One of the possible strategies may be the inclusion of ergogenic compounds, which is a class of supplements that typically includes ingredients used by athletes to enhance their performance. The combination of these compounds offers specific physiological advantages, which include enhanced energy availability/metabolism and improved buffering capacity. However, the literature on their effects in certain biological systems and neurological diseases, such as TBI, has yet to be determined. Thus, the present review aims to discuss the role of ergogenic compounds popularly used in secondary damage induced by this neurological injury. In this narrative review, we also discuss how the results from animal studies can be applied to TBI clinical settings.

Disease-modifying effect of atipamezole in a model of post-traumatic epilepsy.

Treatment of TBI remains a major unmet medical need, with 2.5 million new cases of traumatic brain injury (TBI) each year in Europe and 1.5 million in the USA. This single-center proof-of-concept preclinical study tested the hypothesis that pharmacologic neurostimulation with proconvulsants, either atipamezole, a selective α2-adrenoceptor antagonist, or the cannabinoid receptor 1 antagonist SR141716A, as monotherapy would improve functional recovery after TBI. A total of 404 adult Sprague-Dawley male rats were randomized into two groups: sham-injured or lateral fluid-percussion-induced TBI. The rats were treated with atipamezole (started at 30min or 7 d after TBI) or SR141716A (2min or 30min post-TBI) for up to 9 wk. Total follow-up time was 14 wk after treatment initiation. Outcome measures included motor (composite neuroscore, beam-walking) and cognitive performance (Morris water-maze), seizure susceptibility, spontaneous seizures, and cortical and hippocampal pathology. All injured rats exhibited similar impairment in the neuroscore and beam-walking tests at 2 d post-TBI. Atipamezole treatment initiated at either 30min or 7 d post-TBI and continued for 9 wk via subcutaneous osmotic minipumps improved performance in both the neuroscore and beam-walking tests, but not in the Morris water-maze spatial learning and memory test. Atipamezole treatment initiated at 7 d post-TBI also reduced seizure susceptibility in the pentylenetetrazol test 14 wk after treatment initiation, although it did not prevent the development of epilepsy. SR141716A administered as a single dose at 2min post-TBI or initiated at 30min post-TBI and continued for 9 wk had no recovery-enhancing or antiepileptogenic effects. Mechanistic studies to assess the α2-adrenoceptor subtype specificity of the disease-modifying effects of atipametzole revealed that genetic ablation of α2A-noradrenergic receptor function in Adra2A mice carrying an N79P point mutation had antiepileptogenic effects after TBI. On the other hand, blockade of α2C-adrenoceptors using the receptor subtype-specific antagonist ORM-12741 had no favorable effects on the post-TBI outcome. Finally, to assess whether regulation of the post-injury inflammatory response by atipametzole in glial cells contributed to a favorable outcome, we investigated the effect of atipamezole on spontaneous and/or lipopolysaccharide-stimulated astroglial or microglial cytokine release in vitro. We observed no effect. Our data demonstrate that a 9-wk administration of α2A-noradrenergic antagonist, atipamezole, is recovery-enhancing after TBI.

Levetiracetam prophylaxis ameliorates seizure epileptogenesis after fluid percussion injury.

To determine whether post-traumatic seizure severity would be affected by the interval between seizures and head injury, we measured seizures after various times with or without fluid percussion brain injury (2atm fluid percussion injury; FPI). To determine efficacy of anti-seizure medication, we also determined if levetiracetam (LEV) would alter the relationship between injury and subsequent seizures. Early post-traumatic seizures were induced by Kainic acid (KA) at one week after 2atm fluid percussion injury (FPI) in one group (FPI-ES). Seizures were induced at two weeks after FPI by KA in another group (FPI-LS). In addition, one group had induced seizures by KA without FPI, (sham-ES). Finally one group of animals received the antiepileptic agent (levetiracetam) infusion for one week after FPI and then had seizures induced by KA (FPI-LEV-ES). We measured seizure onset time, ictal duration and severity of seizures using a modified Racine's scale. Histopathological changes in the hippocampus CA1 region were also analyzed. Severity of seizures were increased in the FPI-ES group compared with sham-ES animals. Severity was also enhanced in early post-injury seizures induced by KA (FPI-ES vs. FPI-LS); this exacerbation of seizure severity could be ameliorated by levetiracetam infusion (FPI-ES vs. FPI-LEV-ES). Neuronal degeneration in CA1 was more severe in the FPI-ES group and this degeneration was also diminished by LEV. We conclude that early post injury seizures exacerbate susceptibility and severity of post traumatic seizures and increase neuronal degeneration in the CA1 layer of hippocampus. These changes are partially reversed by LEV infusion after FPI.

Autoregressive spectral analysis of cortical electroencephalographic signals in a rat model of post-traumatic epilepsy.

OBJECTIVES: Post-traumatic epilepsy (PTE) is a common consequence of traumatic brain injury (TBI) and significant predictor of poor prognosis in TBI patients. To develop clinical interventions for PTE risk reduction, there is a need to elucidate the epileptogenic mechanisms induced by brain injury. METHODS: The iron-induced rat model of epilepsy used here mimics many aspects of human PTE. Intracortical injection of iron results in local neuronal damage and the establishment of an epileptic focus, leading to chronic spontaneous electroencephalographic (EEG) signals and motor seizures, with progressively increasing frequency over many months. Identifying unique aspects of PTE seizure semiology for prognosis and treatment may be aided by novel methods of EEG analysis. Here, autoregressive (AR) methods were compared to the conventional fast Fourier transform (FFT) for processing EEG signals in iron-induced epilepsy. RESULTS: Power spectra obtained using AR showed higher frequency resolution over a given epoch than the spectra obtained using FFT. Moreover, changes in total AR spectral power and frequency distribution over brief successive periods provided convenient indexes for long-term monitoring of seizures. DISCUSSION: Autoregression analysis may prove complementary to FFT for EEG analysis in PTE patients.

[Neuroprotection in epilepsy].

Brain damage and neuronal loss caused by traumatic brain injury, ischemic stroke, and symptomatic status epilepticus can lead to severe long-term consequences, such as impairment in learning and memory and cognitive functions, and development of chronic epilepsy. This can be the result of morphologic and functional changes underlying temporal lobe epilepsy. Epilepsy patients have increased risk of status epilepticus. It is a life-threatening condition when seizures last for more than 30 min and trigger processes leading to neuronal apoptosis and necrosis in various parts of brain. Administration of neuroprotective drugs preventing these pathologic processes could improve the prognosis for such patients. However despite of active research of neuroprotective drugs, the effective ways to prevent brain damage resulting from prolonged seizures are yet to be found. Studies of neuroprotective properties of classic and novel anticonvulsant drugs showed that most of them do not have the sufficient neuroprotective effect and are not able to prevent epileptogenesis. Thus the studies of other potential neuroprotective drugs seem to be promising.

Lateralized abnormalities in auditory M50 sensory gating and cortical thickness of the superior temporal gyrus in post-traumatic stress disorder: preliminary results.

Auditory sensory gating deficits have been reported in subjects with post-traumatic stress disorder (PTSD), but the hemispheric and neuronal origins of this deficit are not well understood. The objectives of this study were to: (1) investigate auditory sensory gating of the 50-ms response (M50) in patients diagnosed with PTSD by utilizing magnetoencephalography (MEG); (2) explore the relationship between M50 sensory gating and cortical thickness of the superior temporal gyrus (STG) measured with structural magnetic resonance imaging (MRI); and (3) examine the association between PTSD symptomatology and bilateral sensory gating. Seven participants with combat-related PTSD and eleven controls underwent the paired-click sensory gating paradigm. MEG localized M50 neuronal generators to the STG in both groups. The PTSD group displayed impaired M50 gating in the right hemisphere. Thinner right STG cortical thickness was associated with worse right sensory gating in the PTSD group. The right S1 M50 source strength and gating ratio were correlated with PTSD symptomatology. These findings suggest that the structural integrity of right hemisphere STG cortices play an important role in auditory sensory gating deficits in PTSD.

Presynaptic inhibitory terminals are functionally abnormal in a rat model of posttraumatic epilepsy.

Partially isolated "undercut" neocortex with intact pial circulation is a well-established model of posttraumatic epileptogenesis. Results of previous experiments showed a decreased frequency of miniature inhibitory postsynaptic currents (mIPSCs) in layer V pyramidal (Pyr) neurons of undercuts. We further examined possible functional abnormalities in GABAergic inhibition in rat epileptogenic neocortical slices in vitro by recording whole cell monosynaptic IPSCs in layer V Pyr cells and fast-spiking (FS) GABAergic interneurons using a paired pulse paradigm. Compared with controls, IPSCs in Pyr neurons of injured slices showed increased threshold and decreased peak amplitude at threshold, decreased input/output slopes, increased failure rates, and a shift from paired pulse depression toward paired pulse facilitation (increased paired pulse ratio or PPR). Increasing [Ca(2+)](o) from 2 to 4 mM partially reversed these abnormalities in Pyr cells of the epileptogenic tissue. IPSCs onto FS cells also had an increased PPR and failures. Blockade of GABA(B) receptors did not affect the paired results. These findings suggest that there are functional alterations in GABAergic presynaptic terminals onto both Pyr and FS cells in this model of posttraumatic epileptogenesis.

Posttraumatic epilepsy: the challenge of translating discoveries in the laboratory to pathways to a cure.

Translating laboratory discoveries into successful therapies for preventing epilepsy is a difficult task, but preventing epilepsy in those who are known to be at high risk needs to be one of our highest priorities. At present, we need to approach this task as a parallel set of research endeavors-one concentrating on laboratory experiments designed to learn how to prevent epilepsy after brain trauma and the other focusing on how to perform the appropriate clinical research in humans to demonstrate that whatever is discovered in the laboratory can be appropriately tested. It is too important to let the second process await conclusion of the first. Initially, we need to create a consortium of groups in trauma centers that are dedicated to antiepileptogenic studies and develop funding sources for long-term studies. We need to experiment with clinical protocols, making the studies as cost-effective as possible, while performing continuous data mining of outcomes and surrogate markers. The limitations of current technology to assist in antiepileptogenesis trials must be acknowledged: There is no currently available method for continuously monitoring electroencephalography (EEG) over prolonged periods, and there are no validated biomarkers for the process of epileptogenesis. As we learn more about the process of epileptogenesis and its underlying mechanisms, it is hoped that we will be able to prevent the development of epilepsy after traumatic brain injury (TBI) and after many other known epileptogenic lesions.

Setting apart the affected: the use of behavioral criteria in animal models of post traumatic stress disorder.

Post-traumatic stress disorder (PTSD) affects about 20-30% of exposed individuals. Clinical studies of PTSD generally employ stringent criteria for inclusion in study populations, and yet in animal studies the data collection and analysis are generally expressed as a function of exposed vs nonexposed populations, regardless of individual variation in response. Prior data support an approach to animal models analogous to inclusion criteria in clinical studies. This series of studies sought to assess prevalence rates of maladaptive vs adaptive responses determined according to a more stringent approach to the concept of inclusion/exclusion criteria (cutoff behavioral criteria-CBC), consisting of two successive behavioral tests (elevated plus maze and acoustic startle response tests). The rats were exposed to stressors in two different paradigms; exposure to a predator and underwater trauma. The prevalence rates of maladaptive responses to stress in these two distinct models dropped over time from 90% in the acute phase to 25% enduring/maladaptive response at 7 days, to remain constant over 30 days. As setting the affected individuals apart from the unaffected approximates clinical studies, it might also help to clarify some of the pending issues in PTSD research.

Current perception thresholds of epileptic patients treated with valproate.

We investigated the current perception threshold (CPT) of epileptic patients treated with valproate. The CPTs at frequencies of 5 Hz, 250 Hz and 2000 Hz in the control group of patients were 198.9 +/- 15.8, 62.0 +/- 18.9 and 35.3 +/- 15.8, respectively. The CPTs at 5 Hz, 250 Hz and 2000 Hz in the epileptic group of patients were 350.6 +/- 61.3, 338.6 +/- 64.3 and 193.2 +/- 21.1, respectively. The CPTs at 5 Hz, 250 Hz and 2000 Hz in the epileptic group were significantly higher than those of the control group. We measured the CPTs for 6 months after the administration of valproate in three patients with traumatic epilepsy. Their CPTs were higher than that of the epileptic group. The CPTs at 5 Hz, 250 Hz and 2000 Hz reached a maximum 4 weeks after the administration of valproate for two of these patients and in 6 weeks for the other patient. When the administration of valproate to a patient was stopped, CPTs decreased.

[Reaction of short-latency brain stem evoked potentials to acoustic stimulation and electroencephalography in post-traumatic epilepsy]. / Korotkolatentnye stvolovye vyzvannye potentsialy na akusticheskuiu stimuliatsiiu e élektroéntsefalografiia pri posttravmaticheskoi épilepsii.

Multilevel CNS involvement in closed craniocerebral trauma was manifested by epileptic focus formation and development of posttraumatic epilepsy in roughly 10 to 30% of the cases. The issue of neurophysiological investigation of the late period of posttraumatic epilepsy is far from being well discussed in the literature. The authors revealed the changes of short-latency brainstem evoked potentials to acoustic stimuli in the late period of posttraumatic epilepsy, which are of major diagnostic importance especially in the cases without EEG pathology.

[Short-latency brain stem evoked potentials to acoustic stimulation in posttraumatic epilepsy]. / Korotkolatentnye stvolovye vyzvannye potentsialy na akusticheskuiu stimuliatsiiu pri posttravmaticheskoi épilepsii.

As a result of a comprehensive analysis of posttraumatic epileptic patients the changes in brain stem acoustic evoked potentials are described.