Antioxidant activity elicited by low dose of caffeine attenuates pentylenetetrazol-induced seizures and oxidative damage in rats

AbstractAlthough caffeine supplementation has a beneficial effect on people with neurological disorders, its implications for oxidative damage related to seizures are not well documented. Thus the aim of this study was to investigate the effects of two weeks caffeine supplementation (6mg/kg; p.o.) on seizures and neurochemical alterations induced by pentylenetetrazol (PTZ 60mg/kg i.p.). Statistical analyses showed that long-term rather than single dose caffeine administration decreased the duration of PTZ-induced seizures in adult male Wistar rats as recorded by cortical electroencephalographic (EEG) and behavioral analysis. The quantification of EEG recordings also revealed that caffeine supplementation protected against a wave increase induced by PTZ. Neurochemical analyses revealed that caffeine supplementation increased glutathione (GSH) content per se and protected against the increase in the levels of thiobarbituric acid reactive substances (TBARS) and oxidized diclorofluoresceine diacetate (DCFH-DA). Also, caffeine prevent the decrease in GSH content and Na+, K+-ATPase activity induced by PTZ. Our data also showed that the infusion of L-buthionine sulfoximine (BSO; 3.2μmol/site i.c.v), an inhibitor of GSH synthesis, two days before injecting PTZ reversed the anticonvulsant effect caused by caffeine. BSO infusion also decreased GSH content and Na+, K+-ATPase activity. However, it increased DCFH-DA oxidation and TBARS per se and reversed the protective effect of caffeine. Results presented in this paper support the neuroprotective effects of low long-term caffeine exposure to epileptic damage and suggest that the increase in the cerebral GSH content caused by caffeine supplementation may provide a new therapeutic approach to the control of seizure

The Impact of High-Intensity Interval Training on Brain Derived Neurotrophic Factor in Brain: A Mini-Review

The brain-derived neurotrophic factor (BDNF) is a protein mainly synthetized in the neurons. Early evidence showed that BDNF participates in cognitive processes as measured at the hippocampus. This neurotrophin is as a reliable marker of brain function; moreover, recent studies have demonstrated that BDNF participates in physiological processes such as glucose homeostasis and lipid metabolism. The BDNF has been also studied using the exercise paradigm to determine its response to different exercise modalities; therefore, BDNF is considered a new member of the exercise-related molecules. The high-intensity interval training (HIIT) is an exercise protocol characterized by low work volume performed at a high intensity [i.e., ≥80% of maximal heart rate (HRmax)]. Recent evidence supports the contention that HIIT elicits higher fat oxidation in skeletal muscle than other forms of exercise. Similarly, HIIT is a good stimulus to increase maximal oxygen uptake (VO2max). Few studies have investigated the impact of HIIT on the BDNF response. The present work summarizes the effects of acute and long-term HIIT on BDNF

Diclofenac Administration after Physical Training Blunts Adaptations of Peripheral Systems and Leads to Losses in Exercise Performance: In Vivo and In Silico Analyses

Recovery in athletes is hampered by soreness and fatigue. Consequently, nonsteroidal antiinflammatory drugs are used as an effective strategy to maintain high performance. However, impact of these drugs on adaptations induced by training remains unknown. This study assessed the effects of diclofenac administration (10 mg/kg/day) on rats subjected to an exhaustive test, after six weeks of swimming training. Over the course of 10 days, three repeated swimming bouts were performed, and diclofenac or saline were administered once a day. Trained animals exhibited higher muscle citrate synthase and lower plasma creatinine kinase activities as compared to sedentary animals, wherein diclofenac had no impact. Training increased time to exhaustion, however, diclofenac blunted this effect. It also impaired the increase in plasma and liver interleukin-6 levels. The trained group exhibited augmented catalase, glutathione peroxidase, and glutathione reductase activities, and a higher ratio of reduced-to-oxidized glutathione in the liver. However, diclofenac treatment blunted all these effects. Systems biology analysis revealed a close relationship between diclofenac and liver catalase. These results confirmed that regular exercise induces inflammation and oxidative stress, which are crucial for tissue adaptations. Altogether, diclofenac treatment might be helpful in preventing pain and inflammation, but its use severely affects performance and tissue adaptatio

O papel do óxido nítrico nas alterações comportamentais eletroencefalográficas e neuroquímicas induzidas pelo metilmalonato em estriado de ratos

A acidemia metilmalônica é um erro inato do metabolismo caracterizado pelo acúmulo tecidual de ácido metilmalônico (MMA), dano oxidativo e alterações neurológicas, como degeneração estriatal e convulsões. Considerando que o óxido nítrico é um mensageiro químico trans-sináptico que está envolvido em diversos eventos fisiopatologógicos e seu papel na toxicidade induzida pelo MMA é pouco conhecido, nós decidimos investigar a participação deste radical livre nas alterações comportamentais e neuroquímicas induzidas pela administração intraestriatal de MMA. No primeiro trabalho, foi evidenciado que a administração intraestriatal de um inibidor não-seletivo da enzima óxido nítrico sintase, metil éster de Nϖ-nitro-L-arginina (LNAME: 10-4 - 100 nmol/0,5 μl), exerceu efeito bifásico nas convulsões e na carbonilação proteíca induzidas pela injeção de MMA (4,5 μmol/1,5 μl; 30 minutos após a injeção de L-NAME) no estriado de ratos. Estes resultados sugeriram um envolvimento do óxido nítrico nas convulsões e no dano oxidativo induzido pelo MMA. Em um segundo momento, confirmamos o envolvimento do óxido nítrico nas convulsões induzidas por MMA, uma vez que a injeção intraestriatal de MMA causou um aumento na concentração de nitrito e nitrato (NO2 e NO3) estriatal. Além disso, os episódios convulsivos induzidos por MMA apresentaram uma correlação significativa com a inibição da atividade da Na+,K+-ATPase no estriado injetado, mas não com os níveis de carbonilação protéica, um marcador de dano oxidativo protéico. Neste estudo também foi avaliado o efeito da administração intraestriatal do azul de metileno (AM; 0,015 a 1,5 nmol/ 0,5 μl), que possui atividade antioxidante e é um inibidor da guanilato ciclase, nas convulsões e dano oxidativo induzidos pelo MMA. O AM (1,5 nmol/0,5 μl) diminuiu a formação de NO2 e NO3 estriatal e preveniu as convulsões, a carbonilação protéica e a inibição da atividade da Na+,K+-ATPase induzidos pelo MMA. Esses dados sugerem que a atividade da Na+,K+-ATPase pode ser de grande importância para a gênese das convulsões induzidas pelo MMA e que o AM exerce efeito neuroprotetor contra as alterações comportamentais e neuroquímicas induzidas pelo MMA. Além disso, se essas alterações ocorerem nos pacientes com acidemia metilmalônica, é possível propor que o AM poderia ser considerado como uma terapia adjuvante para o tratamento desta acidemia. O efeito da administração do 7-nitroindazol (7-NI; 3-60 mg/kg, i.p.), um inibidor da enzima NOSn, nas convulsões, carbonilação protéica, produção de NO2 e NO3 e na atividade da Na+,K+-ATPase após trinta minutos da administração intraestriatal de MMA (6 μmol/ 2 μl) também foi avaliado. O tratamento com 7-NI (60 mg/kg, i.p.) potencializou as convulsões, aumentou a carbonilação protéica e reduziu a produção de NO2 e NO3 induzidos pelo MMA, entretanto, este tratamento não alterou a atividade da Na+,K+-ATPase. A adminstração intraestriatal de L-arginina (50 nmol/ 0.5 μl), mas não de D-arginina (5 and 50 nmol/ 0.5 μl), aumentou a produção de NO2 e NO3 e preveniu as convulsões, a carbonilação protéica e a inibição da atividade da Na+,K+-ATPase induzidos pelo MMA. Esses resultados sugerem que o óxido nítrico neuronal pode exercer um efeito protetor sobre as convulsões bem como nas alterações neuroquímicas evidenciadas neste modelo de acidemia orgânica. Concluindo, estes resultados ampliam o papel dos radicais livres nas alterações comportamentais e neuroquímicas induzidas pela administração intra-estriatal de MMA

Making sense of gut feelings in the traumatic brain injury pathogenesis.

Traumatic brain injury (TBI) is a devastating condition which often initiates a sequel of neurological disorders that can last throughout lifespan. From metabolic perspective, TBI also compromises systemic physiology including the function of body organs with subsequent malfunctions in metabolism. The emerging panorama is that the effects of TBI on the periphery strike back on the brain and exacerbate the overall TBI pathogenesis. An increasing number of clinical reports are alarming to show that metabolic dysfunction is associated with incidence of long-term neurological and psychiatric disorders. The autonomic nervous system, associated hypothalamic-pituitary axis, and the immune system are at the center of the interface between brain and body and are central to the regulation of overall homeostasis and disease. We review the strong association between mechanisms that regulate cell metabolism and inflammation which has important clinical implications for the communication between body and brain. We also discuss the integrative actions of lifestyle interventions such as diet and exercise on promoting brain and body health and cognition after TBI

Dietary fructose as a model to explore the influence of peripheral metabolism on brain function and plasticity.

High consumption of fructose has paralleled an explosion in metabolic disorders including obesity and type 2 diabetes. Even more problematic, sustained consumption of fructose is perceived as a threat for brain function and development of neurological disorders. The action of fructose on peripheral organs is an excellent model to understand how systemic physiology impacts the brain. Given the recognized action of fructose on liver metabolism, here we discuss mechanisms by which fructose can impact the brain by interacting with liver and other organs. The interaction between peripheral and central mechanisms is a suitable target to reduce the pathophysiological consequences of neurological disorders

The interaction between brain and liver regulates lipid metabolism in the TBI pathology.

To shed light on the impact of systemic physiology on the pathology of traumatic brain injury (TBI), we examine the effects of TBI (concussive injury) and dietary fructose on critical aspects of lipid homeostasis in the brain and liver of young-adult rats. Lipids are integral components of brain structure and function, and the liver has a role on the synthesis and metabolism of lipids. Fructose is mainly metabolized in the liver with potential implications for brain function. Lipidomic analysis accompanied by unbiased sparse partial least squares discriminant analysis (sPLS-DA) identified lysophosphatidylcholine (LPC) and cholesterol ester (CE) as the top lipid families impacted by TBI and fructose in the hippocampus, and only LPC (16:0) was associated with hippocampal-dependent memory performance. Fructose and TBI elevated liver pro-inflammatory markers, interleukin-1α (IL-1α), Interferon-γ (IFN-γ) that correlated with hippocampal-dependent memory dysfunction, and monocyte chemoattractant protein-1 (MCP-1) positively correlated with LPC levels in the hippocampus. The effects of fructose were more pronounced in the liver, in agreement with the role of liver on fructose metabolism and suggest that fructose could exacerbate liver inflammation caused by TBI. The overall results indicate that TBI and fructose interact to influence systemic and central inflammation by engaging liver lipids. The impact of TBI and fructose diet on the periphery provides a therapeutic target to counteract the TBI pathogenesis