Hippocampal Cb2 receptors: an untold story.

The field of cannabinoid research has been receiving ever-growing interest. Ongoing debates worldwide about the legislation of medical cannabis further motivates research into cannabinoid function within the central nervous system (CNS). To date, two well-characterized cannabinoid receptors exist. While most research has investigated Cb1 receptors (Cb1Rs), Cb2 receptors (Cb2Rs) in the brain have started to attract considerable interest in recent years. With indisputable evidence showing the wide-distribution of Cb2Rs in the brain of different species, they are no longer considered just peripheral receptors. However, in contrast to Cb1Rs, the functionality of central Cb2Rs remains largely unexplored. Here we review recent studies on hippocampal Cb2Rs. While conflicting results about their function have been reported, we have made significant progress in understanding the involvement of Cb2Rs in modulating cellular properties and network excitability. Moreover, Cb2Rs have been shown to be expressed in different subregions of the hippocampus, challenging our prior understanding of the endocannabinoid system. Although more insight into their functional roles is necessary, we propose that targeting hippocampal Cb2Rs may offer novel therapies for diseases related to memory and adult neurogenesis deficits.

Theta and gamma oscillations in the rat hippocampus support the discrimination of object displacement in a recognition memory task.

Episodic memory depends on the recollection of spatial and temporal aspects of past experiences in which the hippocampus plays a critical role. Studies on hippocampal lesions in rodents have shown that dentate gyrus (DG) and CA3 are necessary to detect object displacement in memory tasks. However, the understanding of real-time oscillatory activity underlying memory discrimination of subtle and pronounced displacements remains elusive. Here, we chronically implanted microelectrode arrays in adult male Wistar rats to record network oscillations from DG, CA3, and CA1 of the dorsal hippocampus while animals executed an object recognition task of high and low spatial displacement tests (HD: 108 cm, and LD: 54 cm, respectively). Behavioral analysis showed that the animals discriminate between stationary and displaced objects in the HD but not LD conditions. To investigate the hypothesis that theta and gamma oscillations in different areas of the hippocampus support discrimination processes in a recognition memory task, we compared epochs of object exploration between HD and LD conditions as well as displaced and stationary objects. We observed that object exploration epochs were accompanied by strong rhythmic activity in the theta frequency (6-12 Hz) band in the three hippocampal areas. Comparison between test conditions revealed higher theta band power and higher theta-gamma phase-amplitude coupling in the DG during HD than LD conditions. Similarly, direct comparison between displaced and stationary objects within the HD test showed higher theta band power in CA3 during exploration of displaced objects. Moreover, the discrimination index between displaced and stationary objects directly correlated with CA1 gamma band power in epochs of object exploration. We thus conclude that theta and gamma oscillations in the dorsal hippocampus support the successful discrimination of object displacement in a recognition memory task.

Pranayamas and Their Neurophysiological Effects.

INTRODUCTION: The millenarian breathing exercises from Yoga, commonly called Pranayamas, are known to induce meditative states, reduce stress, and increase lung capacity. However, the physiological mechanisms by which these practices modulate the human nervous system still need to be unveiled. OBJECTIVES: The aim of this work was to review studies describing the influence of breathing exercises on the brain/mind of humans. METHODOLOGY: We reviewed articles written in English and published between 2008 and 2018. Inclusion and exclusion criteria were based on the PRISMA recommendations to filter articles from Science Direct, PubMed, and Virtual Health Library databases. Patient/Population, Intervention, Comparison, and Outcome technique and Prospective Register of Systematic Reviews registration were also considered. RESULTS: From a total of 1588 articles, 14 attended the criteria. They were critically compared to each other and presented in a table divided into study; country; sample size; gender; age; objective; technique; outcome. DISCUSSION: In general, the 14 papers highlight the impact of yogic breathing techniques on emotional and cognitive performance. CONCLUSION: In-depth studies focusing on specific aspects of the practices such as retentions, prolonged expiration, attention on fluid respiration, and abdominal/thoracic respiration should better elucidate the effects of Yogic Breathing Techniques (YBT).

Specific Increase of Hippocampal Delta Oscillations Across Consecutive Treadmill Runs.

Running speed affects theta (6-10 Hz) oscillations, the most prominent rhythm in the rat hippocampus. Many reports have found a strong positive correlation between locomotion speed and the amplitude and frequency of theta oscillations. However, less is known about how other rhythms such as delta (0.5-4 Hz) and gamma (25-100 Hz) are affected, and how consecutive runs impact oscillatory activity in hippocampal networks. Here, we investigated whether the successive execution of short-term runs modulates local field potentials (LFPs) in the rat hippocampus. To do this, we trained Long-Evans rats to perform voluntary 15-s runs at 30 cm/s on a treadmill placed on the central stem of an eight-shape maze, in which they subsequently performed a spatial alternation task. We bilaterally recorded CA1 LFPs while rats executed at least 35 runs on the treadmill-maze apparatus. Within running periods, we observed progressive increases in delta band power along with decreases in the power of the theta and gamma bands across runs. Concurrently, the inter-hemispheric phase coherence in the delta band significantly increased, while in the theta and gamma bands exhibited no changes. Delta power and inter-hemispheric coherence correlated better with the trial number than with the actual running speed. We observed no significant differences in running speed, head direction, nor in spatial occupancy across runs. Our results thus show that consecutive treadmill runs at the same speed positively modulates the power and coherence of delta oscillations in the rat hippocampus.

Hippocampal CA1 and cortical interictal oscillations in the pilocarpine model of epilepsy.

Quantitative electroencephalogram analysis has been increasingly applied to study fine changes in brain oscillations in epilepsy. Here we aimed to evaluate interictal oscillations using pilocarpine model of epilepsy to identify changes in network synchronization. We analyzed the in vivo local field potential of two cortical layers (Ctx1, Ctx2) and hippocampal CA1 (stratum oriens-Ors, pyramidale-Pyr, radiatum-Rad and lacunosum-moleculare-LM) in rats, about 5 weeks after pilocarpine injection. Animals that had status epilepticus (SE) and later spontaneous recurrent seizures (SRS) (epileptic animals) exhibited higher delta power recorded in cortical and hippocampal Ors, Rad and LM electrodes. They also had lower power of theta in Ctx1, Ctx2, Ors and LM, lower slow gamma in Ctx1, Ctx2 and Ors, and lower middle and fast gamma power in Ors. NSE animals had higher delta and lower slow gamma power in Ctx1 only, and lower theta power in Ctx1, Ctx2 and LM. Essentially, epileptic animals had higher delta coherence between Ctx1-Ors, Ctx2-Ors, Ctx2-Pyr, Pyr-Ors and stronger phase-amplitude coupling (PAC) between delta and all frequencies in Rad. NSE animals, also had higher delta coherence between Ctx1-Ors and Ctx2-Ors with no changes in PAC, suggesting some cortical network reorganization. Our data suggest an increased synchrony in cortex and CA1 of epileptic animals, particularly for delta frequency with intense delta coupling in Rad, probably an important synchronization site. Understanding the rhythms organization at non-ictal state could provide insights about network connectivity involved in ictogenesis and seizure propagation.

Brain injury markers (S100B and NSE) in chronic cocaine dependents.

OBJECTIVE: Studies have shown signs of brain damage caused by different mechanisms in cocaine users. The serum neuron specific enolase and S100B protein are considered specific biochemical markers of neuronal and glial cell injury. This study aimed at comparing blood levels of S100B and NSE in chronic cocaine users and in volunteers who did not use cocaine or other illicit drugs. METHOD: Twenty subjects dependent on cocaine but not on alcohol or marijuana, and 20 non-substance using controls were recruited. Subjects were selected by consecutive and non-probabilistic sampling. Neuron specific enolase and S100B levels were determined by luminescence assay. RESULTS: Cocaine users had significantly higher scores than controls in all psychiatric dimensions of the SCL-90 and had cognitive deficits in the subtest cubes of WAIS and the word span. Mean serum S100B level was 0.09 +/- 0.04 microg/l among cocaine users and 0.08 +/- 0.04 microg/l among controls. Mean serum neuron specific enolase level was 9.7 +/- 3.5 ng/l among cocaine users and 8.3 +/- 2.6 ng/l among controls. CONCLUSIONS: In this first study using these specific brain damage markers in cocaine users, serum levels of S100B and neuron specific enolase were not statistically different between cocaine dependent subjects and controls.

Brain injury markers (S100B and NSE) in chronic cocaine dependents

OBJECTIVE: Studies have shown signs of brain damage caused by different mechanisms in cocaine users. The serum neuron specific enolase and S100B protein are considered specific biochemical markers of neuronal and glial cell injury. This study aimed at comparing blood levels of S100B and NSE in chronic cocaine users and in volunteers who did not use cocaine or other illicit drugs. METHOD: Twenty subjects dependent on cocaine but not on alcohol or marijuana, and 20 non-substance using controls were recruited. Subjects were selected by consecutive and non-probabilistic sampling. Neuron specific enolase and S100B levels were determined by luminescence assay. RESULTS: Cocaine users had significantly higher scores than controls in all psychiatric dimensions of the SCL-90 and had cognitive deficits in the subtest cubes of WAIS and the word span. Mean serum S100B level was 0.09 ± 0.04 µg/l among cocaine users and 0.08 ± 0.04 µg/l among controls. Mean serum neuron specific enolase level was 9.7 ± 3.5 ng/l among cocaine users and 8.3 ± 2.6 ng/l among controls. CONCLUSIONS: In this first study using these specific brain damage markers in cocaine users, serum levels of S100B and neuron specific enolase were not statistically different between cocaine dependent subjects and controls.

OBJETIVO: Estudos têm demonstrado sinais de lesão cerebral causadas por diferentes mecanismos em usuários de cocaína. A enolase sérica neurônio-específica e a proteína S100B são consideradas marcadores bioquímicos específicos de lesão neuronal e glial. Este estudo objetivou comparar os níveis sangüíneos de S100B e enolase sérica neurônio-específica em usuários crônicos de cocaína e em voluntários que não usam cocaína ou outras drogas ilícitas. MÉTODO: Vinte sujeitos dependentes de cocaína, mas não dependentes de álcool, maconha ou outra droga, e 20 sujeitos controles não usuários de drogas foram recrutados. Os sujeitos foram selecionados por amostragem consecutiva e não-probabilística e os níveis de enolase neurônio-específica e S100B foram determinados por ensaio de luminescência. RESULTADOS: Os usuários de cocaína tiveram escores significativamente maior que os controles em todas as dimensões psiquiátricas do SCL-90 e apresentaram prejuízos cognitivos no subteste cubos do WAIS e no span de palavras. Os níveis de S100B foram em média 0,09 ± 0,04 µg/l nos usuários de cocaína e 0,08 ± 0,04 µg/l nos controles. Os níveis de enolase neurônio-específica foram em média 9,7 ± 3,5 ng/l nos usuários e 8,3 ± 2,6 ng/l nos controles. CONCLUSÃO: Neste primeiro estudo utilizando esses marcadores específicos de lesão cerebral em usuários de cocaína, os níveis séricos de S100B e enolase específica do neurônio não foram significativamente diferentes entre dependentes de cocaína e controles.

Diagnóstico diferencial dos quadros demenciais associados a parkinsonismo / Differential diagnosis of dementia associated with parkinsonism

Demência é uma síndrome clínica com alta prevalência na população mundial nos dias de hoje. Muitos pacientes com demência também possuem manifestações de sinais neurológicos, assim como um grande número de pacientes neurológicos também apresenta déficits cognitivos. Os achados de parkinsonismo (rigidez, bradicinesia, tremor de repouso e instabilidade postural) na presença de demência são de valor diagnóstico. O presente trabalho tem como objetivo descrever o quadro clínico das principais doenças que são capazes de causar quadros demenciais associados à sintomatologia parkinsoniana, a fim de facilitar o raciocínio clínico para o diagnóstico destas. Para isto, foi realizada uma revisão de literatura científica existente sobre o tema. A importância do conhecimento das doenças descritas nesta revisão deve-se ao fato de que, quando consideradas juntas, elas são responsáveis por um percentual significativo de pacientes que atualmente possuem diagnósticos errôneos.