Selective post-training time window for memory consolidation interference of cannabidiol into the prefrontal cortex: Reduced dopaminergic modulation and immediate gene expression in limbic circuits.

The prefrontal cortex (PFC), amygdala and hippocampus display a coordinated activity during acquisition of associative fear memories. Evidence indicates that PFC engagement in aversive memory formation does not progress linearly as previously thought. Instead, it seems to be recruited at specific time windows after memory acquisition, which has implications for the treatment of post-traumatic stress disorders. Cannabidiol (CBD), the major non-psychotomimetic phytocannabinoid of the Cannabis sativa plant, is known to modulate contextual fear memory acquisition in rodents. However, it is still not clear how CBD interferes with PFC-dependent processes during post-training memory consolidation. Here, we tested whether intra-PFC infusions of CBD immediately after or 5h following contextual fear conditioning was able to interfere with memory consolidation. Neurochemical and cellular correlates of the CBD treatment were evaluated by the quantification of extracellular levels of dopamine (DA), serotonin, and their metabolites in the PFC and by measuring the cellular expression of activity-dependent transcription factors in cortical and limbic regions. Our results indicate that bilateral intra-PFC CBD infusion impaired contextual fear memory consolidation when applied 5h after conditioning, but had no effect when applied immediately after it. This effect was associated with a reduction in DA turnover in the PFC following retrieval 5days after training. We also observed that post-conditioning infusion of CBD reduced c-fos and zif-268 protein expression in the hippocampus, PFC, and thalamus. Our findings support that CBD interferes with contextual fear memory consolidation by reducing PFC influence on cortico-limbic circuits.

Decreased neuron loss and memory dysfunction in pilocarpine-treated rats pre-exposed to hypoxia.

Preconditioning can induce a cascade of cellular events leading to neuroprotection against subsequent brain insults. In this study, we investigated the chronic effects of hypoxic preconditioning on spontaneous recurrent seizures (SRS), neuronal death, and spatial memory performance in rats subjected to pilocarpine (Pilo)-induced status epilepticus (SE). Rats underwent a short hypoxic episode (7% O2+93% N2; 30min on two consecutive days) preceding a 4-h SE (HSE group). Control groups were rats submitted to SE only (SE), rats subjected to hypoxia only (H) or normoxia-saline (C). Animals were monitored for the occurrence of SRS, and spatial memory performance was evaluated in the radial-arm maze. Hippocampal sections were analyzed for cell death and mossy fiber sprouting at 1 or 60days after SE. Compared to SE group, HSE had increased SE latency, reduced number of rats with SRS, reduced mossy fiber sprouting at 60days, and reduced cell death in the hilus and the CA3 region 1 and 60days after SE. Additionally, HSE rats had better spatial memory performance than SE rats. Our findings indicated that short hypoxic preconditioning preceding SE promotes long-lasting protective effects on neuron survival and spatial memory.

Characterization of ICP Behavior in an Experimental Model of Hemorrhagic Stroke in Rats.

Intracranial pressure (ICP) monitoring is sometimes required in clinical pictures of stroke, as extensive intraparenchymal hematomas and intracranial bleeding may severely increase ICP, which can lead to irreversible conditions, such as dementia and cognitive derangement. ICP monitoring has been accepted as a procedure for the safe diagnosis of increased ICP, and for the treatment of intracranial hypertension in some diseases. In this work, we evaluated ICP behavior during the induction of an experimental model of autologous blood injection in rats, simulating a hemorrhagic stroke. Rats were subjected to stereotactic surgery for the implantation of a unilateral cannula into the left striatal region of the brain. Autologous blood was infused into the left striatal region with an automatic microinfusion pump. ICP monitoring was performed throughout the procedure of hemorrhagic stroke induction. Analyses consisted of short-time Fourier transform for ICP before and after stroke induction and the histological processing of the animals' brains. Short-time Fourier transform analysis demonstrated oscillations in the ICP frequency components throughout time after the microinjections compared with data before them. Histological analysis revealed neuropathological changes in the striatum in all microinjected animals.

Papel das sinapses elétricas em crises epilépticas / The role of eletrical synapses in epileptic seizures

INTRODUÇÃO: No sistema nervoso central a comunicação entre neurônios se realiza através de estruturas denominadas sinapses: elétricas ou químicas. As sinapses elétricas são formadas pela aproximação das membranas plasmáticas de dois neurônios formando estruturas chamadas junções comunicantes (gap junctions, do inglês). As junções comunicantes são compostas por seis subunidades da proteína conexina de cada membrana, formando poros que comunicam o citoplasma de células adjacentes e permitem a passagem de íons e pequenas moléculas. OBJETIVOS: A presente revisão pretende descrever e discutir os principais resultados que apontam para uma importante relação entre junções comunicantes e sincronia neuronal durante crises epilépticas. RESULTADOS E CONCLUSÃO: Quando um neurônio é despolarizado, este tipo de comunicação permite a rápida transferência iônica entre as células, promovendo alta sincronia neuronal. Recentemente, o papel das junções comunicantes na geração e propagação de descargas epilépticas tem sido estudado através do uso de diferentes modelos experimentais in vivo, in vitro e in silico (modelos computacionais).

INTRODUCTION: In the central nervous system, neuronal communication is accomplished by structures called synapses: electrical or chemical. Electrical synapses are formed by the apposition of plasmatic membranes at gap junctions and the interaction of connexin subunits from two neurons. At this site, connexin complexes create intercellular pores that communicate the cytoplasm of adjacent neurons and allow free flow of ions and small molecules. OBJECTIVE: In this review, we will present and discuss recent results showing the possible involvement of electrical synapses in the neuronal hypersynchronization during epileptic seizures. RESULTS AND CONCLUSION: When a neuron is depolarized, ions flow very rapidly from one cell to the other promoting high neuronal synchrony. More recently, the role of gap junctions in the generation and propagation of epileptic discharges has been investigated using combined approaches of in vivo, in vitro and in silico (computational) models.