1,721,035 research outputs found
Effects of intrastriatal injiection of selective dopamine agonists on cerebral metabolism and Fos expression in freely-moving rats
No full textMapping neuronal activity of the basal ganglia in experimental models of Parkinson's disease: contributions of the [14C]2-deoxyglucose method
No full textNo abstract availabl
Sexual pheromone or conventional odors increase extracellular lactate without changing glucose utilization in specific brain areas of the rat
No full textBrain extracellular lactate levels increase following physiological stimuli. Monitoring lactate levels might be a tool for detecting dynamic changes in brain activity. In this study we compared changes of extracellular lactate in selected brain areas with rates of glucose utilization as measured by the [14C]2-deoxyglucose method, following olfactory stimulation. Conventional (green pepper essence, heptanal, exanal, octanal) and, above all, non-conventional (sexual pheromone) odors increased lactate in the rhinencephalum, but not in the striatum. Glucose utilization did not change in any area. This discrepancy may result from the different temporal resolution of the two methods employed and/or from the clearance of lactate, whose tissue content increases transiently following neuronal activation as a reflection of the initial oxygen debt
Apomorphine as a neuroprotective drug: a study in MPTP-treated mice and potential relevance to ischemia
No full textNo available abstrac
Effects of nicotine on the nucleus accumbens and similarity to those of addictive drugs
No full textTHE question of whether nicotine, the neuroactive compound of tobacco, is addictive has been open to considerable scientific and public discussion. Although it can serve as a positive reinforcer in several animal species, including man, nicotine is thought to be a weak reinforcer in comparison with addictive drugs such as cocaine and heroin(1,2), and has been argued to be habit forming but not addictive(3,4). Here we report that intravenous nicotine in the rat, at doses known to maintain self-administration, stimulates local energy metabolism, as measured by 2-deoxyglucose autoradiography, and dopamine transmission, as estimated by brain microdialysis, in the shell of the nucleus accumbens. These neurochemical and metabolic effects are qualitatively similar to those of other drugs, such as cocaine, amphetamine and morphine, which have strong addictive properties(5-7). Our results provide functional and neurochemical evidence that there are specific neurobiological commonalities between nicotine and addictive drugs
Th17 and Cognitive Impairmen. Possible Mechanisms of Action
Full text linkT helper 17 (Th17) cells represent a distinct population of immune cells, important in the defense of the organism against extracellular infectious agents. Because of their cytokine profile and ability to recruit other immune cell types, they are highly pro-inflammatory and are involved in the induction of several autoimmune disorders. Recent studies show that Th17 cells and their signature cytokine IL-17 have also a role in a wide variety of neurological diseases. This review article will briefly summarize the evidence linking Th17 cells to brain diseases associated with cognitive impairment, including multiple sclerosis (MS), ischemic brain injury and Alzheimer's disease (AD). We will also investigate the mechanisms by which these cells enter the brain and induce brain damage, including direct effects of IL-17 on brain cells and indirect effects mediated through disruption of the blood-brain barrier (BBB), neurovascular dysfunction and gut-brain axis. Finally, therapeutic prospects targeting Th17 cells and IL-17 will be discussed
Mapping of the pharmacological and toxicological effects of dopaminergic drugs in experimental animals
No full textFunctional consequences of pharmacological and toxicological manipulations of the dopaminergic systems were evaluated by means of the 2-[C-14]deoxyglucose (DG) method for measuring local rates of cerebral glucose utilization. Administration of dopamine agonist drugs modifies glucose metabolism in selected brain areas. Several factors, such as the compound used, the dose, length, and modality of the treatment, and the interval of time between the end of the treatment and the measurement of glucose utilization, contribute to define the topography and intensity of the changes. The differences refer to distinct activation of subtypes of dopamine receptors, to secondary involvement of other neurotransmitter receptor systems, and to modification of the receptor sensitivity occurring during the treatment. Other variables that interfere with the motivated behavior induced by psychostimulants may also affect the metabolic pattern. A few changes in glucose utilization are, however, common to most dopamine agonist drugs. High doses, which induce stereotypic behavior, produce metabolic changes in the extrapyramidal system. Low doses of psychostimulants, which elicit locomotion and exploratory behavior and produce reinforcement, increase glucose metabolism in the limbic system, particularly in the nucleus accumbens. Metabolic mapping in monkeys bearing 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine-induced lesions of the dopaminergic areas in the brainstem contributed to define the key role of the striatopallidal pathway in the production and maintenance of the motor abnormalities that characterize parkinsonism. Metabolic patterns associated with unilateral 6-hydroxydopamine lesion of the nigrostriatal neurons in the rat are modified by dopamine agonist drugs. Specific changes are produced by selective D1 or D2 agonists. In rats bearing unilateral 6-hydroxydopamine lesion, the DG method also revealed functional effects produced by the interaction between D1 and N-methyl-D-aspartate receptors
Chronic cerebral hypoperfusion. An undefined, relevant entity
No full textDespite the large body of data available, chronic cerebral hypoperfusion lacks an operative definition. In a tautological way, the term hypoperfusion is being referred to conditions of ‘‘inadequate blood flow”, ‘‘defects of perfusion” or ‘‘dysfunction of autoregulation”. The chronicity refers to sustained conditions or wavering states characterized by repeated phases of inefficient functional hyperemia. The phenomenon may affect the whole brain or defined areas. A few defined clinical disorders, including heart failure, hypotension, atherosclerosis of large or small vessels and carotid stenosis are thought to cause progressive brain disorders due to chronic hypoperfusion. The clinical relevance manifests mostly as neurocognitive disorders associated with neuroimaging changes. The available data support a conceptual framework that considers chronic cerebral hypoperfusion a likely, relevant pathogenic mechanism for the neurodegeneration-like progression of the neurocognitive disorders. The relationship between neuropathology, cerebral perfusion, and symptoms progression is, however, elusive for several aspects. Typical microangiopathy findings, such as MRI white matter hyperintensities, may appear in individuals without any cerebrovascular risk or vascular lesions. Pathology features of the MRI changes, such as demyelination and gliosis, may result from dysfunction of the neuro-vascular unit not directly associated with vascular mechanisms. In this review, we aim to overview the most common clinical conditions thought to reflect chroni
- …
