Brain serotonergic circuitries

Brain serotonergic circuitries interact with other neurotransmitter systems on a multitude of different molecular levels. In humans, as in other mammalian species, serotonin (5-HT) plays a modulatory role in almost every physiological function. Furthermore, serotonergic dysfunction is thought to be implicated in several psychiatric and neurodegenerative disorders. We describe the neuroanatomy and neurochemistry of brain serotonergic circuitries. The contribution of emergent in vivo imaging methods to the regional localization of binding site receptors and certain aspects of their functional connectivity in correlation to behavior is also discussed. 5-HT cell bodies, mainly localized in the raphe nuclei, send axons to almost every brain region. It is argued that the specificity of the local chemocommunication between 5-HT and other neuronal elements mainly depends on mechanisms regulating the extracellular concentration of 5-HT, the diversity of high-affinity membrane receptors, and their specific transduction modalities

Sex steroid hormones and brain function:PET imaging as a tool for research

Sex steroid hormones are major regulators of sexual characteristic among species. These hormones, however, are also produced in the brain. Steroidal hormone-mediated signalling via the corresponding hormone receptors can influence brain function at the cellular level and thus affect behaviour and higher brain functions. Altered steroid hormone signalling has been associated with psychiatric disorders, such as anxiety and depression. Neurosteroids are also considered to have a neuroprotective effect in neurodegenerative diseases. So far, the role of steroid hormone receptors in physiological and pathological conditions has mainly been investigated post mortem on animal or human brain tissues. To study the dynamic interplay between sex steroids, their receptors, brain function and behaviour in psychiatric and neurological disorders in a longitudinal manner, however, non-invasive techniques are needed. Positron emission tomography (PET) is a non-invasive imaging tool that is used to quantitatively investigate a variety of physiological and biochemical parameters in vivo. PET uses radiotracers aimed at a specific target (eg, receptor, enzyme, transporter) to visualise the processes of interest. In this review, we discuss the current status of the use of PET imaging for studying sex steroid hormones in the brain. So far, PET has mainly been investigated as a tool to measure (changes in) sex hormone receptor expression in the brain, to measure a key enzyme in the steroid synthesis pathway (aromatase) and to evaluate the effects of hormonal treatment by imaging specific downstream processes in the brain. Although validated radiotracers for a number of targets are still warranted, PET can already be a useful technique for steroid hormone research and facilitate the translation of interesting findings in animal studies to clinical trials in patients

The subcortical and neurochemical organization of the Ventral and Dorsal Attention Networks

Attention is a core cognitive function that filters and selects behaviourally relevant information in the environment. The cortical mapping of attentional systems identified two segregated networks that mediate stimulus-driven and goal-driven processes, the Ventral and the Dorsal Attention Networks (VAN, DAN). Deep brain electrophysiological recordings, behavioral data from phylogenetic distant species, and observations from human brain pathologies challenge purely corticocentric models. Here, we used advanced methods of functional alignment applied to resting-state functional connectivity analyses to map the subcortical architecture of the Ventral and Dorsal Attention Networks. Our investigations revealed the involvement of the pulvinar, the superior colliculi, the head of caudate nuclei, and a cluster of brainstem nuclei relevant to both networks. These nuclei are densely connected structural network hubs, as revealed by diffusion-weighted imaging tractography. Their projections establish interrelations with the acetylcholine nicotinic receptor as well as dopamine and serotonin transporters, as demonstrated in a spatial correlation analysis with a normative atlas of neurotransmitter systems. This convergence of functional, structural, and neurochemical evidence provides a comprehensive framework to understand the neural basis of attention across different species and brain diseases

Aluminum-induced testosterone decrease results in physiological and behavioral changes in male mice

Recently, there has been much controversy on the role of testosterone on social and aggression behaviors. This work aimed to determine the effect of testosterone decrease, induced by aluminum exposure on the level of aggression. Male Swiss-Webster strain mice were classified into three groups. The first (control group) received distilled water, while the second and third groups were administrated 300 and 600 mg/kg aluminum chloride, respectively, by oral route for 20 days. Thereafter, they were subjected to “standard opponent” test. A significant decrease in testosterone levels in the treated groups was obtained at both the low and high doses of aluminum. Expectedly, significant decreases were observed in the social contacts, threat, attack and number of fights of both treated groups in a dose dependant manner. All blood parameters revealed a dose dependent significant decrease as well. A significant decrease in both serotonin and dopamine levels was simultaneously obtained with the decrease of testosterone level especially at the high dose of aluminum. In contrast, at the high dose, acetylcholine recorded significantly high value. In conclusion, aluminum-induced testosterone decrease resulted in a significant decline in aggression, several blood parameters and levels of neurotransmitters.Keywords: Aluminum, Swiss-Webster mice, standard opponent test, social behavior, testosteron

Dopamine neurotransmission and atypical antipsychotics in prefrontal cortex: a critical review

Schizophrenia has been historically characterized by the presence of positive symptomatology, however, decades of research highlight the importance of cognitive deficits in this disorder. At present, cognitive impairments remain one of the most important unmet therapeutic needs in schizophrenia. The prefrontal cortex (PFC) controls a large number of higher brain functions altered in a variety of psychiatric disorders, including schizophrenia. Histological studies indicate the presence of a large proportion of PFC neurons expressing monoaminergic receptors sensitive to the action of current atypical antipsychotics. Functional studies also show that these medications act at PFC level to increase dopamine neurotransmission in the mesocortical pathway. Here we focus on monoaminergic molecular targets that are actively being explored as potential therapeutic agents in the basic and clinical cognitive neuroscience research, to support the development of co-treatments used in conjunction with antipsychotic medications. These targets include dopamine and serotonin receptors in the prefrontal cortex, as well as elements of the noradrenergic system

Neuroimaging for Epilepsy Diagnosis and Management

This chapter will cover the neuroimaging techniques and their application to the diagnostic work up and management of adults and children with new onset or chronic epilepsy. We will focus on the specific indications and requirements of different imaging techniques for the diagnosis and pre-surgical work up of pharmacoresistant focal epilepsies. We will discuss the sensitivity, specificity and prognostic value of imaging features, benign variants and artefacts, and the possible diagnostic significance of non-epileptogenic lesions. This chapter is intended to be relevant for day-to-day practice in average clinical circumstances, with emphasis on MRI and most commonly used functional neuroimaging techniques

Effect of Pharmacological Interventions on the Fronto-Cingulo-Parietal Cognitive Control Network in Psychiatric Disorders: A Transdiagnostic Systematic Review of fMRI Studies

Executive function deficits such as working memory, decision-making, and attention problems are a common feature of several psychiatric disorders for which no satisfactory treatment exists. Here, we transdiagnostically investigate the effects of pharmacological interventions (other than methylphenidate) on the fronto-cingulo-parietal cognitive control network, in order to identify functional brain markers for future pro-cognitive pharmacological interventions. 29 manuscripts investigated the effect of pharmacological treatment on executive function-related brain correlates in psychotic disorders (n=11), depression (n=4), bipolar disorder (n=4), ADHD (n=4), OCD (n=2), smoking dependence (n=2), alcohol dependence (n=1) and pathological gambling (n=1). In terms of impact on the fronto-cingulo-parietal networks, the preliminary evidence for catechol-o-methyl-transferase inhibitors, nicotinic receptor agonists and atomoxetine suggested was relatively consistent, the data for atypical antipsychotics and anticonvulsants moderate, and interpretation of the data for antidepressants was hampered by the employed study designs. Increased activity in task-relevant areas and decreased activity in task-irrelevant areas were the most common transdiagnostic effects of pharmacological treatment. These markers showed good positive and moderate negative predictive value. It is concluded that fronto-cingulo-parietal activity changes can serve as a marker for future pro-cognitive interventions. Future recommendations include the use of randomized double-blind designs and selective cholinergic and glutamatergic compounds