Critical reviews in neurobiology最新文献

Recent functional-neuroimaging studies have provided a wealth of new information suggesting that regions of the prefrontal cortex play a role in episodic memory encoding and retrieval. This review seeks to evaluate the results of these studies in the context of one general model that has proposed that the left prefrontal cortex is preferentially involved in episodic memory encoding, whereas the right prefrontal cortex is preferentially involved in episodic memory retrieval, irrespective of the type (e.g., modality) of information being remembered. The origins of this framework are considered in some detail and then all relevant functional-neuroimaging studies are critically reviewed. The results of this review fail to provide support for the functional-asymmetry model, suggesting instead that episodic memory encoding and retrieval may actually involve similar regions of the lateral prefrontal cortex when all factors relating to the type of stimulus material (i.e., modality), are appropriately controlled.

A review of the literature investigating the neural origins of detection behavior in humans reveals two event-related potential components, P3a and P3b, each with a distinct neural organization and cognitive function.The P3a is involved in automatic novelty detection and characterized by a more anterior cortical distribution, whereas the P3b is concerned with volitional target detection and has a more posterior cortical distribution. Intracranial investigation, studies with patients with focal brain lesions, and functional neuroimaging (fMRI) studies converge with scalp-recorded event-related potential (ERP) data in suggesting that a widespread cortical network gives rise to both automatic and controlled detection behavior. The main regions consistently attributed to generating detection-related brain activation include the temporal-parietal junction, medial temporal complex, and the lateral prefrontal cortex. The extant human and animal literature addressing the neural networks, neuropharmacological underpinnings, and behavioral significance of the P300 potential will be reviewed.

Glutamate and aspartate are the primary excitatory neurotransmitters in the mammalian central nervous system and have also been implicated as mediators of excitotoxic neuronal injury and death. The precise control of extracellular glutamate and aspartate is crucial to the maintenance of normal synaptic transmission and the prevention of excitotoxicity following acute insults to the brain, such as stroke or head trauma, or during the progression of neurodegenerative diseases such as amyotrophic lateral sclerosis. The removal of excitatory amino acids (EAAs) from the extracellular space is primarily mediated by a family of sodium-dependent glutamate transporters. These transporters use the sodium electrochemical gradients of the cell to actively concentrate EAAs in both neurons and glia. Five members of this transporter family have been cloned recently and include both 'glial'-specific and 'neuron'-specific subtypes. Although these subtypes share many common functional properties, there are considerable differences in developmental expression, chronic and acute regulation by cellular signaling pathways, and contribution to disease processes among the subtypes. In this review recent studies of glutamate transporter expression, regulation, function, and pathological relevance are summarized, and some of the discrepancies and unexpected results common to any rapidly progressing field are discussed.