The functional neuroanatomy of autobiographical memory: a meta-analysis.
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Autobiographical memory (AM) entails a complex set of operations, including episodic memory, self-reflection, emotion, visual imagery, attention, executive functions, and semantic processes. The heterogeneous nature of AM poses significant challenges in capturing its behavioral and neuroanatomical correlates. Investigators have recently turned their attention to the functional neuroanatomy of AM. We used the effect-location method of meta-analysis to analyze data from 24 functional imaging studies of AM. The results indicated a core neural network of left-lateralized regions, including the medial and ventrolateral prefrontal, medial and lateral temporal and retrosplenial/posterior cingulate cortices, the temporoparietal junction and the cerebellum. Secondary and tertiary regions, less frequently reported in imaging studies of AM, are also identified. We examined the neural correlates of putative component processes in AM, including, executive functions, self-reflection, episodic remembering and visuospatial processing. We also separately analyzed the effect of select variables on the AM network across individual studies, including memory age, qualitative factors (personal significance, level of detail and vividness), semantic and emotional content, and the effect of reference conditions. We found that memory age effects on medial temporal lobe structures may be modulated by qualitative aspects of memory. Studies using rest as a control task masked process-specific components of the AM neural network. Our findings support a neural distinction between episodic and semantic memory in AM. Finally, emotional events produced a shift in lateralization of the AM network with activation observed in emotion-centered regions and deactivation (or lack of activation) observed in regions associated with cognitive processes. (+info)
The nervous system in colours: the tabulae pictae of G.F. d'Acquapendente (ca. 1533-1619).
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Girolamo Fabrici d'Acquapendente (ca.1533-1619), in his olograph will donated to the Signoria of Venice a rich collection of anatomical paintings, which are today preserved in the Marciana Library. The third volume of these tabulae pictae, entitled De Anatomia Capitis Cerebri Nervorum, deals with the nervous system and contains the only known illustrations by Fabrici regarding neuroanatomy. Despite the realisation of this splendid collection of 21 coloured paintings, neither a systematic description nor an iconographic record regarding nervous structures were found to be published by Fabrici. For this reason, a thorough study of these plates is pivotal to a better understanding of the contribution made by d'Acquapendente to the knowledge of the nervous system. Besides their aesthetic quality, Fabrici's tabulae pictae appear as a unique document of exceptional scientific value, thanks to the unprecedented realism given to the anatomical structures by the innovative use of colours. These pictures represent the highest point reached by the 16th-century Paduan Medical School well demonstrating its aim for a sound naturalistic approach. (+info)
Reflections on eponyms in neuroscience terminology.
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Eponyms have played a very significant linguistic role in technical and scientific terminology. They are an important feature of language that have contributed for a long time to engraving in history the names of those researchers who have devoted their lives to scientific discovery. In the field of medical terminology, they are an asset, although their semantic effectiveness has constituted a long-standing debate. We will analyze how language contributes to the advance of science and technology and the current position of eponyms in the health sciences. Eponymy in neuroscience has been used for a long time as a way to identify and recognize scientific issues, such as diseases, syndromes, methods, processes, substances, organs, and parts of organs as a way to honor those who, in a certain way, contributed to the progress of science. However, sometimes those honors do not correspond to the real contributors, thus receiving a nondeserved acknowledgment. Another problem with eponymic references is the lack of information about the matter in hand, because eponyms do not provide any clear information leading to the identification of the situation under study, as they are not reasonably descriptive. The aim of this article is to encourage the use of descriptive terms instead of eponyms and to establish a system of scientific nomenclature to consolidate the use of the language as a means of conveying scientific information among experts. (+info)
The NeuARt II system: a viewing tool for neuroanatomical data based on published neuroanatomical atlases.
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BACKGROUND: Anatomical studies of neural circuitry describing the basic wiring diagram of the brain produce intrinsically spatial, highly complex data of great value to the neuroscience community. Published neuroanatomical atlases provide a spatial framework for these studies. We have built an informatics framework based on these atlases for the representation of neuroanatomical knowledge. This framework not only captures current methods of anatomical data acquisition and analysis, it allows these studies to be collated, compared and synthesized within a single system. RESULTS: We have developed an atlas-viewing application ('NeuARt II') in the Java language with unique functional properties. These include the ability to use copyrighted atlases as templates within which users may view, save and retrieve data-maps and annotate them with volumetric delineations. NeuARt II also permits users to view multiple levels on multiple atlases at once. Each data-map in this system is simply a stack of vector images with one image per atlas level, so any set of accurate drawings made onto a supported atlas (in vector graphics format) could be uploaded into NeuARt II. Presently the database is populated with a corpus of high-quality neuroanatomical data from the laboratory of Dr Larry Swanson (consisting 64 highly-detailed maps of PHAL tract-tracing experiments, made up of 1039 separate drawings that were published in 27 primary research publications over 17 years). Herein we take selective examples from these data to demonstrate the features of NeuArt II. Our informatics tool permits users to browse, query and compare these maps. The NeuARt II tool operates within a bioinformatics knowledge management platform (called 'NeuroScholar') either as a standalone or a plug-in application. CONCLUSION: Anatomical localization is fundamental to neuroscientific work and atlases provide an easily-understood framework that is widely used by neuroanatomists and non-neuroanatomists alike. NeuARt II, the neuroinformatics tool presented here, provides an accurate and powerful way of representing neuroanatomical data in the context of commonly-used brain atlases for visualization, comparison and analysis. Furthermore, it provides a framework that supports the delivery and manipulation of mapped data either as a standalone system or as a component in a larger knowledge management system. (+info)
The Virtual Insect Brain protocol: creating and comparing standardized neuroanatomy.
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BACKGROUND: In the fly Drosophila melanogaster, new genetic, physiological, molecular and behavioral techniques for the functional analysis of the brain are rapidly accumulating. These diverse investigations on the function of the insect brain use gene expression patterns that can be visualized and provide the means for manipulating groups of neurons as a common ground. To take advantage of these patterns one needs to know their typical anatomy. RESULTS: This paper describes the Virtual Insect Brain (VIB) protocol, a script suite for the quantitative assessment, comparison, and presentation of neuroanatomical data. It is based on the 3D-reconstruction and visualization software Amira, version 3.x (Mercury Inc.) 1. Besides its backbone, a standardization procedure which aligns individual 3D images (series of virtual sections obtained by confocal microscopy) to a common coordinate system and computes average intensities for each voxel (volume pixel) the VIB protocol provides an elaborate data management system for data administration. The VIB protocol facilitates direct comparison of gene expression patterns and describes their interindividual variability. It provides volumetry of brain regions and helps to characterize the phenotypes of brain structure mutants. Using the VIB protocol does not require any programming skills since all operations are carried out at an intuitively usable graphical user interface. Although the VIB protocol has been developed for the standardization of Drosophila neuroanatomy, the program structure can be used for the standardization of other 3D structures as well. CONCLUSION: Standardizing brains and gene expression patterns is a new approach to biological shape and its variability. The VIB protocol provides a first set of tools supporting this endeavor in Drosophila. The script suite is freely available at http://www.neurofly.de2. (+info)
Custom views of reference ontologies.
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Generating "views" over reference ontologies allows them to be customized for use within specific application contexts. In this project we investigated the operations necessary to generate one such custom ontology view. We catalogued the involved operations as a first step in defining the requirements of a formal view definition language. (+info)
Former and present aspects in neuro-skull architecture.
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The classical authors considered the functional resistance of the neuro-skull to consist of arcs at the arch level, rafters at the base and pillars at the joint of the arcs and rafters, those last also connecting the neuro-skull framework and that of the viscero-skull. The new outlooks replace the term pillar with that of resistance node and assemble the arcs and rafters within common structures, named resistance belts. The belts are: one in transversal, three sagittal, two in frontal plane and two oblique positions. At the intersection of the belts, the resistance nodes are placed. (+info)
Neurodegeneration in schizophrenia: evidence from in vivo neuroimaging studies.
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Although schizophrenia is primarily considered to be a neurodevelopmental disorder, there is a growing consensus that the disorder may also involve neurodegeneration. Recent research using non-invasive neuroimaging techniques, such as magnetic resonance imaging, suggests that some patients with schizophrenia show progressive losses of gray matter in the frontal and temporal lobes of the brain. The cellular mechanisms responsible for such gray matter losses are unknown, but have been hypothesized to involve abnormal increases in apoptosis. (+info)