Neuronale Netzwerke des Zentralkomplexes und ein räumliches Arbeitsgedächtnis von Drosophila melanogaster

Zielgerichtete Orientierung ermöglicht es Lebewesen, überlebenswichtige Aufgaben, wie die Suche nach Ressourcen, Fortpflanzungspartnern und sicheren Plätzen zu bewältigen. Dafür ist es essentiell, die Umgebung sensorisch wahrzunehmen, frühere Erfahrungen zu speichern und wiederabzurufen und diese Informationen zu integrieren und in motorische Aktionen umzusetzen.rnWelche Neuronengruppen vermitteln zielgerichtete Orientierung im Gehirn einer Fliege? Welche sensorischen Informationen sind in einem gegebenen Kontext relevant und wie werden diese Informationen sowie gespeichertes Vorwissen in motorische Aktionen übersetzt? Wo findet im Gehirn der Übergang von der sensorischen Verarbeitung zur motorischen Kontrolle statt? rnDer Zentralkomplex, ein Verbund von vier Neuropilen des Zentralhirns von Drosophila melanogaster, fungiert als Übergang zwischen in den optischen Loben vorverarbeiteten visuellen Informationen und prämotorischem Ausgang. Die Neuropile sind die Protocerebralbrücke, der Fächerförmige Körper, der Ellipsoidkörper und die Noduli. rnIn der vorliegenden Arbeit konnte gezeigt werden, dass Fruchtfliegen ein räumliches Arbeitsgedächtnis besitzen. Dieses Gedächtnis kann aktuelle visuelle Information ersetzen, wenn die Sicht auf das Zielobjekt verloren geht. Dies erfordert die sensorische Wahrnehmung von Zielobjekten, die Speicherung der Position, die kontinuierliche Integration von Eigen-und Objektposition, sowie die Umsetzung der sensorischen Information in zielgerichtete Bewegung. Durch konditionale Expression von Tetanus Toxin mittels des GAL4/UAS/GAL80ts Systems konnte gezeigt werden, dass die Ringneurone, welche in den Ellipsoidkörper projizieren, für das Orientierungsgedächtnis notwendig sind. Außerdem konnte gezeigt werden, dass Fliegen, denen die ribosomale Serinkinase S6KII fehlt, die Richtung verlieren, sobald keine Objekte mehr sichtbar sind und, dass die partielle Rettung dieser Kinase ausschließlich in den Ringneuronenklassen R3 und R4d hinreichend ist, um das Gedächtnis wieder herzustellen. Bei dieser Gedächtnisleistung scheint es sich um eine idiothetische Form der Orientierung zu handeln. rn Während das räumliche Arbeitsgedächtnis nach Verschwinden von Objekten relevant ist, wurde in der vorliegende Arbeit auch die Vermittlung zielgerichteter Bewegung auf sichtbare Objekte untersucht. Dabei wurde die zentrale Frage bearbeitet, welche Neuronengruppen visuelle Orientierung vermitteln. Anhand von Gehirnstrukturmutanten konnte gezeigt werden, dass eine intakte Protocerebralbrücke notwendig ist, um Laufgeschwindigkeit, Laufaktivität und Zielgenauigkeit bei der Ansteuerung visueller Stimuli korrekt zu vermitteln. Dabei scheint das Horizontale Fasersystem, welches von der Protocerebralbrücke über den Fächerförmigen Körper auf den Zentralkomplex assoziierte Neuropile, die Ventralkörper, projiziert, notwendig für die lokomotorische Kontrolle und die zielgenaue Bewegung zu sein. Letzeres konnte zum einen durch Blockade der synaptischen Transmission anhand konditionaler Tetanus Toxin Expression mittels des GAL4/UAS/GAL80ts Systems im Horizontalen Fasersystem gezeigt werden;. zum anderen auch durch partielle Rettung der in den Strukturmutanten betroffenen Gene. rn Den aktuellen Ergebnissen und früheren Studien folgend, ergibt sich dabei ein Modell, wie zielgerichtete Bewegung auf visuelle Stimuli neuronal vermittelt werden könnte. Nach diesem Modell bildet die Protocerebralbrücke die Azimuthpositionen von Objekten ab und das Horizontale Fasersystem vermittelt die entsprechende lokomotorische Wo-Information für zielgerichtete Bewegungen. Die Eigenposition in Relation zum Zielobjekt wird über die Ringneurone und den Ellipsoidkörper vermittelt. Wenn das Objekt aus der Sicht verschwindet, kann die Relativposition ideothetisch ermittelt werden und integriert werden mit Vorinformation über das Zielobjekt, die im Fächerförmigen Körper abgelegt ist (Was-Information). Die resultierenden Informationen könnten dann über das Horizontale Fasersystem in den Ventralkörpern auf absteigende Neurone gelangen und in den Thorax zu den motorischen Zentren weitergeleitet werden.rn

The Influence of Pre-stimulus EEG Activity on Reaction Time During a Verbal Sternberg Task is Related to Musical Expertise

Abstract Previous work highlighted the possibility that musical training has an influence on cognitive functioning. The suggested reason for this influence is the strong recruitment of attention, planning, and working memory functions during playing a musical instrument. The purpose of the present work was twofold, namely to evaluate the general relationship between pre-stimulus electrophysiological activity and cognition, and more specifically the influence of musical expertise on working memory functions. With this purpose in mind, we used covariance mapping analyses to evaluate whether pre-stimulus electroencephalographic activity is predictive for reaction time during a visual working memory task (Sternberg paradigm) in musicians and non-musicians. In line with our hypothesis, we replicated previous findings pointing to a general predictive value of pre-stimulus activity for working memory performance. Most importantly, we also provide first evidence for an influence of musical expertise on working memory performance that could distinctively be predicted by pre-stimulus spectral power. Our results open novel perspectives for better comprehending the vast influences of musical expertise on cognition.

Human brain regions required for the dividing and switching of attention between two features of a single object

This combined PET and ERP study was designed to identify the brain regions activated in switching and divided attention between different features of a single object using matched sensory stimuli and motor response. The ERP data have previously been reported in this journal [64]. We now present the corresponding PET data. We identified partially overlapping neural networks with paradigms requiring the switching or dividing of attention between the elements of complex visual stimuli. Regions of activation were found in the prefrontal and temporal cortices and cerebellum. Each task resulted in different prefrontal cortical regions of activation lending support to the functional subspecialisation of the prefrontal and temporal cortices being based on the cognitive operations required rather than the stimuli themselves. (C) 2003 Elsevier Science B.V. All rights reserved.

Modificazioni del segnale EEG in un compito di memoria visiva con distrattori visivi ‘deboli’ e ‘forti’

La valutazione del segnale elettroencefalografico acquisito durante compiti di Working Memory è utile per indagare regioni e meccanismi cerebrali alla base della capacità di immagazzinare le informazioni provenienti dall’ambiente rilevanti per il task da svolgere e di inibire stimoli irrilevanti/distraenti. In questo lavoro di Tesi è stato condotto uno studio su 13 volontari che hanno svolto un compito di memoria di lavoro visiva, consistente di prove ripetute (trial) ognuna composta di diverse fasi: Encoding (memorizzazione del memory set), Retention (mantenimento in memoria) in cui si mostra un distrattore, che può essere weak (poco interferente) o strong (maggiormente interferente). Ciascun trial termina con la comparsa della Probe, a cui il soggetto deve rispondere indicando se apparteneva o meno al memory set. Durante il task è stato acquisito il segnale EEG da 64 elettrodi, ed analizzato per indagare i potenziali evocati (ERPs) e la sincronizzazione/desincronizzazione in banda alpha (8-12 Hz) e theta (4-8 Hz) correlata agli stimoli visivi; è stata svolta anche un’analisi preliminare ricostruendo l’attività delle sorgenti corticali dal segnale EEG. Dalle analisi emerge che gli ERPs sono visibili principalmente nelle fasi di Encoding e Distractor, e nelle regioni fronto-centrali e parieto-occipitali, e che nella fase di Distractor sono maggiori per distrattore weak rispetto a strong. Si conferma la natura inibitoria del ritmo alpha e il ruolo del ritmo theta nei processi cognitivi; infatti la potenza in banda alpha aumenta nella fase pre-distrattore (sia weak che strong) e la potenza in banda theta è sostenuta durante l’intero task. Non si osservano differenze in banda alpha e theta tra i due distrattori nella fase pre-distrattore, mentre si osserva una modulazione durante la presentazione del distrattore.

Effetto di distrattori acustici rispetto a distrattori visivi in un compito di memoria visiva: analisi del segnale EEG

Studi recenti hanno evidenziato cambiamenti nei ritmi alpha (8-12 Hz) e theta (4-8 Hz) in vari processi modulatori top-down e di controllo cognitivo come la memoria di lavoro (WM, working memory) e la soppressione di distrattori. I compiti di WM richiedono attenzione interna sostenuta per dare priorità alle informazioni rilevanti a discapito di quelle interferenti che distraggono dall’obiettivo. I meccanismi di attenzione in tali compiti sono associati ad aumento di potenza alpha, che riflette la funzione inibitoria di tale ritmo, in regioni che elaborano informazioni distraenti, e ad aumento di potenza theta, soprattutto in regioni frontali, che riflette funzioni di controllo cognitivo per raggiungere l’obiettivo pur in presenza di interferenze. Questo lavoro è volto ad indagare gli effetti di distrattori acustici rispetto a distrattori visivi in un compito di visual WM. A tale scopo sono stati acquisiti ed elaborati i segnali EEG di 12 soggetti volontari mentre eseguivano un compito di visual WM, in cui la fase di retention (mantenimento in memoria delle informazioni codificate) veniva interrotta con la presentazione di distrattori di due modalità sensoriali differenti (visiva e acustica), per valutare le variazioni dell’attività cerebrale in termini di ritmi alpha e theta e le regioni coinvolte. Si è osservato un aumento maggiore di potenza alpha (principalmente posteriore) in presenza del distrattore acustico rispetto al visivo sia nella fase pre-distrattore che nella fase distrattore, statisticamente significativo nella fase distrattore. Si è osservato un aumento maggiore di potenza theta (principalmente frontale) in presenza del distrattore acustico rispetto al visivo in tutte le fasi del task, statisticamente significativo nella fase iniziale di retention e nella fase del distrattore. I risultati potrebbero indicare una maggiore necessità di controllo cognitivo e di protezione da stimoli interferenti in caso di distrattore acustico rispetto al visivo.

"What" and "Where" in the intraparietal sulcus : an fMRI study of object identity and location in visual short-term memory

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal

Neural mechanisms for visual memory and their role in attention

Recent studies show that neuronal mechanisms for learning and memory both dynamically modulate and permanently alter the representations of visual stimuli in the adult monkey cortex. Three commonly observed neuronal effects in memory-demanding tasks are repetition suppression, enhancement, and delay activity. In repetition suppression, repeated experience with the same visual stimulus leads to both short- and long-term suppression of neuronal responses in subpopulations of visual neurons. Enhancement works in an opposite fashion, in that neuronal responses are enhanced for objects with learned behavioral relevance. Delay activity is found in tasks in which animals are required to actively hold specific information “on-line” for short periods. Repetition suppression appears to be an intrinsic property of visual cortical areas such as inferior temporal cortex and is thought to be important for perceptual learning and priming. By contrast, enhancement and delay activity may depend on feedback to temporal cortex from prefrontal cortex and are thought to be important for working memory. All of these mnemonic effects on neuronal responses bias the competitive interactions that take place between stimulus representations in the cortex when there is more than one stimulus in the visual field. As a result, memory will often determine the winner of these competitions and, thus, will determine which stimulus is attended.

Visual binding abilities in the initial and advanced stages of schizophrenia

OBJECTIVE: The study tests the hypothesis that intramodal visual binding is disturbed in schizophrenia and should be detectable in all illness stages as a stable trait marker. METHOD: Three groups of patients (rehospitalized chronic schizophrenic, first admitted schizophrenic and schizotypal patients believed to be suffering from a pre-schizophrenic prodrome) and a group of normal control subjects were tested on three tasks targeting visual 'binding' abilities (Muller-Lyer's illusion and two figure detection tasks) in addition to control parameters such as reaction time, visual selective attention, Raven's test and two conventional cortical tasks of spatial working memory (SWM) and a global local test. RESULTS: Chronic patients had a decreased performance on the binding tests. Unexpectedly, the prodromal group exhibited an enhanced Gestalt extraction on these tests compared both to schizophrenic patients and to healthy subjects. Furthermore, chronic schizophrenia was associated with a poor performance on cortical tests of SWM, global local and on Raven. This association appears to be mediated by or linked to the chronicity of the illness. CONCLUSION: The study confirms a variety of neurocognitive deficits in schizophrenia which, however, in this sample seem to be linked to chronicity of illness. However, certain aspects of visual processing concerned with Gestalt extraction deserve attention as potential vulnerability- or prodrome- indicators. The initial hypothesis of the study is rejected.

Time processing in visual cortices: How the visual brain encodes and keeps track of time

Time is embedded in any sensory experience: the movements of a dance, the rhythm of a piece of music, the words of a speaker are all examples of temporally structured sensory events. In humans, if and how visual cortices perform temporal processing remains unclear. Here we show that both primary visual cortex (V1) and extrastriate area V5/MT are causally involved in encoding and keeping time in memory and that this involvement is independent from low-level visual processing. Most importantly we demonstrate that V1 and V5/MT are functionally linked and temporally synchronized during time encoding whereas they are functionally independent and operate serially (V1 followed by V5/MT) while maintaining temporal information in working memory. These data challenge the traditional view of V1 and V5/MT as visuo-spatial features detectors and highlight the functional contribution and the temporal dynamics of these brain regions in the processing of time in millisecond range. The present project resulted in the paper entitled: 'How the visual brain encodes and keeps track of time' by Paolo Salvioni, Lysiann Kalmbach, Micah Murray and Domenica Bueti that is now submitted for publication to the Journal of Neuroscience.

How the visual brain encodes and keeps track of time.

Time is embedded in any sensory experience: the movements of a dance, the rhythm of a piece of music, the words of a speaker are all examples of temporally structured sensory events. In humans, if and how visual cortices perform temporal processing remains unclear. Here we show that both primary visual cortex (V1) and extrastriate area V5/MT are causally involved in encoding and keeping time in memory and that this involvement is independent from low-level visual processing. Most importantly we demonstrate that V1 and V5/MT come into play simultaneously and seem to be functionally linked during interval encoding, whereas they operate serially (V1 followed by V5/MT) and seem to be independent while maintaining temporal information in working memory. These data help to refine our knowledge of the functional properties of human visual cortex, highlighting the contribution and the temporal dynamics of V1 and V5/MT in the processing of the temporal aspects of visual information.

Visual efficiency detection index : a new composite measure of visual search

Visual search is an important component of our interaction with our surroundings, allowing us to successfully identify external cues that impact our spatial navigation. Previous research has established fixation duration, fixation count, saccade velocity, and saccade amplitude as important indices of visual search. We examined the Visual Efficiency Detection Index (VEDI) comprising multiple aspects of visual search performance into a single measure of global visual performance. Forty participants, 10 adults ages 22-48, and children ages 6, 8, and 10, completed tests of working memory and visual search in response to stimuli relevant to pedestrian decision making. Results indicated VEDI statistically relates to established indices of visual search in relation to their interpretability for human performance. The VEDI was also sensitive to developmental differences in visual search performance, suggesting insight to its utility in the developmental psychological literature.

The effects of anxiety on visual search, movement kinematics, and performance in table tennis: A test of Eysenck and Calvo's processing efficiency theory

Processing efficiency theory predicts that anxiety reduces the processing capacity of working memory and has detrimental effects on performance. When tasks place little demand on working memory, the negative effects of anxiety can be avoided by increasing effort. Although performance efficiency decreases, there is no change in performance effectiveness. When tasks impose a heavy demand on working memory, however, anxiety leads to decrements in efficiency and effectiveness. These presumptions were tested using a modified table tennis task that placed low (LWM) and high (HWM) demands on working memory. Cognitive anxiety was manipulated through a competitive ranking structure and prize money. Participants' accuracy in hitting concentric circle targets in predetermined sequences was taken as a measure of performance effectiveness, while probe reaction time (PRT), perceived mental effort (RSME), visual search data, and arm kinematics were recorded as measures of efficiency. Anxiety had a negative effect on performance effectiveness in both LWM and HWM tasks. There was an increase in frequency of gaze and in PRT and RSME values in both tasks under high vs. low anxiety conditions, implying decrements in performance efficiency. However, participants spent more time tracking the ball in the HWM task and employed a shorter tau margin when anxious. Although anxiety impaired performance effectiveness and efficiency, decrements in efficiency were more pronounced in the HWM task than in the LWM task, providing support for processing efficiency theory.

Core networks for visual-concrete and abstract thought content: a brain electric microstate analysis

Commonality of activation of spontaneously forming and stimulus-induced mental representations is an often made but rarely tested assumption in neuroscience. In a conjunction analysis of two earlier studies, brain electric activity during visual-concrete and abstract thoughts was studied. The conditions were: in study 1, spontaneous stimulus-independent thinking (post-hoc, visual imagery or abstract thought were identified); in study 2, reading of single nouns ranking high or low on a visual imagery scale. In both studies, subjects' tasks were similar: when prompted, they had to recall the last thought (study 1) or the last word (study 2). In both studies, subjects had no instruction to classify or to visually imagine their thoughts, and accordingly were not aware of the studies' aim. Brain electric data were analyzed into functional topographic brain images (using LORETA) of the last microstate before the prompt (study 1) and of the word-type discriminating event-related microstate after word onset (study 2). Conjunction analysis across the two studies yielded commonality of activation of core networks for abstract thought content in left anterior superior regions, and for visual-concrete thought content in right temporal-posterior inferior regions. The results suggest that two different core networks are automatedly activated when abstract or visual-concrete information, respectively, enters working memory, without a subject task or instruction about the two classes of information, and regardless of internal or external origin, and of input modality. These core machineries of working memory thus are invariant to source or modality of input when treating the two types of information.

Neuronal Correlates of Perception, Imagery, and Memory for Familiar Tunes

We used fMRI to investigate the neuronal correlates of encoding and recognizing heard and imagined melodies. Ten participants were shown lyrics of familiar verbal tunes; they either heard the tune along with the lyrics, or they had to imagine it. In a subsequent surprise recognition test, they had to identify the titles of tunes that they had heard or imagined earlier. The functional data showed substantial overlap during melody perception and imagery, including secondary auditory areas. During imagery compared with perception, an extended network including pFC, SMA, intraparietal sulcus, and cerebellum showed increased activity, in line with the increased processing demands of imagery. Functional connectivity of anterior right temporal cortex with frontal areas was increased during imagery compared with perception, indicating that these areas form an imagery-related network. Activity in right superior temporal gyrus and pFC was correlated with the subjective rating of imagery vividness. Similar to the encoding phase, the recognition task recruited overlapping areas, including inferior frontal cortex associated with memory retrieval, as well as left middle temporal gyrus. The results present new evidence for the cortical network underlying goal-directed auditory imagery, with a prominent role of the right pFC both for the subjective impression of imagery vividness and for on-line mental monitoring of imagery-related activity in auditory areas.

Internal and external effects on cognition: Evidence from memory training in very preterm-born children and cognition in patients with carotid artery stenosis before and after treatment

The present synopsis aims to integrate one study about memory training in very preterm-born children and two studies about cognition in patients with carotid artery stenosis before and after treatments. Preterm-born children are at increased risk of cognitive deficits and behavioural problems compared with peers born at term. This thesis determined whether memory training would improve cognitive functions in school-age very preterm-born children. Memory strategy training produced significant improvements in trained and non-trained cognitive functions; a core working memory training revealed significant effects on short-term memory and working memory tasks. Six months after training, children in both training groups showed better working memory performance than children in the waiting control group. This is evidence that memory training – an external influence on cognition – induces plastic changes in very preterm-born children. Patients with carotid artery stenosis are known to be at increased risk of cognitive impairment. We showed that patients with symptomatic or asymptomatic carotid artery stenosis were at higher risk for cognitive deficits than expected in a normative sample. This thesis seeks to link cognitive plasticity to internal factors like carotid stenosis. An external factor, which influences blood flow to the brain is the nature of the carotid artery stenosis treatment. Research on the effects of carotid artery stenosis treatment on cognition has produced inconsistent results. We found significant improvement in frontal lobe functions, visual memory and motor speed one year after treatment independent of the treatment type (best medical treatment, carotid artery stenting, carotid artery endarterectomy); providing evidence for ‘treatment-induced’ cognitive plasticity. Baseline performance was negatively associated with improvement in various cognitive functions after training in very preterm-born children and after treatment in patients with carotid artery stenosis. The present synopsis aims to integrate these findings into the current and relevant literature, and discuss consequences as well as methodological considerations resulting from the studies constituting the thesis at hand.