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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
21

The Impact of Genome-Wide Supported Schizophrenia Risk Variants in the Neurogranin Gene on Brain Structure and Function

Walton, Esther, Geisler, Daniel, Hass, Johannes, Liu, Jingyu, Turner, Jessica, Yendiki, Anastasia, Smolka, Michael N., Ho, Beng-Choon, Manoach, Dara S., Gollub, Randy L., Rößner, Veit, Calhoun, Vince D., Ehrlich, Stefan 06 February 2014 (has links)
The neural mechanisms underlying genetic risk for schizophrenia, a highly heritable psychiatric condition, are still under investigation. New schizophrenia risk genes discovered through genome-wide association studies (GWAS), such as neurogranin (NRGN), can be used to identify these mechanisms. In this study we examined the association of two common NRGN risk single nucleotide polymorphisms (SNPs) with functional and structural brain-based intermediate phenotypes for schizophrenia. We obtained structural, functional MRI and genotype data of 92 schizophrenia patients and 114 healthy volunteers from the multisite Mind Clinical Imaging Consortium study. Two schizophrenia-associated NRGN SNPs (rs12807809 and rs12541) were tested for association with working memory-elicited dorsolateral prefrontal cortex (DLPFC) activity and surface-wide cortical thickness. NRGN rs12541 risk allele homozygotes (TT) displayed increased working memory-related activity in several brain regions, including the left DLPFC, left insula, left somatosensory cortex and the cingulate cortex, when compared to non-risk allele carriers. NRGN rs12807809 non-risk allele (C) carriers showed reduced cortical gray matter thickness compared to risk allele homozygotes (TT) in an area comprising the right pericalcarine gyrus, the right cuneus, and the right lingual gyrus. Our study highlights the effects of schizophrenia risk variants in the NRGN gene on functional and structural brain-based intermediate phenotypes for schizophrenia. These results support recent GWAS findings and further implicate NRGN in the pathophysiology of schizophrenia by suggesting that genetic NRGN risk variants contribute to subtle changes in neural functioning and anatomy that can be quantified with neuroimaging methods.
22

Fear Processing in Dental Phobia during Crossmodal Symptom Provocation: An fMRI Study

Hilbert, Kevin, Evens, Ricarda, Maslowski, Nina Isabel, Wittchen, Hans-Ulrich, Lüken, Ulrike 09 July 2014 (has links)
While previous studies successfully identified the core neural substrates of the animal subtype of specific phobia, only few and inconsistent research is available for dental phobia. These findings might partly relate to the fact that, typically, visual stimuli were employed. The current study aimed to investigate the influence of stimulus modality on neural fear processing in dental phobia. Thirteen dental phobics (DP) and thirteen healthy controls (HC) attended a block-design functional magnetic resonance imaging (fMRI) symptom provocation paradigm encompassing both visual and auditory stimuli. Drill sounds and matched neutral sinus tones served as auditory stimuli and dentist scenes and matched neutral videos as visual stimuli. Group comparisons showed increased activation in the insula, anterior cingulate cortex, orbitofrontal cortex, and thalamus in DP compared to HC during auditory but not visual stimulation. On the contrary, no differential autonomic reactions were observed in DP. Present results are largely comparable to brain areas identified in animal phobia, but also point towards a potential downregulation of autonomic outflow by neural fear circuits in this disorder. Findings enlarge our knowledge about neural correlates of dental phobia and may help to understand the neural underpinnings of the clinical and physiological characteristics of the disorder.
23

The effect of body posture on cognitive performance: a question of sleep quality

Mühlhan, Markus, Marxen, Michael, Landsiedel, Julia, Malberg, Hagen, Zaunseder, Sebastian 14 July 2014 (has links)
Nearly all functional magnetic resonance imaging (fMRI) studies are conducted in the supine body posture, which has been discussed as a potential confounder of such examinations. The literature suggests that cognitive functions, such as problem solving or perception, differ between supine and upright postures. However, the effect of posture on many cognitive functions is still unknown. Therefore, the aim of the present study was to investigate the effects of body posture (supine vs. sitting) on one of the most frequently used paradigms in the cognitive sciences: the N-back working memory paradigm. Twenty-two subjects were investigated in a randomized within-subject design. Subjects performed the N-back task on two consecutive days in either the supine or the upright posture. Subjective sleep quality and chronic stress were recorded as covariates. Furthermore, changes in mood dimensions and heart rate variability (HRV) were assessed during the experiment. Results indicate that the quality of sleep strongly affects reaction times when subjects performed a working memory task in a supine posture. These effects, however, could not be observed in the sitting position. The findings can be explained by HRV parameters that indicated differences in autonomic regulation in the upright vs. the supine posture. The finding is of particular relevance for fMRI group comparisons when group differences in sleep quality cannot be ruled out.
24

Instructions matter: a comparison of baseline conditions for cognitive emotion regulation paradigms

Diers, Kersten, Weber, Fanny, Brocke, Burkhard, Strobel, Alexander, Schönfeld, Sabine 15 July 2014 (has links)
The choice of a meaningful baseline condition is a crucial issue for each experimental design. In the case of cognitive emotion regulation, it is common to either let participants passively view emotional stimuli without any further specific instructions or to instruct them to actively attend to and permit any arising emotions, and to contrast one of these baseline conditions with a regulation condition. While the “view” strategy can be assumed to allow for a more spontaneous emotional response, the “permit” strategy may result in a more pronounced affective and cognitive response. As these conceptual differences may be associated with differences both in subjective emotional experience and neural activation, we compared these two common control conditions within a single functional magnetic resonance imaging (fMRI) experiment, during which participants were instructed to either passively view a set of unpleasant and neutral pictures or to actively permit any emotions arising in response to the unpleasant pictures. Trial-by-trial ratings confirmed that participants perceived the unpleasant pictures as more arousing than the neutral pictures, but also indicated higher subjective arousal during the “permit negative” as compared to the “view negative” and “view neutral” conditions. While both the “permit negative” and “view negative” conditions led to increased activation of the bilateral amygdala when contrasted with the passive viewing of neutral pictures, activation in the left amygdala was increased in response to the “permit” instruction as compared to the “view” instruction for unpleasant pictures. The increase in amygdala activation in both the “permit” and “view” conditions renders both strategies as suitable baseline conditions for studies of cognitive emotion regulation. Conceptual and activation differences, however, indicate that these two variants are not exchangeable and should be chosen depending on the experimental context.
25

Anticipating agoraphobic situations: the neural correlates of panic disorder with agoraphobia

Wittmann, A., Schlagenhauf, F., Guhn, A., Lueken, U., Gaehlsdorf, C., Stoy, M., Bermpohl, F., Fydrich, T., Pfleiderer, B., Bruhn, H., Gerlach, A. L., Kircher, T., Straube, B., Wittchen, H.-U., Arolt, V., Heinz, A., Ströhle, A. 11 June 2020 (has links)
Background: Panic disorder with agoraphobia is characterized by panic attacks and anxiety in situations where escape might be difficult. However, neuroimaging studies specifically focusing on agoraphobia are rare. Here we used functional magnetic resonance imaging (fMRI) with disorder-specific stimuli to investigate the neural substrates of agoraphobia. Method. We compared the neural activations of 72 patients suffering from panic disorder with agoraphobia with 72 matched healthy control subjects in a 3-T fMRI study. To isolate agoraphobia-specific alterations we tested the effects of the anticipation and perception of an agoraphobia-specific stimulus set. During fMRI, 48 agoraphobia-specific and 48 neutral pictures were randomly presented with and without anticipatory stimulus indicating the content of the subsequent pictures (Westphal paradigm). Results: During the anticipation of agoraphobia-specific pictures, stronger activations were found in the bilateral ventral striatum and left insula in patients compared with controls. There were no group differences during the perception phase of agoraphobia-specific pictures. Conclusions: This study revealed stronger region-specific activations in patients suffering from panic disorder with agoraphobia in anticipation of agoraphobia-specific stimuli. Patients seem to process these stimuli more intensively based on individual salience. Hyperactivation of the ventral striatum and insula when anticipating agoraphobiaspecific situations might be a central neurofunctional correlate of agoraphobia. Knowledge about the neural correlates of anticipatory and perceptual processes regarding agoraphobic situations will help to optimize and evaluate treatments, such as exposure therapy, in patients with panic disorder and agoraphobia.
26

Neural Correlates of Procedural Variants in Cognitive-Behavioral Therapy: A Randomized, Controlled Multicenter fMRI Study

Straube, Benjamin, Lueken, Ulrike, Jansen, Andreas, Konrad, Carsten, Gloster, Andrew T., Gerlach, Alexander L., Ströhle, Andreas, Wittmann, André, Pfleiderer, Bettina, Gauggel, Siegfried, Wittchen, Ulrich, Arolt, Volker, Kircher, Tilo 05 August 2020 (has links)
Background: Cognitive behavioral therapy (CBT) is an effective treatment for panic disorder with agoraphobia (PD/AG). It is unknown, how variants of CBT differentially modulate brain networks involved in PD/AG. This study was aimed to evaluate the effects of therapist-guided (T+) versus selfguided (T–) exposure on the neural correlates of fear conditioning in PD/AG. Method: In a randomized, controlled multicenter clinical trial in medication-free patients with PD/AG who were treated with 12 sessions of manualized CBT, functional magnetic resonance imaging (fMRI) was used during fear conditioning before (t1) and after CBT (t2). Quality-controlled fMRI data from 42 patients and 42 healthy subjects (HS) were obtained. Patients were randomized to two variants of CBT (T+, n = 22, and T–, n = 20). Results: The interaction of diagnosis (PD/AG, HS), treatment group (T+, T–), time point (t1, t2) and stimulus type (conditioned stimulus: yes, no) revealed activation in the left hippocampus and the occipitotemporal cortex. The T+ group demonstrated increased activation of the hippocampus at t2 (t2 > t1), which was positively correlated with treatment outcome, and a decreased connectivity between the left inferior frontal gyrus and the left hippocampus across time (t1 > t2). Conclusion: After T+ exposure, contingency-encoding processes related to the posterior hippocampus are augmented and more decoupled from processes of the left inferior frontal gyrus, previously shown to be dysfunctionally activated in PD/AG. Linking single procedural variants to neural substrates offers the potential to inform about the optimization of targeted psychotherapeutic interventions.
27

Stimulationsintensitäten in kognitiven Paradigmen

Kaminski, Jakob 08 October 2015 (has links)
Die transkranielle Magnetstimulation (TMS) ist zu einer essentiellen Untersuchungsmethode der Neurowissenschaften geworden. Sie ermöglicht es, mittels eines kurzen, starken Magnetfeldes, Neuronen im Gehirn anzuregen und kurzfristig deren Aktivität zu modulieren. Diese Effekte sind allerdings nur bei Stimulation des motorischen Kortexes als motorisch evozierte Potentiale (MEP) an peripheren Muskeln direkt messbar. Hier lässt sich auch eine individuelle Reizschwelle (engl. motorthreshold, MT) bestimmen, die sich allerdings von Proband zu Proband stark unterscheidet. Bei Stimulation außerhalb des motorischen Kortexes, bei der durch Änderung der Aktivität einer umschriebenen Neuronengruppe, behaviorale Effekte erzeugt werden sollen, existiert ein solches direktes Maß der neuronalen Erregbarkeit nicht, weshalb häufig die Stimulationsintensität an die individuelle MT angepasst wird. Die vorliegenden Arbeit stellt, diese Anpassung der Intensität in Frage. Hierzu erhielten Probanden vor der Durchführung eines kognitiven Tests über einer mittels funktioneller Magnetresonanztomographie (fMRT) ermittelten Region des präfrontalen Kortex eine Stimulation. Die Intensität wurde hierbei einmal an die MT angepasst und einmal nicht. Erstmals konnte mittels einer Korrelationsanalyse gezeigt werden, dass es einen Zusammenhang zwischen der Sensitivität des präfrontalen Kortexes und der des Motorkortexes gibt. Dieser Zusammenhang kann zur nachträglichen Korrektur der behavioralen Daten genutzt werden, da die MT die zwischen den Probanden bestehenden relativen Unterschiede erklärt.
28

Kombinierte Analyse funktioneller PET/MRT Veränderungen des zentralnervösen Noradrenalin-/Serotonin-Netzwerkes und deren Einfluss auf das emotionale Wohlbefinden bei Adipositas

Melasch, Juliana Teresa 22 June 2017 (has links)
Die grundlegenden neurobiologischen Mechanismen für das Zusammenwirken eines pathologisch erhöhten Körpergewichts und der gewichts-assoziierten emotionalen Belastung sind bisher noch wenig erforscht. Die vorliegende Arbeit untersucht gezielt Abweichungen der regionalen Transporter-Verfügbarkeiten mittels Positronen-Emissions-Tomographie (PET) mit hochselektiven Marker für den Noradrenalin- (NET) sowie den Serotonin-(5-Hydroxytryptamin-)transporter (5-HTT) und funktioneller Magnetresonanztomographie (fMRT) sowie damit verbundene Alterationen der neuronalen Ruhe-(resting-state-)Aktivität konnektierter Hirnregionen. Die Ergebnisse der kombinierten PET/fMRT Analyse wurden mit zwei neuropsychologischen Scores zur Erfassung allgemeiner und gewichtsabhängiger emotionaler Veränderungen korreliert. Insgesamt 48 Teilnehmer (Body-Mass-Index [BMI]: 19 - 50 kg/m2) erhielten eine fMRT und eine PET mittels NET-selektivem [11C]MRB (n = 20) beziehungsweise 5-HTT-selektivem [11C]DASB (n = 28). Die PET ergab im Hypothalamus eine tendentielle, BMI-abhängig verminderte Verfügbarkeit des NET, nicht jedoch des 5-HTT. Zusätzlich fand sich bei steigendem BMI innerhalb beider Neurotransmitternetzwerke in Abhängigkeit zur jeweiligen Transporter-Verfügbarkeit eine teils geschlechtsspezifisch verstärkte funktionelle Konnektivität zwischen dem Hypothalamus und Hirnregionen der Verarbeitung und Bewertung von Nahrungsreizen. Korrelationen der lokalen resting-state Aktivitäten mit den neuropsychologischen Scores lassen vermuten, dass diese Regionen zudem auch mit langfristigen, negativen Veränderungen des gewichtsabhängigen emotionalen Wohlbefindens assoziiert sind. Insgesamt spielen diese beiden zentralen Neurotransmitter-Systeme eine wichtige Rolle in der Modulation von Netzwerken zur Regulation des gewichtsabhängigen emotionalen Wohlbefindens und könnten somit wichtige Anhaltspunkte für neue pharmakologische Ansätze bereitstellen.
29

Interindividual Differences in Mid-Adolescents in Error Monitoring and Post-Error Adjustment

Rodehacke, Sarah, Mennigen, Eva, Müller, Kathrin U., Ripke, Stephan, Jacob, Mark J., Hübner, Thomas, Schmidt, Dirk H. K., Goschke, Thomas, Smolka, Michael N. 14 July 2014 (has links) (PDF)
A number of studies have concluded that cognitive control is not fully established until late adolescence. The precise differences in brain function between adults and adolescents with respect to cognitive control, however, remain unclear. To address this issue, we conducted a study in which 185 adolescents (mean age (SD) 14.6 (0.3) years) and 28 adults (mean age (SD) 25.2 (6.3) years) performed a single task that included both a stimulus-response (S-R) interference component and a task-switching component. Behavioural responses (i.e. reaction time, RT; error rate, ER) and brain activity during correct, error and post-error trials, detected by functional magnetic resonance imaging (fMRI), were measured. Behaviourally, RT and ER were significantly higher in incongruent than in congruent trials and in switch than in repeat trials. The two groups did not differ in RT during correct trials, but adolescents had a significantly higher ER than adults. In line with similar RTs, brain responses during correct trials did not differ between groups, indicating that adolescents and adults engage the same cognitive control network to successfully overcome S-R interference or task switches. Interestingly, adolescents with stronger brain activation in the bilateral insulae during error trials and in fronto-parietal regions of the cognitive control network during post-error trials did have lower ERs. This indicates that those mid-adolescents who commit fewer errors are better at monitoring their performance, and after detecting errors are more capable of flexibly allocating further cognitive control resources. Although we did not detect a convincing neural correlate of the observed behavioural differences between adolescents and adults, the revealed interindividual differences in adolescents might at least in part be due to brain development.
30

High fluid intelligence and analogical reasoning

Preusse, Franziska 13 December 2011 (has links)
Hitherto, previous studies on the cerebral correlates of fluid intelligence (fluIQ) used tasks that did not exclusively demand fluIQ, or were restricted to participants of average fluIQ (ave-fluIQ) solving intelligence test items of varying difficulty, thus not allowing assumptions on interindividual differences in fluIQ. Geometric analogical reasoning (GAR) demands fluIQ very purely and thus is an eligible approach for research on interindividual differences in fluIQ. In a first study, we examined the cerebral correlates of GAR, and showed the involvement of parietal and frontal brain regions. This is in line with the assumptions of the parieto-frontal integration theory (P-FIT) of intelligence and with literature reports for other visuo-spatial tasks. Building upon these findings, we report results from a second study with high fluIQ (hi-fluIQ) and ave-fluIQ school students solving a GAR task. Again in line with the P-FIT model, we demonstrated that the parieto-frontal network is involved in GAR in both groups. However, the extent of task-related brain activation in parietal and frontal brain regions was differentially modulated by fluIQ. Our results thus partly run counter to the postulates of the neural efficiency hypothesis, which assumes a negative brain activation-intelligence relationship. We conclude that this relationship is not generally unitary; rather, it can be conjectured that the adaptive and flexible modulation of brain activation is characteristic of hi-fluIQ. Knowledge on the stability of the cerebral correlates of hi-fluIQ during adolescence had been sparse. To elucidate this field, we examined the follow-up stability of the cerebral correlates of GAR in hi-fluIQ in a third study. We demonstrated that the relevant brain network is in place already at age 17 and that improvements in behavioral performance at age 18 due to task familiarity are indicative of more efficient use of the cerebral resources available. / Bisherige Studien zu zerebralen Korrelaten fluider Intelligenz (fluIQ) haben Aufgaben verwendet, die fluIQ nicht in Reinform erfordern oder haben Probanden mit durchschnittlicher fluIQ (ave-fluIQ) beim Lösen von Intelligenztestaufgaben mit variierenden Schwierigkeitsstufen untersucht und ermöglichen daher keine Aussagen zu interindividuellen Unterschieden in fluIQ. Geometrisches analoges Schließen (GA) beansprucht fluIQ in Reinform und eignet sich daher als differentielles Untersuchungsparadigma. In einer ersten Studie haben wir die zerebralen Korrelate des GA untersucht und nachgewiesen, dass parietale und frontale Hirnregionen involviert sind. Dies steht im Einklang mit der parieto-frontalen Integrationstheorie (P-FIT) der Intelligenz und mit Literaturberichten zu anderen visuell-räumlichen Aufgaben. Aufbauend auf diesen Befunden berichten wir Ergebnisse einer zweiten Studie, in der Schüler mit hoher fluIQ (hi-fluIQ) und ave-fluIQ GA-Aufgaben lösten. In Übereinstimmung mit den Annahmen des P-FIT-Modells konnten wir zeigen, dass GA in beiden Gruppen das parieto-frontale Netzwerk beansprucht. Das Ausmaß der Hirnaktivierung wurde jedoch differentiell durch fluIQ moduliert. Unsere Ergebnisse widersprechen damit teilweise den Postulaten der neuralen Effizienztheorie, die einen negativen Zusammenhang zwischen Hirnaktivierung und Intelligenz annimmt. Wir schlussfolgern, dass dieser Zusammenhang nicht generell einseitig gerichtet ist, sondern die flexible Modulation von Hirnaktivierung charakteristisch für hi-fluIQ ist. Befunde zur Stabilität zerebraler Korrelate von hi-fluIQ in der Jugend waren bisher rar. Um dieses Feld zu beleuchten, haben wir die follow-up-Stabilität zerebraler Korrelate des GA in der hi-fluIQ Gruppe in einer dritten Studie untersucht. Wir konnten zeigen, dass das relevante zerebrale Netzwerk schon mit 17 Jahren etabliert ist und Performanzverbesserungen über die Zeit für eine effizientere Nutzung der verfügbaren zerebralen Ressourcen sprechen.

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