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Ziel der vorliegenden Studie war es, mögliche Verbesserungen in der motorischen Performanz nach einem unilateralen motorischen Training (Arm-Fähigkeits-Training, AFT, Platz, 2004) der nicht-dominanten Hand von Gesunden sowie mögliche Transfereffekte auf die nicht-trainierte rechte Hand zu detektieren und des Weiteren mit Hilfe von funktioneller Magnetresonanztomographie (fMRT, durchgeführt vor und nach dem Training) zu untersuchen, inwieweit sich solche Veränderungen auf zerebraler, zerebellärer sowie Basalganglien-Ebene abbilden lassen. Im Rahmen des motorischen Trainings trainierten wir über zwei Wochen hinweg die linke Hand von stark rechtshändigen gesunden Studienteilnehmern mit einem umfangreichen Training (AFT, entwickelt für Patienten mit leichter bis mittelschwerer Armlähmung, z.B. nach Schlaganfall; bestehend aus acht unterschiedlichen Aufgaben zum Training unterschiedlicher motorischer Fähigkeiten). Die motorische Performanz wurde sowohl für die trainierte linke als auch für die nichttrainierte rechte Hand vor und nach der Trainingsperiode gemessen, wobei u.a. die folgenden funktionellen Einheiten als Maß für den Trainingserfolg und mögliche Transfereffekte gebildet wurden: sequentielle Fingerbewegungen (AFT-Tippbewegung), Griffkraft (durchschnittliche maximale Griffkraft) sowie visuell geführte Bewegungen (Durchschnittswert aus drei unterschiedlichen AFT-Aufgaben: AFT-Zielbewegungen, AFT-Kreise durchstreichen und AFT-Labyrinth). Funktionelle Bildgebung wurde sowohl bei der Ausführung von Bewegungen mit der trainierten linken als auch bei der Ausführung mit der nicht-trainierten rechten Hand durchgeführt und beinhaltete eine Kraftmodulationsaufgabe (fMRT- Faustschluss; Faustschlussbewegung), sequentielle Fingerbewegungen (fMRT-Fingersequenz, Tipp-Bewegung) und eine Schreibaufgabe (fMRT-Schreiben, visuell geführte Bewegung). Nach der Trainingsperiode waren die Verbesserungen der Ausführung von sequentiellen Finger-bewegungen für beide Hände vergleichbar, wohingegen sich für die Ausführung von visuell geführten Bewegungen ein größerer Trainingseffekt für die trainierte Hand zeigte. Für die Griffkraft konnten wir keine signifikanten Veränderungen beobachten. Bei der fMRT zeigte sich während der Ausführung der fMRT-Fingersequenz über die Zeit hinweg eine Reduktion der Aktivität im supplementär-motorischen Areal, im dorsolateralen präfrontalen Kortex, in parietalen kortikalen Arealen und lateralen zerebellären Arealen. Während des fMRT-Schreibens mit der linken Hand zeigte die laterale zerebrale Hemisphäre außerdem eine reduzierte Aktivität, wohingegen die Aktivität der anterioren zerebellären Hemisphäre zugenommen hatte. Eine initial ausgeprägte anteriore zerebelläre Aktivität stellte einen Prädiktor für ein gutes Trainingsergebnis bei der Finger-Sequenz sowie bei visuell geführten Bewegungen dar. Für die fMRT-Faustschluss-Aufgabe fanden wir eine Zunahme der Aktivität im Striatum. Alles in allem resultierte ein umfangreiches Langzeittraining der nicht-dominanten Hand von gesunden Probanden in deutlichen Verbesserungen der motorischen Performanz und es zeigte sich ein unterschiedlicher intermanueller Lerntransfer je nach getestetem Bewegungstyp (sequentielle Fingerbewegungen, Griffkraft, visuell geführte Bewegungen). Während die Aktivität kortikaler motorischer Areale über die Zeit hinweg abnahm, schienen die Aktivität der anterioren zerebellären Hemisphäre und des Striatums zunehmende Ressourcen nach einem motorischen Langzeittraining zu repräsentieren.

Brain aging even in healthy older adults is characterized by a decline in cognitive functions including memory, learning and attention. Among others, memory is one of the major cognitive functions affected by aging. Understanding the mechanisms underlying age-related memory decline may help pave the road for novel treatment strategies. Here, we tried to elucidate the neural correlates associated with memory decline using structural and functional neuroimaging and neuromodulation with transcranial direct current stimulation (tDCS). Over the course of three studies, we investigated 1) the influence of white matter integrity and grey matter volume on memory performance in healthy older adults, 2) the role of functional coupling within the memory network in predicting memory performance and the impact of tDCS in modulating retrieval performance in healthy older adults, 3) the effect of tDCS over the sensorimotor cortex on cognitive performance in young adults. MRI was used to study associations of cognitive performance with white matter integrity and grey matter volume, and examine their causal relationship in the course of aging. White matter integrity was assessed by acquiring diffusion tensor imaging (DTI) and performing deterministic tractography based on constrained spherical deconvolution. Grey matter volume was estimated using fully automated segmentation. Both white matter integrity and grey matter volume were correlated with behavioral data of a verbal episodic memory task. Percentage of correct answers at retrieval was used to measure memory performance (Manuscript 1). In addition, anodal tDCS (atDCS) (1 mA, 20 min) was applied over CP5 (left temporoparietal cortex) to modulate memory formation in healthy older adults. Participants underwent resting-state fMRI before the stimulation. Functional connectivity analysis was performed to determine whether functional coupling within the memory network predicted initial memory performance, and to examine its association to tDCS-induced enhancement effect (Manuscript 2). Finally, atDCS (1 mA, 20 min) was applied over C3 (left sensorimotor cortex) to explore the effect of tDCS over the sensorimotor cortex on cognitive performance in young adults. During the stimulation, participants performed three tasks; gestural task, attentional load task and simple reaction time task (Manuscript 3). Results showed that volumes of the left dentate gyrus (DG) and tractography-based fractional anisotropy (FA) of individual fornix pathways were positively related to memory retrieval in older adults. Brain-behavior associations were observed for correct rejections rather than hits of memory performance, indicating specificity of memory network functioning for detecting false associations. Thus, the data suggested a particular role of neural integrity that promotes successful memory retrieval in older adults. Subsequent mediation analysis showed that left DG volume mediated the effect of fornix FA on memory performance (48%), corrected for age, revealing a crucial role of hippocampal pathway microstructure in modulating memory performance in older adults (Manuscript 1). tDCS results showed that atDCS led to better retrieval performance and increasing learning curves, indicating that brain stimulation can induce plasticity of episodic memory processes in older adults. Combining tDCS and fMRI, hippocampo-temporoparietal functional connectivity was positively associated with initial memory performance in healthy older adults and was positively correlated with the magnitude of individual tDCS-induced enhancement, suggesting that individual tDCS responsiveness may be determined by intrinsic network coupling (Manuscript 2). Finally, our findings suggested that atDCS over left sensorimotor cortex reduced reaction times in the gestural-verbal integration task, specifically for incongruent pairs of gestures and verbal expressions, indicating the role of sensorimotor cortex in gestural-verbal integration in young adults (Manuscript 3). The results of all three studies may help to elucidate age-related structural deterioration and functional coupling network underlying cognitive processes in healthy adults. Furthermore, these studies emphasized the importance of interventions like tDCS in modulating cognitive performance, specifically episodic verbal memory and gestural-verbal integration. By unveiling the specific role of brain structures and functional network coupling as well as the role of tDCS in modulating cognitive performance, our results contribute to a better understanding of brain-behavior associations, and may help to develop clinical interventional approaches, tailored for specific cognitive functions in aging.

The fear of somatic sensations is highly relevant in the etiology and maintenance of various disorders. Nevertheless, little is known about this fear of body symptoms and many questions are yet unanswered. Especially physiological studies on interoceptive threat are rare. Therefore, the present thesis investigated defensive mobilization, autonomic arousal, and brain activation during the anticipation of, exposure to, and recovery from unpleasant body sensations. Symptoms were provoked using a standardized hyperventilation procedure in a sample of high (and as controls: low) anxiety sensitive individuals - a population high at risk for developing a panic disorder and high in fear of internal body symptoms. In study one, anxious apprehension was investigated during anticipation of interoceptive threat (somatic sensations evoked by hyperventilation) and exteroceptive threat (electric shock). Symptom reports, autonomic arousal, and defensive mobilization assessed by the startle eyeblink response were analyzed. Extending the knowledge on anticipation of interoceptive threat, study two investigated the neural networks activated during anxious apprehension of unpleasant body sensations. Symptom reports and startle response data were collected during a learning session after which participants high and low in fear of somatic symptoms attended a fMRI session anticipating threat (hyperventilation – learned to provoke unpleasant symptoms) or safety (normal breathing). Study three examined the actual exposure to internal body symptoms, investigating symptoms reports, autonomic arousal, and the startle eyeblink response during guided breathing (hyperventilation and, as a non-provocative comparison condition, normoventilation) and during recovery. And finally, study four addressed changes in the defensive mobilization during repeated interoceptive exposure via a hyperventilation procedure. High and low anxiety sensitive persons went through two guided hyperventilation and normoventilation procedures that were spaced one week apart while symptom reports, breathing parameters, and startle response magnitudes were measured. In study one it was demonstrated that the anticipation of exteroceptive threat led to a defensive and autonomic mobilization in high and low anxiety sensitive individuals, while during interoceptive threat only high anxiety sensitive participants were characterized by a potentiated startle response and autonomic activation. Imaging data of study two revealed that 1) during anticipation of hyperventilation all participants were characterized by an increased activation of a fear network consisting of anterior insula/ orbitofrontal cortex and rostral parts of the dorsal anterior cingulate cortex/ dorsomedial prefrontal cortex, 2) high fear individuals showed higher anxious apprehension than low fear controls during the entire context (safe and threat conditions), indexed by an overall stronger activation of the described network, and 3) while low fear controls learned that (undisclosed to all participants) in the fMRI scanner the threat cue was not followed by an unpleasant hyperventilation task, high fear participants continued to show stronger fear network activation to this cue. In study three it was demonstrated, that the hyperventilation procedure led to a marked increase in somatic symptoms and to autonomic arousal. While high and low anxiety sensitive groups did not differ during hyperventilation, in the early recovery only high anxiety sensitive individuals showed defensive mobilization, indicated by potentiated startle response magnitudes, and increased autonomic arousal after hyperventilation as compared to after normoventilation. Substantiating these findings, in study four all participants reported more symptoms during hyperventilation than during normoventilation, in both sessions. Nevertheless, only high anxiety sensitive participants displayed a potentiation of startle response magnitudes after the first hyper- vs. normoventilation. One week later, when the exercise was repeated this potentiation was no longer present and thus both groups no longer differed in their defensive mobilization. Even more, the number of reported baseline symptoms decreased from session one to session two in the high-AS group. While high anxiety sensitive persons reported increased baseline anxiety symptoms in session one, groups did not anymore differ in session two. These data indicate that the standardized hyperventilation procedure is a valid paradigm to induce somatic symptoms. Moreover, it induces anxious apprehension especially in persons highly fearful of internal body symptoms. The repetition of interoceptive exposure, however, reduces associated fear in highly fearful individuals. Thus, this paradigm might provide an innovative method to study anxious apprehension and also treatment effects in patients with panic disorder. The present findings are integrated and discussed in the light of the current literature.

Fear is an emotional state, characterized by the activation of a defense system that is designed to ensure the organism’s survival. This system enables a rapid recognition of threats and organizes defensive response patterns in order to adaptively cope with the threatening environment. Yet, to ensure its flexibility under changing environmental conditions, inhibitory pathways exist that modulate the activation of this defense system, if a previously threatening cue no longer predicts any harm – a memory-formatting process referred to as fear extinction, leading to a reduction of defensive responding. Fear extinction is presumed to at least partially underlie exposure treatment of anxiety disorders, which is why the facilitation of this learning process may promote such treatment’s efficacy. Animal models suggested, that the stimulation of the vagus nerve or the superior colliculus (SC) – a midbrain structure mediating visual attentional processing – target these inhibitory extinction pathways and, thus, facilitate fear extinction. However, as it is unclear whether similar mechanisms exist in humans, this thesis manuscript examined how non-invasive stimulation of these inhibitory pathways by transcutaneous vagus nerve stimulation (tVNS) or SC-recruiting visual attentional manipulation impact on human fear extinction. To this end, we conducted three studies using multiple-day single-cue fear conditioning and extinction paradigms. First, we elaborated on fear that is established in these paradigms by examining defensive responding that is elicited by an innocuous conditioned stimulus, which has either been paired (fear learning group) with an aversive unconditioned stimulus (US; an electric shock) or was unpaired (control group; study 1). During the following extinction training, either tVNS vs. sham stimulation was applied (study 1, study 2) or participants were instructed, to either generate saccadic eye movements (strong SC activation) vs. smooth eye pursuits (low SC activation; study 3). During subsequent sessions, extinction consolidation as well as the short- and long-term extinction recall was tested (study 2, study 3). Conditioned fear in the fear learning group was characterized by elevated cognitive risk assessments (US-expectancy ratings), as well as increased cardiac deceleration and startle reflex potentiation compared to controls. Cardiac deceleration was positively correlated to startle potentiation, but was decoupled from cognitive risk assessments (study 1). Initial, short- and long-term extinction of these defensive responses was facilitated by tVNS on all three response levels (cognitive, physiological, behavioral; study 1, study 2). In contrast, saccades facilitated initial extinction only for physiological and behavioral elements of the defensive response pattern, while extinction consolidation and recall was impaired by any eye movement manipulation (study 3) for physiological and behavioral indicators of defensive responding. Taken together, the data of the experimental series suggest, that on a behavioral level, conditioned fear may best be conceived as attentive immobility – a defense strategy elicited by inevitable distal threats, that is uniformly expressed across species and is accompanied by cardiac deceleration and startle reflex potentiation. In addition, it was shown that such rather automatic defensive adaptations are independent from verbally expressed threat expectancies. As expected, tVNS impacted on fear extinction on both levels, strongly in line with the suggestion, that vagal stimulation activates cortical and subcortical neural pathways involved in extinction learning, consolidation and recall. TVNS may, thus, be a promising adjuvant for exposure treatment of mental disorders. In contrast, SC-recruiting visual attentional manipulation only affected subcortically mediated defensive responding, in line with rodent findings, indicating that the SC specifically inhibits subcortical parts of the neural defense system. However, as extinction recall was impaired by any type of visual attentional manipulation, this appeared to have functioned as a form of avoidance, initially attenuating fear but preventing extinction consolidation and, thus, impairing sustained fear reduction. Both non-invasive stimulation techniques may therefore increase initial defensive flexibility in the face of no-longer threat-signaling stimuli, but only tVNS may achieve long-term effects on multiple response levels.