Recently, the use of resting-state functional MRI (rsfMRI) has been extended beyond the assessment of the brain’s functional organization to the monitoring of various aspects of cerebral hemodynamics. This has found practical applications in various disease states, particularly in cerebrovascular disorders, and has substantial methodological implications for the use of rsfMRI in clinical research. In this talk, I will: ● Discuss recent findings regarding the physiological sources and mechanisms of the components of the blood oxygenation level dependent (BOLD) signal that reflect the brain’s hemodynamic status ● Present recent methodological and practical developments to established rsfMRI-based methods for the assessment of blood flow within the brain ● Present some upcoming techniques for extracting hemodynamic parameters from rsfMRI data and their potential use in various diseases. [mehr]

Computational visual neuroscience has come a long way in the past 10 years. For the first time, we have fully explicit, image-computable models that can recognise objects with near-human accuracy, and predict brain activity in high-level visual regions. I will present evidence that diverse deep neural network architectures all predict brain representations well, and that task-training and subsequent reweighting of model features is critical to this high performance. However, vision is not yet explained. The most successful models are deep neural networks that have been supervised using ground-truth labels for millions of images. Brains have no such access to the ground truth, and must instead learn directly from sensory data. Unsupervised deep learning, in which networks learn statistical regularities in their data by compressing, extrapolating or predicting images and videos, is an ecologically feasible alternative. I will show that an unsupervised deep network trained on an environment of 3D rendered surfaces with varying shape, material and illumination, spontaneously comes to encode those factors in its internal representations. Most strikingly, the network makes patterns of errors in its perception of material which follow, on an image-by-image basis, the patterns of errors made by human observers. Unsupervised deep learning may provide a coherent framework for how our perceptual dimensions arise. [mehr]

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When studying perception, the focus is typically on neural signals in the brain. However, bodily signals can also influence perception. The underlying mechanisms of such effects are poorly understood. In my talk, I will demonstrate how the heart influences perception. Specifically, we have recently identified two heart-related factors, heartbeat-evoked potentials (HEP) and cardiac-phase, both of which influence perception. In an EEG study, we investigated psychophysical and neural mechanisms underlying the influence of cardiac-phase and HEP on somatosensory detection. In a follow-up EEG study, we tested the replicability of these heartbeat-related effects in a modified experimental paradigm and further explored the neural sources of the HEP modulations associated with perception. Lastly, using simultaneous EEG-TMS, we investigated whether the effect of heartbeat-related factors might be due to general changes in excitability. Together, this talk will highlight how cardiac signals are integrated into our conscious perception of the world. [mehr]

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*** Zoom Link *** https://gwdg.zoom.us/j/82649211062 *** Interoception refers to the set of physiological and cognitive processes that are involved in determining the physiological condition of the body. Recently, the number of studies showing the extent to which interoceptive signals such as heartbeat modulate cognition and perception in the healthy and atypical human brain has markedly increased. This has been shown by measuring participants’ responses to sensory events that are locked to distinct phases of the cardiac cycle. These studies have shown that perception and cognition are modulated by the phase of the cardiac cycle in which the stimuli were presented. However, it is unclear how these results relate to our everyday interaction with the world where sensory inputs are not presented according to our cardiac cycle, but rather actively sampled at one’s own pace. Moreover, if the phase of the cardiac cycle is an important modulator of perception and cognition, as previously proposed, then the way in which we actively sample the world should be similarly modulated by the phase of the cardiac cycle. One possibility is that we sample the world in a way that is linked to our cardiac signal and in this way optimize the sampling of our sensory inputs. Here, I will talk about a series of studies designed to test this hypothesis and I will discuss these results in relation to current theoretical models of interoception. [mehr]

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Interest in disorders of later life have grown in proportion with the increase of this population group in many societies. We are accustomed to see age as a confounder, so attempts to pinpoint group difference while adjusting for age effects often result in the removal of differences that may be crucial to understanding the aging process. In addition, age reflects between-subject variation (particularly in cross-sectional studies), as well as within-subject changes over time in repeat measures designs. Both are relevant clinically, as the importance of education or IQ for dementia diagnosis and the gradual development of vascular and cognitive risks in mid-life for accelerated ageing demonstrate. I will try to illustrate these issues with studies from UK Biobank and the EU Lifebrain Consortium, covering concepts such as brain-, cognitive age and -reserve, and the role of the natural history and life-time course of depression in its relation to biomarkers and putative aetiologies. [mehr]

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Neural activity is remarkably variable: Even for the very same stimulus, the brain´s response can differ from moment to moment. Although it has been hypothesized that changes of the system´s excitability may account for this variability, the underlying dynamics that link instantaneous brain state and stimulus processing remain poorly understood. Therefore, we studied the spatiotemporal organization of cortical excitability in a series of three somatosensory stimulation paradigms in humans, examining the interplay between pre-stimulus oscillatory state and short-latency somatosensory evoked potentials in the EEG, as well as their association with the consciously accessible stimulus percept. We found that these dynamics of excitability are (i) temporally structured in a special way (long-range temporal dependencies), (ii) linked to the perceived stimulus intensity already via first cortical responses, and (iii) organized with spatially confined, somatotopic patterns. Taken together, these findings may reflect a delicate balance between robustness and flexibility of neural responses to sensory stimuli, enabling the brain to adaptively change the neural encoding of even low-level stimulus features, such as the stimulus´ intensity. [mehr]

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What motivates us to do what we do? And why is it so incredibly difficult to do the right thing, even when we (think we) set our minds to it? Successful behavioural change is still a major challenge for people, both in clinical and non-clinical settings. This lack of flexibility, which often results in maladaptive behaviour of some kind, is what fascinates me and what broadly has been driving my research interest in real-world habits. In this talk, I would like to give you a concise overview of some of the studies I worked on regarding people’s ability to adjust to changes in learnt responses and reward probabilities (reversal learning, two-step task, outcome devaluation) in different target populations (e.g., disordered gambling, diet-induced obesity). Dopamine will be a red thread throughout the talk. Finally, I will discuss the idea that adaptive flexibility requires sufficient stability, and that it may be worth reconsidering the traditional dichotomous thinking in behavioural control research. [mehr]

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