TY  - JOUR
A1  - Stegmann, Yannik
A1  - Andreatta, Marta
A1  - Wieser, Matthias J.
T1  - The effect of inherently threatening contexts on visuocortical engagement to conditioned threat
JF  - Psychophysiology
N2  - Fear and anxiety are crucial for adaptive responding in life‐threatening situations. Whereas fear is a phasic response to an acute threat accompanied by selective attention, anxiety is characterized by a sustained feeling of apprehension and hypervigilance during situations of potential threat. In the current literature, fear and anxiety are usually considered mutually exclusive, with partially separated neural underpinnings. However, there is accumulating evidence that challenges this distinction between fear and anxiety, and simultaneous activation of fear and anxiety networks has been reported. Therefore, the current study experimentally tested potential interactions between fear and anxiety. Fifty‐two healthy participants completed a differential fear conditioning paradigm followed by a test phase in which the conditioned stimuli were presented in front of threatening or neutral contextual images. To capture defense system activation, we recorded subjective (threat, US‐expectancy), physiological (skin conductance, heart rate) and visuocortical (steady‐state visual evoked potentials) responses to the conditioned stimuli as a function of contextual threat. Results demonstrated successful fear conditioning in all measures. In addition, threat and US‐expectancy ratings, cardiac deceleration, and visuocortical activity were enhanced for fear cues presented in threatening compared with neutral contexts. These results are in line with an additive or interactive rather than an exclusive model of fear and anxiety, indicating facilitated defensive behavior to imminent danger in situations of potential threat.
KW  - anxiety
KW  - EEG
KW  - emotion
KW  - fear
KW  - heart rate
KW  - ssVEP
Y1  - 2023
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-312465
VL  - 60
IS  - 4
ER  - 
TY  - JOUR
A1  - Aboagye, B.
A1  - Weber, T.
A1  - Merdian, H. L.
A1  - Bartsch, D.
A1  - Lesch, K. P.
A1  - Waider, J.
T1  - Serotonin deficiency induced after brain maturation rescues consequences of early life adversity
JF  - Scientific Reports
N2  - Brain serotonin (5-HT) system dysfunction is implicated in depressive disorders and acute depletion of 5-HT precursor tryptophan has frequently been used to model the influence of 5-HT deficiency on emotion regulation. Tamoxifen (TAM)-induced Cre/loxP-mediated inactivation of the tryptophan hydroxylase-2 gene (Tph2) was used to investigate the effects of provoked 5-HT deficiency in adult mice (Tph2 icKO) previously subjected to maternal separation (MS). The efficiency of Tph2 inactivation was validated by immunohistochemistry and HPLC. The impact of Tph2 icKO in interaction with MS stress (Tph2 icKOxMS) on physiological parameters, emotional behavior and expression of 5-HT system-related marker genes were assessed. Tph2 icKO mice displayed a significant reduction in 5-HT immunoreactive cells and 5-HT concentrations in the rostral raphe region within four weeks following TAM treatment. Tph2 icKO and MS differentially affected food and water intake, locomotor activity as well as panic-like escape behavior. Tph2 icKO prevented the adverse effects of MS stress and altered the expression of the genes previously linked to stress and emotionality. In conclusion, an experimental model was established to study the behavioral and neurobiological consequences of 5-HT deficiency in adulthood in interaction with early-life adversity potentially affecting brain development and the pathogenesis of depressive disorders.
KW  - emotion
KW  - molecular medicine
KW  - neuroscience
Y1  - 2021
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-258626
SN  - 2045-2322
VL  - 11
IS  - 1
ER  - 
TY  - JOUR
A1  - Citron, Francesca M. M.
A1  - Abugaber, David
A1  - Herbert, Cornelia
T1  - Approach and Withdrawal Tendencies during Written Word Processing: Effects of Task, Emotional Valence, and Emotional Arousal
JF  - frontiers in Psychology
N2  - The affective dimensions of emotional valence and emotional arousal affect processing of verbal and pictorial stimuli. Traditional emotional theories assume a linear relationship between these dimensions, with valence determining the direction of a behavior (approach vs. withdrawal) and arousal its intensity or strength. In contrast, according to the valence-arousal conflict theory, both dimensions are interactively related: positive valence and low arousal (PL) are associated with an implicit tendency to approach a stimulus, whereas negative valence and high arousal (NH) are associated with withdrawal. Hence, positive, high-arousal (PH) and negative, low-arousal (NL) stimuli elicit conflicting action tendencies. By extending previous research that used several tasks and methods, the present study investigated whether and how emotional valence and arousal affect subjective approach vs. withdrawal tendencies toward emotional words during two novel tasks. In Study 1, participants had to decide whether they would approach or withdraw from concepts expressed by written words. In Studies 2 and 3 participants had to respond to each word by pressing one of two keys labeled with an arrow pointing upward or downward. Across experiments, positive and negative words, high or low in arousal, were presented. In Study 1 (explicit task), in line with the valence-arousal conflict theory, PH and NL words were responded to more slowly than PL and NH words. In addition, participants decided to approach positive words more often than negative words. In Studies 2 and 3, participants responded faster to positive than negative words, irrespective of their level of arousal. Furthermore, positive words were significantly more often associated with “up” responses than negative words, thus supporting the existence of implicit associations between stimulus valence and response coding (positive is up and negative is down). Hence, in contexts in which participants' spontaneous responses are based on implicit associations between stimulus valence and response, there is no influence of arousal. In line with the valence-arousal conflict theory, arousal seems to affect participants' approach-withdrawal tendencies only when such tendencies are made explicit by the task, and a minimal degree of processing depth is required.
KW  - approach
KW  - withdrawal
KW  - valence
KW  - arousal
KW  - emotion
KW  - words
KW  - polarity effects
Y1  - 2016
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-165318
VL  - 6
IS  - 1935
ER  - 
TY  - THES
A1  - Menne, Isabelle M.
T1  - Facing Social Robots – Emotional Reactions towards Social Robots
N2  - Ein Army Colonel empfindet Mitleid mit einem Roboter, der versuchsweise Landminen entschärft und deklariert den Test als inhuman (Garreau, 2007). Roboter bekommen militärische Beförderungen, Beerdigungen und Ehrenmedaillen (Garreau, 2007; Carpenter, 2013). Ein Schildkrötenroboter wird entwickelt, um Kindern beizubringen, Roboter gut zu behandeln (Ackermann, 2018). Der humanoide Roboter Sophia wurde erst kürzlich Saudi-Arabischer Staatsbürger und es gibt bereits Debatten, ob Roboter Rechte bekommen sollen (Delcker, 2018). Diese und ähnliche Entwicklungen zeigen schon jetzt die Bedeutsamkeit von Robotern und die emotionale Wirkung die diese auslösen. Dennoch scheinen sich diese emotionalen Reaktionen auf einer anderen Ebene abzuspielen, gemessen an Kommentaren in Internetforen. Dort ist oftmals die Rede davon, wieso jemand überhaupt emotional auf einen Roboter reagieren kann. Tatsächlich ist es, rein rational gesehen, schwierig zu erklären, warum Menschen mit einer leblosen (‚mindless‘) Maschine mitfühlen sollten. Und dennoch zeugen nicht nur oben genannte Berichte, sondern auch erste wissenschaftliche Studien (z.B. Rosenthal- von der Pütten et al., 2013) von dem emotionalen Einfluss den Roboter auf Menschen haben können. Trotz der Bedeutsamkeit der Erforschung emotionaler Reaktionen auf Roboter existieren bislang wenige wissenschaftliche Studien hierzu. Tatsächlich identifizierten Kappas, Krumhuber und Küster (2013) die systematische Analyse und Evaluation sozialer Reaktionen auf Roboter als eine der größten Herausforderungen der affektiven Mensch-Roboter Interaktion. Nach Scherer (2001; 2005) bestehen Emotionen aus der Koordination und Synchronisation verschiedener Komponenten, die miteinander verknüpft sind. Motorischer Ausdruck (Mimik), subjektives Erleben, Handlungstendenzen, physiologische und kognitive Komponenten gehören hierzu. Um eine Emotion vollständig zu erfassen, müssten all diese Komponenten gemessen werden, jedoch wurde eine solch umfassende Analyse bisher noch nie durchgeführt (Scherer, 2005). Hauptsächlich werden Fragebögen eingesetzt (vgl. Bethel & Murphy, 2010), die allerdings meist nur das subjektive Erleben abfragen. Bakeman und Gottman (1997) geben sogar an, dass nur etwa 8% der psychologischen Forschung auf Verhaltensdaten basiert, obwohl die Psychologie traditionell als das ‚Studium von Psyche und Verhalten‘ (American Psychological Association, 2018) definiert wird. Die Messung anderer Emotionskomponenten ist selten. Zudem sind Fragebögen mit einer Reihe von Nachteilen behaftet (Austin, Deary, Gibson, McGregor, Dent, 1998; Fan et al., 2006; Wilcox, 2011). Bethel und Murphy (2010) als auch Arkin und Moshkina (2015) plädieren für einen Multi-Methodenansatz um ein umfassenderes Verständnis von affektiven Prozessen in der Mensch-Roboter Interaktion zu erlangen. Das Hauptziel der vorliegenden Dissertation ist es daher, mithilfe eines Multi-Methodenansatzes verschiedene Komponenten von Emotionen (motorischer Ausdruck, subjektive Gefühlskomponente, Handlungstendenzen) zu erfassen und so zu einem vollständigeren und tiefgreifenderem Bild emotionaler Prozesse auf Roboter beizutragen. 
Um dieses Ziel zu erreichen, wurden drei experimentelle Studien mit insgesamt 491 Teilnehmern durchgeführt. Mit unterschiedlichen Ebenen der „apparent reality“ (Frijda, 2007) sowie Macht / Kontrolle über die Situation (vgl. Scherer & Ellgring, 2007) wurde untersucht, inwiefern sich Intensität und Qualität emotionaler Reaktionen auf Roboter ändern und welche weiteren Faktoren (Aussehen des Roboters, emotionale Expressivität des Roboters, Behandlung des Roboters, Autoritätsstatus des Roboters) Einfluss ausüben. 
Experiment 1 basierte auf Videos, die verschiedene Arten von Robotern (tierähnlich, anthropomorph, maschinenartig), die entweder emotional expressiv waren oder nicht (an / aus) in verschiedenen Situationen (freundliche Behandlung des Roboters vs. Misshandlung) zeigten. Fragebögen über selbstberichtete Gefühle und die motorisch-expressive Komponente von Emotionen: Mimik (vgl. Scherer, 2005) wurden analysiert. Das Facial Action Coding System (Ekman, Friesen, & Hager, 2002), die umfassendste und am weitesten verbreitete Methode zur objektiven Untersuchung von Mimik, wurde hierfür verwendet. Die Ergebnisse zeigten, dass die Probanden Gesichtsausdrücke (Action Unit [AU] 12 und AUs, die mit positiven Emotionen assoziiert sind, sowie AU 4 und AUs, die mit negativen Emotionen assoziiert sind) sowie selbstberichtete Gefühle in Übereinstimmung mit der Valenz der in den Videos gezeigten Behandlung zeigten. Bei emotional expressiven Robotern konnten stärkere emotionale Reaktionen beobachtet werden als bei nicht-expressiven Robotern. Der tierähnliche Roboter Pleo erfuhr in der Misshandlungs-Bedingung am meisten Mitleid, Empathie, negative Gefühle und Traurigkeit, gefolgt vom anthropomorphen Roboter Reeti und am wenigsten für den maschinenartigen Roboter Roomba. Roomba wurde am meisten Antipathie zugeschrieben. Die Ergebnisse knüpfen an frühere Forschungen an (z.B. Krach et al., 2008; Menne & Schwab, 2018; Riek et al., 2009; Rosenthal-von der Pütten et al., 2013) und zeigen das Potenzial der Mimik für eine natürliche Mensch-Roboter Interaktion. 
Experiment 2 und Experiment 3 übertrugen die klassischen Experimente von Milgram (1963; 1974) zum Thema Gehorsam in den Kontext der Mensch-Roboter Interaktion. Die Gehorsamkeitsstudien von Milgram wurden als sehr geeignet erachtet, um das Ausmaß der Empathie gegenüber einem Roboter im Verhältnis zum Gehorsam gegenüber einem Roboter zu untersuchen. Experiment 2 unterschied sich von Experiment 3 in der Ebene der „apparent reality“ (Frijda, 2007): in Anlehnung an Milgram (1963) wurde eine rein text-basierte Studie (Experiment 2) einer live Mensch-Roboter Interaktion (Experiment 3) gegenübergestellt. Während die abhängigen Variablen von Experiment 2 aus den Selbstberichten emotionaler Gefühle sowie Einschätzungen des hypothetischen Verhaltens bestand, erfasste Experiment 3 subjektive Gefühle sowie reales Verhalten (Reaktionszeit: Dauer des Zögerns; Gehorsamkeitsrate; Anzahl der Proteste; Mimik) der Teilnehmer. Beide Experimente untersuchten den Einfluss der Faktoren „Autoritätsstatus“ (hoch / niedrig) des Roboters, der die Befehle erteilt (Nao) und die emotionale Expressivität (an / aus) des Roboters, der die Strafen erhält (Pleo). Die subjektiven Gefühle der Teilnehmer aus Experiment 2 unterschieden sich zwischen den Gruppen nicht. Darüber hinaus gaben nur wenige Teilnehmer (20.2%) an, dass sie den „Opfer“-Roboter definitiv bestrafen würden. Ein ähnliches Ergebnis fand auch Milgram (1963). Das reale Verhalten von Versuchsteilnehmern in Milgrams‘ Labor-Experiment unterschied sich jedoch von Einschätzungen hypothetischen Verhaltens von Teilnehmern, denen Milgram das Experiment nur beschrieben hatte. Ebenso lassen Kommentare von Teilnehmern aus Experiment 2 darauf schließen, dass das beschriebene Szenario möglicherweise als fiktiv eingestuft wurde und Einschätzungen von hypothetischem Verhalten daher kein realistisches Bild realen Verhaltens gegenüber Roboter in einer live Interaktion zeichnen können. Daher wurde ein weiteres Experiment (Experiment 3) mit einer Live Interaktion mit einem Roboter als Autoritätsfigur (hoher Autoritätsstatus vs. niedriger) und einem weiteren Roboter als „Opfer“ (emotional expressiv vs. nicht expressiv) durchgeführt. Es wurden Gruppenunterschiede in Fragebögen über emotionale Reaktionen gefunden. Dem emotional expressiven Roboter wurde mehr Empathie entgegengebracht und es wurde mehr Freude und weniger Antipathie berichtet als gegenüber einem nicht-expressiven Roboter. Außerdem konnten Gesichtsausdrücke beobachtet werden, die mit negativen Emotionen assoziiert sind während Probanden Nao’s Befehl ausführten und Pleo bestraften. Obwohl Probanden tendenziell länger zögerten, wenn sie einen emotional expressiven Roboter bestrafen sollten und der Befehl von einem Roboter mit niedrigem Autoritätsstatus kam, wurde dieser Unterschied nicht signifikant. Zudem waren alle bis auf einen Probanden gehorsam und bestraften Pleo, wie vom Nao Roboter befohlen. Dieses Ergebnis steht in starkem Gegensatz zu dem selbstberichteten hypothetischen Verhalten der Teilnehmer aus Experiment 2 und unterstützt die Annahme, dass die Einschätzungen von hypothetischem Verhalten in einem Mensch-Roboter-Gehorsamkeitsszenario nicht zuverlässig sind für echtes Verhalten in einer live Mensch-Roboter Interaktion. Situative Variablen, wie z.B. der Gehorsam gegenüber Autoritäten, sogar gegenüber einem Roboter, scheinen stärker zu sein als Empathie für einen Roboter. Dieser Befund knüpft an andere Studien an (z.B. Bartneck & Hu, 2008; Geiskkovitch et al., 2016; Menne, 2017; Slater et al., 2006), eröffnet neue Erkenntnisse zum Einfluss von Robotern, zeigt aber auch auf, dass die Wahl einer Methode um Empathie für einen Roboter zu evozieren eine nicht triviale Angelegenheit ist (vgl. Geiskkovitch et al., 2016; vgl. Milgram, 1965). Insgesamt stützen die Ergebnisse die Annahme, dass die emotionalen Reaktionen auf Roboter tiefgreifend sind und sich sowohl auf der subjektiven Ebene als auch in der motorischen Komponente zeigen. Menschen reagieren emotional auf einen Roboter, der emotional expressiv ist und eher weniger wie eine Maschine aussieht. Sie empfinden Empathie und negative Gefühle, wenn ein Roboter misshandelt wird und diese emotionalen Reaktionen spiegeln sich in der Mimik. Darüber hinaus unterscheiden sich die Einschätzungen von Menschen über ihr eigenes hypothetisches Verhalten von ihrem tatsächlichen Verhalten, weshalb videobasierte oder live Interaktionen zur Analyse realer Verhaltensreaktionen empfohlen wird. Die Ankunft sozialer Roboter in der Gesellschaft führt zu nie dagewesenen Fragen und diese Dissertation liefert einen ersten Schritt zum Verständnis dieser neuen Herausforderungen.
N2  - An Army Colonel feels sorry for a robot that defuses landmines on a trial basis and declares the test inhumane (Garreau, 2007). Robots receive military promotions, funerals and medals of honor (Garreau, 2007; Carpenter, 2013). A turtle robot is being developed to teach children to treat robots well (Ackermann, 2018). The humanoid robot Sophia recently became a Saudi Arabian citizen and there are now debates whether robots should have rights (Delcker, 2018). These and similar developments already show the importance of robots and the emotional impact they have. Nevertheless, these emotional reactions seem to take place on a different level, judging by comments in internet forums alone: Most often, emotional reactions towards robots are questioned if not denied at all. In fact, from a purely rational point of view, it is difficult to explain why people should empathize with a mindless machine. However, not only the reports mentioned above but also first scientific studies (e.g. Rosenthal- von der Pütten et al., 2013) bear witness to the emotional influence of robots on humans. Despite the importance of researching emotional reactions towards robots, there are few scientific studies on this subject. In fact, Kappas, Krumhuber and Küster (2013) identified effective testing and evaluation of social reactions towards robots as one of the major challenges of affective Human-Robot Interaction (HRI). According to Scherer (2001; 2005), emotions consist of the coordination and synchronization of different components that are linked to each other. These include motor expression (facial expressions), subjective experience, action tendencies, physiological and cognitive components. To fully capture an emotion, all these components would have to be measured, but such a comprehensive analysis has never been performed (Scherer, 2005). Primarily, questionnaires are used (cf. Bethel & Murphy, 2010) but most of them only capture subjective experiences. Bakeman and Gottman (1997) even state that only about 8% of psychological research is based on behavioral data, although psychology is traditionally defined as the 'study of the mind and behavior' (American Psychological Association, 2018). The measurement of other emotional components is rare. In addition, questionnaires have a number of disadvantages (Austin, Deary, Gibson, McGregor, Dent, 1998; Fan et al., 2006; Wilcox, 2011). Bethel and Murphy (2010) as well as Arkin and Moshkina (2015) argue for a multi-method approach to achieve a more comprehensive understanding of affective processes in HRI. The main goal of this dissertation is therefore to use a multi-method approach to capture different components of emotions (motor expression, subjective feeling component, action tendencies) and thus contribute to a more complete and profound picture of emotional processes towards robots. 
To achieve this goal, three experimental studies were conducted with a total of 491 participants. With different levels of ‘apparent reality’ (Frijda, 2007) and power/control over the situation (cf. Scherer & Ellgring, 2007), the extent to which the intensity and quality of emotional responses to robots change were investigated as well as the influence of other factors (appearance of the robot, emotional expressivity of the robot, treatment of the robot, authority status of the robot). 
Experiment 1 was based on videos showing different types of robots (animal-like, anthropomorphic, machine-like) in different situations (friendly treatment of the robot vs. torture treatment) while being either emotionally expressive or not. Self-reports of feelings as well as the motoric-expressive component of emotion: facial expressions (cf. Scherer, 2005) were analyzed. The Facial Action Coding System (Ekman, Friesen, & Hager, 2002), the most comprehensive and most widely used method for objectively assessing facial expressions, was utilized for this purpose. Results showed that participants displayed facial expressions (Action Unit [AU] 12 and AUs associated with positive emotions as well as AU 4 and AUs associated with negative emotions) as well as self-reported feelings in line with the valence of the treatment shown in the videos. Stronger emotional reactions could be observed for emotionally expressive robots than non-expressive robots. Most pity, empathy, negative feelings and sadness were reported for the animal-like robot Pleo while watching it being tortured, followed by the anthropomorphic robot Reeti and least for the machine-like robot Roomba. Most antipathy was attributed to Roomba. The findings are in line with previous research (e.g., Krach et al., 2008; Menne & Schwab, 2018; Riek et al., 2009; Rosenthal-von der Pütten et al., 2013) and show facial expressions’ potential for a natural HRI. 
Experiment 2 and Experiment 3 transferred Milgram’s classic experiments (1963; 1974) on obedience into the context of HRI. Milgram’s obedience studies were deemed highly suitable to study the extent of empathy towards a robot in relation to obedience to a robot. Experiment 2 differed from Experiment 3 in the level of ‘apparent reality’ (Frijda, 2007): based on Milgram (1963), a purely text-based study (Experiment 2) was compared with a live HRI (Experiment 3). While the dependent variables of Experiment 2 consisted of self-reports of emotional feelings and assessments of hypothetical behavior, Experiment 3 measured subjective feelings and real behavior (reaction time: duration of hesitation; obedience rate; number of protests; facial expressions) of the participants. Both experiments examined the influence of the factors "authority status" (high / low) of the robot giving the orders (Nao) and the emotional expressivity (on / off) of the robot receiving the punishments (Pleo). The subjective feelings of the participants from Experiment 2 did not differ between the groups. In addition, only few participants (20.2%) stated that they would definitely punish the "victim" robot. Milgram (1963) found a similar result. However, the real behavior of participants in Milgram's laboratory experiment differed from the estimates of hypothetical behavior of participants to whom Milgram had only described the experiment. Similarly, comments from participants in Experiment 2 suggest that the scenario described may have been considered fictitious and that assessments of hypothetical behavior may not provide a realistic picture of real behavior towards robots in a live interaction. Therefore, another experiment (Experiment 3) was performed with a live interaction with a robot as authority figure (high authority status vs. low) and another robot as "victim" (emotional expressive vs. non-expressive). Group differences were found in questionnaires on emotional responses. More empathy was shown for the emotionally expressive robot and more joy and less antipathy was reported than for a non-expressive robot. In addition, facial expressions associated with negative emotions could be observed while subjects executed Nao's command and punished Pleo. Although subjects tended to hesitate longer when punishing an emotionally expressive robot and the order came from a robot with low authority status, this difference did not reach significance. Furthermore, all but one subject were obedient and punished Pleo as commanded by the Nao robot. This result stands in stark contrast to the self-reported hypothetical behavior of the participants from Experiment 2 and supports the assumption that the assessments of hypothetical behavior in a Human-Robot obedience scenario are not reliable for real behavior in a live HRI. Situational variables, such as obedience to authorities, even to a robot, seem to be stronger than empathy for a robot. This finding is in line with previous studies (e.g. Bartneck & Hu, 2008; Geiskkovitch et al., 2016; Menne, 2017; Slater et al., 2006), opens up new insights into the influence of robots, but also shows that the choice of a method to evoke empathy for a robot is not a trivial matter (cf. Geiskkovitch et al., 2016; cf. Milgram, 1965). Overall, the results support the assumption that emotional reactions to robots are profound and manifest both at the subjective level and in the motor component. Humans react emotionally to a robot that is emotionally expressive and looks less like a machine. They feel empathy and negative feelings when a robot is abused and these emotional reactions are reflected in facial expressions. In addition, people's assessments of their own hypothetical behavior differ from their actual behavior, which is why video-based or live interactions are recommended for analyzing real behavioral responses. The arrival of social robots in society leads to unprecedented questions and this dissertation provides a first step towards understanding these new challenges.
N2  - Are there emotional reactions towards social robots? Could you love a robot? Or, put the other way round: Could you mistreat a robot, tear it apart and sell it? Media reports people honoring military robots with funerals, mourning the “death” of a robotic dog, and granting the humanoid robot Sophia citizenship. But how profound are these reactions? Three experiments take a closer look on emotional reactions towards social robots by investigating the subjective experience of people as well as the motor expressive level. Contexts of varying degrees of Human-Robot Interaction (HRI) sketch a nuanced picture of emotions towards social robots that encompass conscious as well as unconscious reactions. The findings advance the understanding of affective experiences in HRI. It also turns the initial question into: Can emotional reactions towards social robots even be avoided?
T2  - Im Angesicht sozialer Roboter - Emotionale Reaktionen angesichts sozialer Roboter
KW  - Roboter
KW  - social robot
KW  - emotion
KW  - FACS
KW  - Facial Action Coding System
KW  - facial expressions
KW  - emotional reaction
KW  - Human-Robot Interaction
KW  - HRI
KW  - obedience
KW  - empathy
KW  - Gefühl
KW  - Mimik
KW  - Mensch-Maschine-Kommunikation
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-187131
SN  - 978-3-95826-120-4
SN  - 978-3-95826-121-1
N1  - Parallel erschienen als Druckausgabe in Würzburg University Press, 978-3-95826-120-4, 27,80 EUR.
PB  - Würzburg University Press
CY  - Würzburg
ET  - 1. Auflage
ER  - 
TY  - JOUR
A1  - Madan, Christopher R.
A1  - Bayer, Janine
A1  - Gamer, Matthias
A1  - Lonsdorf, Tina B.
A1  - Sommer, Tobias
T1  - Visual Complexity and Affect: Ratings Reflect More Than Meets the Eye
JF  - Frontiers in Psychology
N2  - Pictorial stimuli can vary on many dimensions, several aspects of which are captured by the term ‘visual complexity.’ Visual complexity can be described as, “a picture of a few objects, colors, or structures would be less complex than a very colorful picture of many objects that is composed of several components.” Prior studies have reported a relationship between affect and visual complexity, where complex pictures are rated as more pleasant and arousing. However, a relationship in the opposite direction, an effect of affect on visual complexity, is also possible; emotional arousal and valence are known to influence selective attention and visual processing. In a series of experiments, we found that ratings of visual complexity correlated with affective ratings, and independently also with computational measures of visual complexity. These computational measures did not correlate with affect, suggesting that complexity ratings are separately related to distinct factors. We investigated the relationship between affect and ratings of visual complexity, finding an ‘arousal-complexity bias’ to be a robust phenomenon. Moreover, we found this bias could be attenuated when explicitly indicated but did not correlate with inter-individual difference measures of affective processing, and was largely unrelated to cognitive and eyetracking measures. Taken together, the arousal-complexity bias seems to be caused by a relationship between arousal and visual processing as it has been described for the greater vividness of arousing pictures. The described arousal-complexity bias is also of relevance from an experimental perspective because visual complexity is often considered a variable to control for when using pictorial stimuli.
KW  - visual complexity
KW  - affect
KW  - arousal
KW  - valence
KW  - eyetracking
KW  - emotion
Y1  - 2018
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-190015
SN  - 1664-1078
VL  - 8
IS  - 2368
ER  - 
TY  - THES
A1  - Ramirez Pasos, Uri Eduardo
T1  - Subthalamic Nucleus Neural Synchronization and Connectivity during Limbic Processing of Emotional Pictures: Evidence from Invasive Recordings in Patients with Parkinson's Disease
T1  - Synchronisierung und Konnektivität des Nucleus subthalamicus während limbischer Bearbeitung affektiver Bilder: Evidenz aus invasiven Aufzeichnungen in Patienten mit Morbus Parkinson
N2  - In addition to bradykinesia and tremor, patients with Parkinson’s disease (PD) are known to exhibit non-motor symptoms such as apathy and hypomimia but also impulsivity in response to dopaminergic replacement therapy. Moreover, a plethora of studies observe differences in electrocortical and autonomic responses to both visual and acoustic affective stimuli in PD subjects compared to healthy controls. This suggests that the basal ganglia (BG), as well as the hyperdirect pathway and BG thalamocortical circuits, are involved in affective processing. Recent studies have shown valence and dopamine-dependent changes in synchronization in the subthalamic nucleus (STN) in PD patients during affective tasks. This thesis investigates the role of dopamine, valence, and laterality in STN electrophysiology by analyzing event-related potentials (ERP), synchronization, and inter-hemispheric STN connectivity. STN recordings were obtained from PD patients with chronically implanted electrodes for deep brain stimulation during a passive affective picture presentation task. The STN exhibited valence-dependent ERP latencies and lateralized ‘high beta’ (28–40 Hz) event-related desynchronization. This thesis also examines the role of dopamine, valence, and laterality on STN functional connectivity with the anterior cingulate cortex (ACC) and the amygdala. The activity of these limbic structures was reconstructed using simultaneously recorded electroencephalographic signals. While the STN was found to establish early coupling with both structures, STN-ACC coupling in the ‘alpha’ range (7–11 Hz) and uncoupling in the ‘low beta’ range (14–21 Hz) were lateralized. Lateralization was also observed at the level of synchrony in both reconstructed sources and for ACC ERP amplitude, whereas dopamine modulated ERP latency in the amygdala. These results may deepen our current understanding of the STN as a limbic node within larger emotional-motor networks in the brain.

N2  - Neben Bradykinese und Tremor weisen Patienten mit Morbus Parkinson (PD) bekannterweise nicht-motorische Symptome auf wie Apathie und Hypomimie, aber auch Impulsivität, welche durch Dopaminersatztherapien bedingt ist. Viele Studien belegen außerdem Unterschiede von kortikalen und autonomen Reaktionen auf sowohl visuelle als auch akustische Reize bei Patienten mit PD im Vergleich zu gesunden Kontrollgruppen. Dies legt nahe, dass sich die Basalganglien (BG), und auch die hyperdirekte Verbindung sowie die BG-thalamokortikalen Schleifen, an der Affektbearbeitung beteiligen. Jüngere Studien haben Valenz- und Dopamin-bedingte Veränderungen der Synchronisierung im Nucleus subthalamicus (STN) von Parkinson-Patienten bei affektiven Aufgaben belegt. Diese Promotionsarbeit untersucht die Rolle von Dopamin, Valenz und Lateralität in der STN-Elektrophysiologie mittels Analysen von ereigniskorrelierten Potentialen (ERP), Synchronisierung und interhemisphärischer funktioneller Konnektivität. STN-Aufzeichnungen wurden von Patienten mit dauerhaft implantierten Elektroden für die Tiefenhirnstimulation während einer passiven Aufgabe abgeleitet, bei den ihnen Bilder mit emotionalen Inhalten gezeigt wurden. Der STN wies Valenz-bedingte ERP-Latenz und lateralisierte ereigniskorrelierte Desynchronisierung in ‘hohem Beta’ (28–40 Hz) auf. Diese Dissertation untersucht auch die Rolle von Dopamin, Valenz und Lateralität bezüglich der funktionellen Konnektivität zwischen dem STN und dem Gyrus cinguli pars anterior (ACC) sowie der Amygdala. Die Aktivität dieser Strukturen wurde aus simultanen elektroenzephalographischen Aufzeichnungen rekonstruiert. Obwohl eine STN-Kopplung mit beiden Strukturen auftritt, war die STN-ACC-Kopplung im ‘Alpha’- Bereich (7–11 Hz) und die Entkopplung im ‘niedrigen Beta’-Bereich (14–21 Hz) lateralisiert. Lateralisierung wurde auch an der Synchronisierung in beiden rekonstruierten Quellen und an der ACC-ERP-Amplitude festgestellt, wohingegen Dopamin die ERP-Latenz in der Amygdala modulierte. Diese Ergebnisse mögen das gegenwärtige Wissen vom STN als limbischem Knoten innerhalb größerer affektiv-motorischer Schleifen im Gehirn vertiefen.
KW  - Nucleus subthalamicus
KW  - subthalamic nucleus
KW  - Emotionales Verhalten
KW  - functional connectivity
KW  - oscillations
KW  - emotion
KW  - Affekt
KW  - Elektrophysiologie
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-169850
ER  - 
TY  - JOUR
A1  - Diemer, Julia
A1  - Alpers, Georg W.
A1  - Peperkorn, Henrik M.
A1  - Shiban, Youssef
A1  - Mühlberger, Andreas
T1  - The impact of perception and presence on emotional reactions: a review of research in virtual reality
JF  - Frontiers in Psychology
N2  - Virtual reality (VR) has made its way into mainstream psychological research in the last two decades. This technology, with its unique ability to simulate complex, real situations and contexts, offers researchers unprecedented opportunities to investigate human behavior in well controlled designs in the laboratory. One important application of VR is the investigation of pathological processes in mental disorders, especially anxiety disorders. Research on the processes underlying threat perception, fear, and exposure therapy has shed light on more general aspects of the relation between perception and emotion. Being by its nature virtual, i.e., simulation of reality, VR strongly relies on the adequate selection of specific perceptual cues to activate emotions. Emotional experiences in turn are related to presence, another important concept in VR, which describes the user's sense of being in a VR environment. This paper summarizes current research into perception of fear cues, emotion, and presence, aiming at the identification of the most relevant aspects of emotional experience in VR and their mutual relations. A special focus lies on a series of recent experiments designed to test the relative contribution of perception and conceptual information on fear in VR. This strand of research capitalizes on the dissociation between perception (bottom up input) and conceptual information (top-down input) that is possible in VR. Further, we review the factors that have so far been recognized to influence presence, with emotions (e.g., fear) being the most relevant in the context of clinical psychology. Recent research has highlighted the mutual influence of presence and fear in VR, but has also traced the limits of our current understanding of this relationship. In this paper, the crucial role of perception on eliciting emotional reactions is highlighted, and the role of arousal as a basic dimension of emotional experience is discussed. An interoceptive attribution model of presence is suggested as a first step toward an integrative framework for emotion research in VR. Gaps in the current literature and future directions are outlined.
KW  - exposure therapy
KW  - flight phobics
KW  - environments
KW  - virtual reality
KW  - anxiety
KW  - presence
KW  - emotion
KW  - fear
KW  - perception
KW  - anxiety disorders
KW  - presence questionnaire
KW  - public speaking
KW  - spider phobia
KW  - social phobia
KW  - immersion
Y1  - 2015
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-144200
VL  - 6
IS  - 26
ER  - 
TY  - JOUR
A1  - Topolinski, Sascha
A1  - Strack, Fritz
T1  - Corrugator activity confirms immediate negative affect in surprise
JF  - Frontiers in Psychology
N2  - The emotion of surprise entails a complex of immediate responses, such as cognitive interruption, attention allocation to, and more systematic processing of the surprising stimulus. All these processes serve the ultimate function to increase processing depth and thus cognitively master the surprising stimulus. The present account introduces phasic negative affect as the underlying mechanism responsible for this switch in operating mode. Surprising stimuli are schema discrepant and thus entail cognitive disfluency, which elicits immediate negative affect. This affect in turn works like a phasic cognitive tuning switching the current processing mode from more automatic and heuristic to more systematic and reflective processing. Directly testing the initial elicitation of negative affect by surprising events, the present experiment presented high and low surprising neutral trivia statements to N = 28 participants while assessing their spontaneous facial expressions via facial electromyography. High compared to low surprising trivia elicited higher corrugator activity, indicative of negative affect and mental effort, while leaving zygomaticus (positive affect) and frontalis (cultural surprise expression) activity unaffected. Future research shall investigate the mediating role of negative affect in eliciting surprise-related outcomes.
KW  - phasic affective modulation
KW  - processing fluency
KW  - intuition
KW  - surprise
KW  - EMG
KW  - elevator EMG activity
KW  - facial expressions
KW  - semantic coherence
KW  - emotion
KW  - judgments
KW  - attention
KW  - memory
KW  - affect
KW  - expectancy
Y1  - 2015
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-144068
VL  - 6
IS  - 134
ER  - 
TY  - RPRT
A1  - Fuchs, Florian
T1  - “Disney Dreams!“ – A Nighttime Spectacular in the Tension Field of Crowds, Communion, Emotion, and Religion
N2  - The text deals with the nighttime spectacular of Disneyland Paris´ "Disney Dreams!" from the perspectives of mass, community, religion and emotions. It tries to open up this pop cultural show sociologically and theologically.
N2  - Der Text beschäftigt sich mit der Abendshow des Disneyland Paris "Disney Dreams!" aus den Perspektiven Masse, Gemeinschaft, Religion und Emotionen. Es wird versucht, diese popkulturelle Show soziologisch und theologisch zu erschließen.
KW  - Soziologie
KW  - Phänomenologische Soziologie
KW  - Theologie
KW  - Disney
KW  - mass
KW  - emotion
KW  - theme park
KW  - event
KW  - Praktische Theologie
KW  - Ritual
KW  - Disney
KW  - Emotion
KW  - Event
KW  - Masse
KW  - Themenpark
Y1  - 2018
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-159949
N1  - Die englische Fassung dieses Working Papers ist unter folgendem Link verfügbar: nbn-resolving.org/urn:nbn:de:bvb:20-opus-159931
ER  - 
TY  - JOUR
A1  - Conzelmann, Annette
A1  - Reif, Andreas
A1  - Jacob, Christian
A1  - Weyers, Peter
A1  - Lesch, Klaus-Peter
A1  - Lutz, Beat
A1  - Pauli, Paul
T1  - A polymorphism in the gene of the endocannabinoid-degrading enzyme FAAH (FAAH C385A) is associated with emotional–motivational reactivity
JF  - Psychopharmacology
N2  - Rationale
The endocannabinoid (eCB) system is implicated in several psychiatric disorders. Investigating emotional–motivational dysfunctions as underlying mechanisms, a study in humans revealed that in the C385A polymorphism of the fatty acid amide hydrolase (FAAH), the degrading enzyme of the eCB anandamide (AEA), A carriers, who are characterized by increased signaling of AEA as compared to C/C carriers, exhibited reduced brain reactivity towards unpleasant faces and enhanced reactivity towards reward. However, the association of eCB system with emotional–motivational reactivity is complex and bidirectional due to upcoming compensatory processes.

Objectives
Therefore, we further investigated the relationship of the FAAH polymorphism and emotional–motivational reactivity in humans.

Methods
We assessed the affect-modulated startle, and ratings of valence and arousal in response to higher arousing pleasant, neutral, and unpleasant pictures in 67 FAAH C385A C/C carriers and 45 A carriers.

Results
Contrarily to the previous functional MRI study, A carriers compared to C/C carriers exhibited an increased startle potentiation and therefore emotional responsiveness towards unpleasant picture stimuli and reduced startle inhibition indicating reduced emotional reactivity in response to pleasant pictures, while both groups did not differ in ratings of arousal and valence.

Conclusions
Our findings emphasize the bidirectionality and thorough examination of the eCB system’s impact on emotional reactivity as a central endophenotype underlying various psychiatric disorders.
KW  - startle reflex
KW  - FAAH
KW  - genetics
KW  - endocannabinoid
KW  - emotion
Y1  - 2012
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-129936
VL  - 224
IS  - 4
ER  -