@phdthesis{Brembs2000, author = {Brembs, Bj{\"o}rn}, title = {An Analysis of Associative Learning in Drosophila at the Flight Simulator}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-1039}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2000}, abstract = {Most natural learning situations are of a complex nature and consist of a tight conjunction of the animal's behavior (B) with the perceived stimuli. According to the behavior of the animal in response to these stimuli, they are classified as being either biologically neutral (conditioned stimuli, CS) or important (unconditioned stimuli, US or reinforcer). A typical learning situation is thus identified by a three term contingency of B, CS and US. A functional characterization of the single associations during conditioning in such a three term contingency has so far hardly been possible. Therefore, the operational distinction between classical conditioning as a behavior-independent learning process (CS-US associations) and operant conditioning as essentially behavior-dependent learning (B-US associations) has proven very valuable. However, most learning experiments described so far have not been successful in fully separating operant from classical conditioning into single-association tasks. The Drosophila flight simulator in which the relevant behavior is a single motor variable (yaw torque), allows for the first time to completely separate the operant (B-US, B-CS) and the classical (CS-US) components of a complex learning situation and to examine their interactions. In this thesis the contributions of the single associations (CS-US, B-US and B-CS) to memory formation are studied. Moreover, for the first time a particularly prominent single association (CS-US) is characterized extensively in a three term contingency. A yoked control shows that classical (CS-US) pattern learning requires more training than operant pattern learning. Additionally, it can be demonstrated that an operantly trained stimulus can be successfully transferred from the behavior used during training to a new behavior in a subsequent test phase. This result shows unambiguously that during operant conditioning classical (CS-US) associations can be formed. In an extension to this insight, it emerges that such a classical association blocks the formation of an operant association, which would have been formed without the operant control of the learned stimuli. Instead the operant component seems to develop less markedly and is probably merged into a complex three-way association. This three-way association could either be implemented as a sequential B-CS-US or as a hierarchical (B-CS)-US association. The comparison of a simple classical (CS-US) with a composite operant (B, CS and US) learning situation and of a simple operant (B-US) with another composite operant (B, CS and US) learning situation, suggests a hierarchy of predictors of reinforcement. Operant behavior occurring during composite operant conditioning is hardly conditioned at all. The associability of classical stimuli that bear no relation to the behavior of the animal is of an intermediate value, as is operant behavior alone. Stimuli that are controlled by operant behavior accrue associative strength most easily. If several stimuli are available as potential predictors, again the question arises which CS-US associations are formed? A number of different studies in vertebrates yielded amazingly congruent results. These results inspired to examine and compare the properties of the CS-US association in a complex learning situation at the flight simulator with these vertebrate results. It is shown for the first time that Drosophila can learn compound stimuli and recall the individual components independently and in similar proportions. The attempt to obtain second-order conditioning with these stimuli, yielded a relatively small effect. In comparison with vertebrate data, blocking and sensory preconditioning experiments produced conforming as well as dissenting results. While no blocking could be found, a sound sensory preconditioning effect was obtained. Possible reasons for the failure to find blocking are discussed and further experiments are suggested. The sensory preconditioning effect found in this study is revealed using simultaneous stimulus presentation and depends on the amount of preconditioning. It is argued that this effect is a case of 'incidental learning', where two stimuli are associated without the need of reinforcement. Finally, the implications of the results obtained in this study for the general understanding of memory formation in complex learning situations are discussed.}, subject = {Taufliege}, language = {en} } @phdthesis{Hoehn2002, author = {H{\"o}hn, Holger}, title = {Multimediale, datenbankgest{\"u}tzte Lehr- und Lernplattformen}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-4049}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2002}, abstract = {Die Dissertation befaßt sich mit der Entwicklung einer multimedialen, datenbankgest{\"u}tzten Lehr- und Lernplattform. Die entwickelten Module erm{\"o}glichen und erweitern nicht nur die M{\"o}glichkeit des Selbststudiums f{\"u}r den Studenten sondern erleichtern auch die Arbeit der Dozenten. Außerdem wird auch die Zusammenarbeit und der Austausch von Lernobjekten zwischen verschiedenen Institutionen erm{\"o}glicht. In der Lehr- und Lernplattform k{\"o}nnen verschiedene Lernobjekt-Typen verwaltet werden. Exemplarisch wurden die Typen Bilder, 3D-Animationen, Vorlesungen, Lerntexte, Fallbeispiele und Quizelemente integriert. Die Lehr- und Lernplattform besteht aus drei Bausteinen: 1. In der Lernobjekt-Datenbank werden alle Lernobjekt-Typen und Lernobjekte verwaltet. 2. Autorenwerkzeuge dienen zur Erstellung von Lernobjekten. 3. In der Lernplattform werden die Lernobjekte den Studenten zum (Selbst-)Lernen pr{\"a}sentiert. Neben den Vorteilen, die der Einsatz von E-Learning im allgemeinen bietet, wie die flexible Lernorganisation oder die Nutzung von Lerninhalten unabh{\"a}ngig von Ort und Zeit, zeichnet sich die entwickelte Lehr- und Lernplattform besonders durch folgende Punkte aus: Generierung von Lerninhalten h{\"o}herer Qualit{\"a}t durch multizentrische Expertenb{\"u}ndelung und Arbeitsteilung, Erweiterbarkeit auf andere, neue Lernobjekt-Typen, Verwaltbarkeit, Konsistenz, Flexibilit{\"a}t, geringer Verwaltungsaufwand, Navigationsm{\"o}glichkeiten f{\"u}r den Studenten, Personalisierbarkeit und Konformit{\"a}t zu internationalen Standards. Sowohl bei der Modellierung als auch bei der Umsetzung wurde darauf geachtet, m{\"o}glichst gut die Anforderungen der Dermatologie bei gleichzeitiger Erweiterbarkeit auf andere, {\"a}hnliche Szenarien zu erf{\"u}llen. Besonders einfach sollte die Anpassung der Plattform f{\"u}r andere bildorientierte Disziplinen sein.}, subject = {Multimedia}, language = {de} } @phdthesis{Schwaerzel2003, author = {Schw{\"a}rzel, Martin}, title = {Localizing engrams of olfactory memories in Drosophila}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-5065}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2003}, abstract = {Zars and co-workers were able to localize an engram of aversive olfactory memory to the mushroom bodies of Drosophila (Zars et al., 2000). In this thesis, I followed up on this finding in two ways. Inspired by Zars et al. (2000), I first focused on the whether it would also be possible to localize memory extinction.While memory extinction is well established behaviorally, little is known about the underlying circuitry and molecular mechanisms. In extension to the findings by Zars et al (2000), I show that aversive olfactory memories remain localized to a subset of mushroom body Kenyon cells for up to 3 hours. Extinction localizes to the same set of Kenyon cells. This common localization suggests a model in which unreinforced presentations of a previously learned odorant intracellularly antagonizes the signaling cascades underlying memory formation. The second part also targets memory localization, but addresses appetitive memory. I show that memories for the same olfactory cue can be established through either sugar or electric shock reinforcement. Importantly, these memories localize to the same set of neurons within the mushroom body. Thus, the question becomes apparent how the same signal can be associated with different events. It is shown that two different monoamines are specificaly necessary for formation of either of these memories, dopamine in case of electric shock and octopamine in case of sugar memory, respectively. Taking the representation of the olfactory cue within the mushroom bodies into account, the data suggest that the two memory traces are located in the same Kenyon cells, but in separate subcellular domains, one modulated by dopamine, the other by octopamine. Taken together, this study takes two further steps in the search for the engram. (1) The result that in Drosophila olfactory learning several memories are organized within the same set of Kenyon cells is in contrast to the pessimism expressed by Lashley that is might not be possible to localize an engram. (2) Beyond localization, a possibible mechanism how several engrams about the same stimulus can be localized within the same neurons might be suggested by the models of subcellular organisation, as postulated in case of appetitive and aversive memory on the one hand and acquisition and extinction of aversive memory on the other hand.}, subject = {Taufliege}, language = {en} } @phdthesis{Masek2005, author = {Masek, Pavel}, title = {Odor intensity learning in Drosophila}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-15546}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2005}, abstract = {It has been known for a long time that Drosophila can learn to discriminate not only between different odorants but also between different concentrations of the same odor. Olfactory associative learning has been described as a pairing between odorant and electric shock and since then, most of the experiments conducted in this respect have largely neglected the dual properties of odors: quality and intensity. For odorant-coupled short-term memory, a biochemical model has been proposed that mainly relies on the known cAMP signaling pathway. Mushroom bodies (MB) have been shown to be necessary and sufficient for this type of memory, and the MB-model of odor learning and short-term memory was established. Yet, theoretically, based on the MB-model, flies should not be able to learn concentrations if trained to the lower of the two concentrations in the test. In this thesis, I investigate the role of concentration-dependent learning, establishment of a concentration-dependent memory and their correlation to the standard two-odor learning as described by the MB-model. In order to highlight the difference between learning of quality and learning of intensity of the same odor I have tried to characterize the nature of the stimulus that is actually learned by the flies, leading to the conclusion that during the training flies learn all possible cues that are presented at the time. The type of the following test seems to govern the usage of the information available. This revealed a distinction between what flies learned and what is actually measured. Furthermore, I have shown that learning of concentration is associative and that it is symmetrical between high and low concentrations. I have also shown how the subjective quality perception of an odor changes with changing intensity, suggesting that one odor can have more than one scent. There is no proof that flies perceive a range of concentrations of one odorant as one (odor) quality. Flies display a certain level of concentration invariance that is limited and related to the particular concentration. Learning of concentration is relevant only to a limited range of concentrations within the boundaries of concentration invariance. Moreover, under certain conditions, two chemically distinct odorants could smell sufficiently similarly such, that they can be generalized between each other like if they would be of the same quality. Therefore, the abilities of the fly to identify the difference in quality or in intensity of the stimuli need to be distinguished. The way how the stimulus is analyzed and processed speaks in favor of a concept postulating the existence of two separated memories. To follow this concept, I have proposed a new form of memory called odor intensity memory (OIM), characterized it and compared it to other olfactory memories. OIM is independent of some members of the known cAMP signaling pathway and very likely forms the rutabaga-independent component of the standard two-odor memory. The rutabaga-dependent odor memory requires qualitatively different olfactory stimuli. OIM is revealed within the limits of concentration invariance where the memory test gives only sub-optimal performance for the concentration differences but discrimination of odor quality is not possible at all. Based on the available experimental tools, OIM seems to require the mushroom bodies the same as odor-quality memory but its properties are different. Flies can memorize the quality of several odorants at a given time but a newly formed memory of one odor interferes with the OIM stored before. In addition, the OIM lasts only 1 to 3 hours - much shorter than the odor-quality memory.}, subject = {Taufliege}, language = {en} } @phdthesis{Thum2006, author = {Thum, Andreas Stephan}, title = {Sugar reward learning in Drosophila : neuronal circuits in Drosophila associative olfactory learning}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-17930}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2006}, abstract = {Genetic intervention in the fly Drosophila melanogaster has provided strong evidence that the mushroom bodies of the insect brain act as the seat of memory traces for aversive and appetitive olfactory learning (reviewed in Heisenberg, 2003). In flies, electroshock is mainly used as negative reinforcer. Unfortunately this fact complicates a comparative consideration with other inscets as most studies use sugar as positive reinforcer. For example, several lines of evidence from honeybee and moth have suggested another site, the antennal lobe, to house neuronal plasticity underlying appetitive olfactory memory (reviewed in Menzel, 2001; Daly et al., 2004). Because of this I focused my work mainly on appetitive olfactory learning. In the first part of my thesis, I used a novel genetic tool, the TARGET system (McGuire et al., 2003), which allows the temporally controlled expression of a given effector gene in a defined set of cells. Comparing effector genes which either block neurotransmission or ablate cells showed important differences, revealing that selection of the appropriate effector gene is critical for evaluating the function of neural circuits. In the second part, a new engram of olfactory memory in the Drosophila projection neurons is described by restoring Rutabaga adenlylate cyclase (rut-AC) activity specifically in these cells. Expression of wild-type rutabaga in the projection neurons fully rescued the defect in sugar reward memory, but not in aversive electric shock memory. No difference was found in the stability of the appetitive memories rescued either in projection neurons or Kenyon cells. In the third part of the thesis I tried to understand how the reinforcing signals for sugar reward are internally represented. In the bee Hammer (1993) described a single octopaminergic neuron - called VUMmx1 - that mediates the sugar stimulus in associative olfactory reward learning. Analysis of single VUM neurons in the fly (Selcho, 2006) identified a neuron with a similar morphology as the VUMmx1 neuron. As there is a mutant in Drosophila lacking the last enzymatic step in octopamine synthesis (Monastirioti et al., 1996), Tyramine beta Hydroxylase, I was able to show that local Tyramine beta Hydroxylase expression successfully rescued sugar reward learning. This allows to conclude that about 250 cells including the VUM cluster are sufficient for mediating the sugar reinforcement signal in the fly. The description of a VUMmx1 similar neuron and the involvement of the VUM cluster in mediating the octopaminergic sugar stimulus are the first steps in establishing a neuronal map for US processing in Drosophila. Based on this work several experiments are contrivable to reach this ultimate goal in the fly. Taken together, the described similiarities between Drosophila and honeybee regarding the memory organisation in MBs and PNs and the proposed internal representation of the sugar reward suggest an evolutionarily conserved mechanism for appetitive olfactory learning in insects.}, subject = {Taufliege}, language = {en} } @phdthesis{Bertolucci2008, author = {Bertolucci, Franco}, title = {Operant and classical learning in Drosophila melanogaster: the ignorant gene (ign)}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-33984}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2008}, abstract = {One of the major challenges in neuroscience is to understand the neuronal processes that underlie learning and memory. For example, what biochemical pathways underlie the coincidence detection between stimuli during classical conditioning, or between an action and its consequences during operant conditioning? In which neural substructures is this information stored? How similar are the pathways mediating these two types of associative learning and at which level do they diverge? The fly Drosophila melanogaster is an appropriate model organism to address these questions due to the availability of suitable learning paradigms and neurogenetic tools. It permits an extensive study of the functional role of the gene S6KII which in Drosophila had been found to be differentially involved in classical and operant conditioning (Bertolucci, 2002; Putz et al., 2004). Genomic rescue experiments showed that olfactory conditioning in the Tully machine, a paradigm for Pavlovian olfactory conditioning, depends on the presence of an intact S6KII gene. This rescue was successfully performed on both the null mutant and a partial deletion, suggesting that the removal of the phosphorylating unit of the kinase was the main cause of the functional defect. The GAL4/UAS system was used to achieve temporal and spatial control of S6KII expression. It was shown that expression of the kinase during the adult stage was essential for the rescue. This finding ruled out a developmental origin of the mutant learning phenotype. Furthermore, targeted spatial rescue of S6KII revealed a requirement in the mushroom bodies and excluded other brain structures like the median bundle, the antennal lobes and the central complex. This pattern is very similar to the one previously identified with the rutabaga mutant (Zars et al., 2000). Experiments with the double mutant rut, ign58-1 suggest that both rutabaga and S6KII operate in the same signalling pathway. Previous studies had already shown that deviating results from operant and classical conditioning point to different roles for S6KII in the two types of learning (Bertolucci, 2002; Putz, 2002). This conclusion was further strengthened by the defective performance of the transgenic lines in place learning and their normal behavior in olfactory conditioning. A novel type of learning experiment, called "idle experiment", was designed. It is based on the conditioning of the walking activity and represents a purely operant task, overcoming some of the limitations of the "standard" heat-box experiment, a place learning paradigm. The novel nature of the idle experiment allowed exploring "learned helplessness" in flies, unveiling astonishing similarities to more complex organisms such as rats, mice and humans. Learned helplessness in Drosophila is found only in females and is sensitive to antidepressants.}, subject = {Klassische Konditionierung}, language = {en} } @phdthesis{Yarali2008, author = {Yarali, Ayse}, title = {Aspects of predictive learning in the fruit fly}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-28741}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2008}, abstract = {Past experience contributes to behavioural organization mainly via learning: Animals learn otherwise ordinary cues as predictors for biologically significant events. This thesis studies such predictive, associative learning, using the fruit fly Drosophila melanogaster. I ask two main questions, which complement each other: One deals with the processing of those cues that are to be learned as predictors for an important event; the other one deals with the processing of the important event itself, which is to be predicted. Do fruit flies learn about combinations of olfactory and visual cues? I probe larval as well as adult fruit flies for the learning about combinations of olfactory and visual cues, using a so called 'biconditional discrimination' task: During training, one odour is paired with reinforcement only in light, but not in darkness; the other odour in turn is reinforced only in darkness, but not in light. Thus, neither the odours nor the visual conditions alone predict reinforcement, only combinations of both do. I find no evidence that either larval or adult fruit flies were to solve such task, speaking against a cross-talk between olfactory and visual modalities. Previous studies however suggest such cross-talk. To reconcile these results, I suggest classifying different kinds of interaction between sensory modalities, according to their site along the sensory-motor continuum: I consider an interaction 'truly' cross-modal, if it is between the specific features of the stimuli. I consider an interaction 'amodal' if it instead engages the behavioural tendencies or 'values' elicited by each stimulus. Such reasoning brings me to conclude that different behavioural tasks require different kinds of interaction between sensory modalities; whether a given kind of interaction will be found depends on the neuronal infrastructure, which is a function of the species and the developmental stage. Predictive learning of pain-relief in fruit flies Fruit flies build two opposing kinds of memory, based on an experience with electric shock: Those odours that precede shock during training are learned as predictors for punishment and are subsequently avoided; those odours that follow shock during training on the other hand are learned as signals for relief and are subsequently approached. I focus on such relief learning. I start with a detailed parametric analysis of relief learning, testing for reproducibility as well as effects of gender, repetition of training, odour identity, odour concentration and shock intensity. I also characterize how relief memories, once formed, decay. In addition, concerning the psychological mechanisms of relief learning, first, I show that relief learning establishes genuinely associative conditioned approach behaviour and second, I report that it is most likely not mediated by context associations. These results enable the following neurobiological analysis of relief learning; further, they will form in the future the basis for a mathematical model; finally, they will guide the researchers aiming at uncovering relief learning in other experimental systems. Next, I embark upon neurogenetic analysis of relief learning. First, I report that fruit flies mutant for the so called white gene build overall more 'negative' memories about an experience with electric shock. That is, in the white mutants, learning about the painful onset of shock is enhanced, whereas learning about the relieving offset of shock is diminished. As they are coherently affected, these two kinds of learning should be in a balance. The molecular mechanism of the effect of white on this balance remains unresolved. Finally, as a first step towards a neuronal circuit analysis of relief learning, I compare it to reward learning and punishment learning. I find that relief learning is distinct from both in terms of the requirement for biogenic amine signaling: Reward and punishment are respectively signalled by octopamine and dopamine, for relief learning, either of these seem dispensible. Further, I find no evidence for roles for two other biogenic amines, tyramine and serotonin in relief learning. Based on these findings I give directions for further research.}, subject = {Lernen}, language = {en} } @phdthesis{Saverschek2010, author = {Saverschek, Nicole}, title = {The influence of the symbiotic fungus on foraging decisions in leaf-cutting ants - Individual behavior and collective patterns}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-52087}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {Foraging behavior is a particularly fascinating topic within the studies of social insects. Decisions made by individuals have effects not only on the individual level, but on the colony level as well. Social information available through foraging in a group modulates individual preferences and shapes the foraging pattern of a colony. Identifying parameters influencing foraging behavior in leaf-cutting ants is especially intriguing because they do not harvest for themselves, but for their symbiotic fungus which in turn influences their plant preferences after the incorporation of the substrate. To learn about the substrates' unsuitability for the fungus, ants need to be able to identify the incorporated substrate and associate it with detrimental effects on the fungus. Odor is an important plant characteristic known to be used as recognition key outside the nest in the context of foraging. Chapter 1 shows that foragers are able to recall information about the unsuitability of a substrate through odor alone and consequently reject the substrate, which leads to the conclusion that inside the nest, odor might be enough to indentify incorporated substrate. Identification of plant species is a key factor in the foraging success of leaf-cutting ants as they harvest a multitude of different plant species in a diverse environment and host plant availability and suitability changes throughout the year. Fixed plant preferences of individuals through innate tendencies are therefore only one factor influencing foraging decisions. On the individual as well as the colony level, foraging patterns are flexible and a result of an intricate interplay between the different members involved in the harvesting process: foragers, gardeners and the symbiotic fungus. In chapter 2 I identified several conditions necessary for na{\"i}ve foragers to learn about the unsuitability of substrate inside the nest. In order to exchange of information about the unsuitability of a substrate, the plant in question must be present in the fungus garden. Foragers can learn without own foraging experience and even without experiencing the effects of the substrate on the fungus, solely through the presence of experienced gardeners. The presence of experienced foragers alone on the other hand is not enough to lower the acceptance of substrate by na{\"i}ve foragers in the presence of na{\"i}ve gardeners, even if experienced foragers make up the majority of the workforce inside the nest. Experienced foragers are also able to reverse their previous negative experience and start accepting the substrate again. The individual behavior of foragers and gardeners with different experiential backgrounds in the presence of suitable or unsuitable substrate inside the fungus chamber was investigated in chapter 3 to shed some light on possible mechanisms involved in the flow of information about substrate suitability from the fungus to the ants. Gardeners as well as foragers are involved in the leaf processing and treatment of the applied leaf patches on the fungus. If the plant material is unsuitable, significantly more ants treat the plant patches, but foragers are less active overall. Contacts between workers initiated by either gardeners or foragers occur significantly more frequent and last longer if the substrate is unsuitable. Even though experienced gardeners increase na{\"i}ve foragers' contact rates and duration with other workers in the presence of suitable plant patches, na{\"i}ve foragers show no differences in the handling of the plant patches. This suggests that foragers gain information about plant suitability not only indirectly through the gardening workers, but might also be able to directly evaluate the effects of the substrate on the fungus themselves. Outside the nest, foragers influence each other the trail (chapter 4). Foraging in a group and the presence of social information is a decisive factor in the substrate choice of the individual and leads to a distinct and consentaneous colony response when encountering unfamiliar or unsuitable substrates. As leaf-cutting ants harvest different plant species simultaneously on several trails, foragers gain individual experiences concerning potential host plants. Preferences might vary among individuals of the same colony to the degree that foragers on the same trail perceive a certain substrate as either suitable or unsuitable. If the majority of foragers on the trail perceives one of the currently harvested substrates as unsuitable, na{\"i}ve foragers lower their acceptance within 4 hours. In the absence of a cue in the fungus, na{\"i}ve foragers harvesting by themselves still eventually (within 6 hours) reject the substrate as they encounter experienced gardeners during visits to the nest within foraging bouts. As foraging trails can be up to 100 m long and foragers spend a considerable amount of time away from the nest, learning indirectly from experienced foragers on the trail accelerates the distribution of information about substrate suitability. The level of rejection of a formerly unsuitable substrate after eight hours of foraging by na{\"i}ve foragers correlates with the average percentage of unladen experienced foragers active on the trail. This suggests that unladen experienced foragers might actively contact laden na{\"i}ve workers transmitting information about the unsuitability of the load they carry. Results from experiments were I observed individual laden foragers on their way back to the nest backed up this assumption as individuals were antennated and received bites into the leaf disk they carried. Individuals were contacted significantly more often by nestmates that perceived the carried leaf disk as unsuitable due to previous experience than by nestmates without this experience (chapter 6). Leaf-cutting ants constantly evaluate, learn and re-evaluate the suitability of harvested substrate and adjust their foraging activity accordingly. The importance of the different sources of information within the colony and their effect on the foraging pattern of the colony depend on the presence or absence of each of them as e.g. experienced foragers have a bigger influence on the plant preferences of na{\"i}ve foragers in the absence of a cue in the fungus garden.}, subject = {Blattschneiderameisen}, language = {en} } @phdthesis{Andreatta2010, author = {Andreatta, Marta}, title = {Emotional reactions after event learning : a Rift between Implicit and Explicit Conditioned Valence in Humans Pain Relief Lerning}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-55715}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {Organismen vermeiden Gefahren und streben nach Belohnungen, um zu {\"u}berleben. Klassische Konditionierung ist ein einfaches Model, das erkl{\"a}rt, wie Tiere und Menschen Ereignisse in Verbindung bringen. Dieses Lernen erm{\"o}glicht Lebewesen Gefahr oder Belohnung direkt vorherzusehen. Normalerweise besteht das Konditionierungsparadigma aus der Pr{\"a}sentation eines neutralen Stimulus zusammen mit einem biologisch bedeutsamen Event (der unkonditionierte Stimulus - US). Aufgrund dieser Assoziation erwirbt der neutrale Stimulus affektive Eigenschaften und wird dann konditionierter Stimulus (CS+) genannt. Wenn der CS+ mit Schmerz w{\"a}hrend der Trainingsphase assoziiert wird, leitet er eine defensive Reaktion, wie z.B. Vermeidung ein. Wenn der CS+ mit einer Belohnung assoziiert wird, leitet er eine appetitive Reaktion, wie z.B. Ann{\"a}herungsreaktionen ein. Interessanterweise haben Tierstudien gezeigt, dass ein konditionierter Stimulus vermieden wurde, wenn er einem aversiven US in der Trainingsphase vorausgegangen war (CS+US; Vorw{\"a}rtskonditionierung). Das deutet darauf hin, dass der CS+ aversive Eigenschaften erlangt hat. Jedoch f{\"u}hrte ein konditionierter Stimulus zu einer Ann{\"a}herung, wenn er in der Trainingsphase auf einen aversiven US folgt (US CS+; R{\"u}ckw{\"a}rtskonditionierung). Das deutet darauf hin, dass der CS+ appetitive Eigenschaften erlangt hat. Kann das Event Timing sowohl aversive als auch appetitive konditionierten Reaktionen auch bei Menschen ausl{\"o}sen, die zu Kognitionen bez{\"u}glich der Assoziationen f{\"a}hig sind? Um diese Fragestellung zu beantworten, wurden vier Studien durchgef{\"u}hrt. Die Studien hatten den gleichen Ablauf, variiert wurde nur die Zeit zwischen CS+ und US (das Interstimulusintervall - ISI - ist als das Zeitintervall zwischen dem Onset des CS+ und dem Onset des US definiert). W{\"a}hrend der Akquisitionsphase (Konditionierung) wurden, zwei einfache geometrische Figuren als konditionierte Stimuli dargeboten. Eine geometrische Figur (der CS+) war immer mit einem leichten schmerzhaften elektrischen Reiz (der aversive US) assoziiert; die andere Figur (der CS-) war nie mit dem elektrischen Reiz assoziiert. In einem between-subjects Design wurde entweder eine Vorw{\"a}rtskonditionierung oder eine R{\"u}ckw{\"a}rtskonditionierung durchgef{\"u}hrt. W{\"a}hrend der Testsphase (Extinktion) wurden CS+ und CS- pr{\"a}sentiert sowie zus{\"a}tzlich eine neue neutrale geometrische Figur pr{\"a}sentiert, die als Kontrollstimulus fungierte; der US wurde in dieser Phase nie dargeboten. Vor und nach der Konditionierung wurden die Probanden sowohl bez{\"u}glich der Valenz (bzw. Unangenehmheit und Angenehmheit) als auch der Erregung (bzw. Ruhe und Aufregung) hinsichtlich der geometrischen Figuren befragt. In der ersten Studie wurde der Schreckreflex (Startle Reflex) als Maß f{\"u}r die implizite Valenz der Stimuli gemessen. Der Schreckreflex ist eine defensive Urreaktion, die aus einem Muskelzucken des Gesichts und des K{\"o}rpers besteht. Dieser Reflex ist durch pl{\"o}tzliche und intensive visuelle, taktile oder akustische Reize evoziert. Einerseits war die Amplitude des Startles bei der Anwesenheit des vorw{\"a}rts CS+ potenziert und das deutet daraufhin, dass der CS+ eine implizite negative Valenz nach der Vorw{\"a}rtskonditionierung erworben hat. Anderseits war die Amplitude des Startles bei der Anwesenheit des r{\"u}ckw{\"a}rts CS+ abgeschw{\"a}cht, was darauf hin deutet, dass der CS+ nach der R{\"u}ckw{\"a}rtskonditionierung eine implizite positive Valenz erworben hat. In der zweiten Studie wurde die oxygenierte Bloodsresponse (BOLD) mit funktioneller Magnetresonanztomographie (fMRI) erhoben, um neuronale Korrelate des Event-Timings zu erfassen. Eine st{\"a}rkere Aktivierung wurde in der Amygdala in Erwiderung auf den vorw{\"a}rts CS+ und im Striatum in Erwiderung auf den r{\"u}ckw{\"a}rts CS+ gefunden. Zum Einen entspricht dies einer Aktivierung des Defensive Motivational Systems, da die Amygdala eine wichtige Rolle beim Angstexpression und Angstakquisition hat. Deshalb wurde der vorw{\"a}rts CS+ als aversiv betrachtet. Zum Anderen entspricht dies einer Aktivierung des Appetitive Motivational System, da das Striatum eine wichtige Rolle bei Belohnung hat. Deshalb wurde der r{\"u}ckw{\"a}rts CS+ als appetitiv betrachtet. In der dritten Studie wurden Aufmerksamkeitsprozesse beim Event-Timing n{\"a}her beleuchtet, indem steady-state visuelle evozierte Potentiale (ssVEP) gemessen wurden. Sowohl der vorw{\"a}rts CS+ als auch der r{\"u}ckw{\"a}rts CS+ zog Aufmerksamkeit auf sich. Dennoch war die Amplitude der ssVEP großer w{\"a}hrend der letzen Sekunden des vorw{\"a}rts CS+, d.h. direkt vor dem aversiven US. Die Amplitude der ssVEP war aber gr{\"o}ßer w{\"a}hrend der ersten Sekunden des r{\"u}ckw{\"a}rts CS+, d.h. kurz nach dem aversiven US. Vermutlich wird die Aufmerksamkeit auf den hinsichtlich des aversiven US informativsten Teil des CS+. Alle Probanden der drei Studien haben den vorw{\"a}rts CS+ und den r{\"u}ckw{\"a}rts CS+ negativer und erregender als den Kontrollstimulus beurteilt. Daher werden die expliziten Ratings vom Event-Timing nicht beeinflusst. Bemerkenswert ist die Dissoziation zwischen den subjektiven Ratings und den physiologischen Reaktionen. Nach der Dual-Prozess Theorie werden die Verhaltensreaktionen des Menschen von zwei Systemen determiniert: einem impulsiv impliziten System, das auf assoziativen Prinzipien beruht, und einem reflektiv expliziten System, das auf der Kenntnis {\"u}ber Fakten und Werte basiert. Wichtig ist, dass die zwei Systeme auf synergetische oder antagonistische Weise agieren k{\"o}nnen. Folglich k{\"o}nnte es sein, dass das impulsive und das reflektive System nach der R{\"u}ckw{\"a}rtskonditionierung antagonistisch arbeiten. Zusammen deuten die vorliegenden Studien daraufhin, dass Event-Timing eine Bestrafung in eine Belohnung umwandeln kann, aber die Probanden erleben den Stimulus assoziiert mit einem aversiven Event als negativ. Diese Dissoziation k{\"o}nnte zum Verst{\"a}ndnis der psychiatrischen St{\"o}rungen wie z.B. Angstst{\"o}rungen oder Drogenabh{\"a}ngigkeit beitragen.}, subject = {Gef{\"u}hl}, language = {en} } @phdthesis{Eschbach2011, author = {Eschbach, Claire}, title = {Classical and operant learning in the larvae of Drosophila melanogaster}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-70583}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {In dieser Doktorarbeit studiere ich einige psychologische Aspekte im Verhalten der Drosophila, insbesondere von Drosophila Larven. Nach einer Einleitung, in der ich den wissenschaftlichen Kontext darstelle und die Mechanismen der olfaktorischen Wahrnehmung sowie des klassichen und operanten Lernens beschreibe, stelle ich die verschiedenen Experimente meiner Doktorarbeit vor. Wahrnehmung Das zweite Kapitel behandelt die Art, in der adulte Drosophila zwischen Einzeld{\"u}ften und Duftgemischen generaliseren. Ich habe gefunden, daß die Fliegen eine Mischung aus zwei D{\"u}ften als gleich verschieden von ihren beiden Elementen wahrnehmen; und daß die Intensit{\"a}t sowie die chemisch-physikalische Natur der Elemente das Ausmass der Generalisierung zwischen der Mischung und ihren beiden Elementen beeinflusst. Diese Entdeckungen sollten f{\"u}r die weitere Forschung anregend sein, wie zum Beispiel zum functional imaging. Ged{\"a}chtnis Das dritte Kapitel stellt die Etablierung eines neuen Protokolls zur klassischen Konditionierung bei Drosophila Larven dar. Es handelt sich um Experimente, bei denen ein Duft mit einer mechanischen St{\"o}rung als Strafreiz verkn{\"u}pft wird. Das Protokoll wird einen Vergleich zwischen zwei Arten vom aversiven Ged{\"a}chtnissen (Geschmack vs. mechanische St{\"o}rung als Strafreize) erm{\"o}glichen, einschliesslich eines Vergleiches ihrer neurogenetischen Grundlagen; zudem kann nun geforscht werden, ob die jeweiligen Ged{\"a}chtnisse spezifisch f{\"u}r die Art des verwendeten Strafreizes sind. Selbstgestaltung Das vierte Kapitel umfasst unsere Versuche, operantes Ged{\"a}chtnis bei Drosophila Larven zu beobachten. Zumindest f{\"u}r die unmittelbar ersten Momente des Tests konnte ich zeigen, dass die Larven ihr Verhalten entsprechend dem Training ausrichten. Dieses Ged{\"a}chtnis scheint jedoch im Laufe des Tests schnell zu verschwinden. Es ist daher geraten, diese Ergebnisse {\"u}ber operantes Lernen zu wiederholen, eventuell das experimentelle Protokoll zu verbessern, um so eine systematische Analyse der Bedingungen und Mechanismen f{\"u}r das operante Lernen bei der Drosophila Larve zu erlauben. Im f{\"u}nften Kapitel verwende ich die im Rahmen des vierten Kapitels entwickelten Methoden f{\"u}r eine Analyse der Fortbewegung der Larven. Ich habe insbesondere die Wirkung des pflanzlichen ‚cognitive enhancers' Rhodiola rosea untersucht, sowie die Auswirkungen von Mutationen in den Genen, welche f{\"u}r Synapsin und SAP47 kodieren; schliesslich habe ich getestet, ob die Geschmacksqualit{\"a}t der Testsituation lokomotorische Parameter ver{\"a}ndert. Diese Dissertation erbringt also eine Reihe neuer Aspekte zur Psychologie der Drosophila und wird hoffentlich in diesem Bereich der Forschung neue Wege {\"o}ffnen.}, subject = {Lernen}, language = {en} }