Neural adaptation in the auditory pathway of crickets and grasshoppers

Hildebrandt, Kai Jannis

06 July 2010

Neuronale Adaptation dient dazu, eine Sinnesbahn kurzfristig an die aktuelle Umgebung des Tieres anzupassen. Ihr zeitlicher Verlauf lässt sich in der Antwort einzelner Nervenzellen direkt beobachten. Der Adaptation unterliegen eine Vielzahl verschiedener Mechanismen, die über die gesamte Sinnesbahn verteilt sein können. In der vorliegenden Arbeit wurde der Versuch unternommen, diese unterschiedlichen Betrachtungsebenen zusammenzuführen. Dazu wurden mehrere experimentelle und theoretische Studien durchgeführt. In zwei der vorgestellten Studien wurden Kombinationen aus Strominjektionen und akustischen Reizen verwendet, um intrinsische Adaptation von Netzwerkeffekten zu trennen. Dabei ergab sich in einer experimentellen Studie am auditorischen System der Heuschrecke, dass die Adaptationsmechanismen, die in verschiedenen Teilen der Hörbahn rekrutiert werden, sehr stark von Identität und Funktion der jeweils untersuchten Nervenzelle abhängen. Ähnliche Methoden ermöglichten es, im auditorischen System der Grille präsynaptische Hemmung als Substrat für die wichtige mathematische Operation der Division zu identifizieren. Zusätzlich wurden Modellierungen durchgeführt, bei denen die Frage bearbeitet wurde, wo Adaptation in der Hörbahn wirken sollte, bezogen auf zwei verschieden Aufgaben: die Lokalisation eines Signals und die neuronale Abbildung dessen zeitlicher Struktur. Die Ergebnisse dieser Studie deuten darauf hin, dass die Anforderungen für diese beiden Aufgaben sehr unterschiedliche sind. In einer vierten Studie wurde untersucht, ob die Adaptation in einem auditorischen Interneuron der Grille dazu dient, die gesamte sensorische Umgebung gut abzubilden, oder ob durch die Adaptation eine Abtrennung des jeweils lautesten Signals erreicht werden kann. Zusammenfassend lässt sich sagen, dass sowohl die Adaptationsmechanismen, als auch deren genaue Platzierung innerhalb der sensorischen Bahn wesentlich für Sinnesleistungen sind. / Neural adaptation serves to adjust the sensory pathway to the current environment of an animal. While the effect and time course of adaptation can be observed directly within single cells, its underlying cause is a combination of many different mechanisms spread out along the sensory pathway. The present work has the objective to unite these different levels of understanding of the term adaptation. In order to do so, several experimental and theoretical studies were carried out. In two of these studies, a combination of current injection and auditory stimulation was used, in order to disentangle intrinsic adaptation from network effects. In one of the studies, carried out in the auditory system of locusts, it was revealed that the mechanisms behind adaptation that are activated within different parts of the auditory system depend critically on identity and function of the cell under study. Similar methods enabled the identification of presynaptic inhibition as a possible mechanisms behind the important mathematical operation of division in the auditory system of crickets. Additionally, a modeling study pursued the question, where adaption should work in the auditory system from the perspective of two different tasks of sensory processing: identification of a signal and localization of its source. The results obtained from the model suggest conflicting demands for these two tasks and also present a solution of this conflict. In a fourth study, it was asked wether adaptation in the auditory system of crickets serves to guarantee optimal representation of the entire sensory environment or if it helps to separate one most important signal from the background. In summary, not only which mechanisms of adaptation are at work is of crucial importance for sensory processing, but also the exact placement of these along the pathway.

senosorische Adaptation

auditorisches System

Computational Neuroscience

Insekten

auditory system

sensory adaptation

computational neuroscience

insects

570 Biologie

32 Biologie

WW 1620

ddc:570

INVESTIGATION OF AN ADAPTATION-INDUCED TACTILE SPATIAL ILLUSION: PSYCHOPHYSICS AND BAYESIAN MODELING / INVESTIGATION OF AN ADAPTATION-INDUCED TACTILE SPATIAL ILLUSION

Li, Luxi

11 1900

Sensory adaptation is an important aspect of perception. A seemingly non-beneficial consequence of adaptation is that it produces perceptual illusions. For instance, following focal adaptation, the perceived separation between stimuli straddling the adapted attribute or region is often exaggerated. This type of illusion, known as perceptual repulsion, is both a consequence of and a clue to the brain’s coding strategies and how they are influenced by recent sensory events. Adaptation-induced perceptual repulsion has been well documented in vision (e.g. the tilt aftereffect) and to a lesser extent in audition, but rarely studied in touch. The present thesis investigated the effects of adaptation on tactile spatial perception using a combination of human psychophysics and computational modeling. In a two-interval forced choice task, participants compared the perceived separation between two point-stimuli applied on the forearms successively. The point of subjective equality was extracted as a measure of perceived two-point distance. We showed that tactile spatial perception is subject to an adaptation-induced repulsion illusion: vibrotactile adaptation focally reduced tactile sensitivity and significantly increased the perceived distance between points straddling the adapted skin site (Chapter 2). This repulsion illusion, however, was not observed when the intervening skin was desensitized with topical anesthesia instead of vibrotactile adaptation, suggesting that peripheral desensitization alone is insufficient to induce the illusion (Chapter 3). With Bayesian perceptual modeling, we showed that the illusion was consistent with the hypothesis that the brain decodes tactile spatial input without awareness of the adaptation state in the nervous system (Chapter 4). Together, the empirical and theoretical work furthers the understanding of dynamic tactile spatial coding as the somatosensory system adapts to the sensory environment. Its main findings are consistent with the adaptation- induced repulsion illusions reported in vision and audition, suggesting that perception in different sensory modalities shares common processing features and computational principles. / Thesis / Doctor of Philosophy (PhD) / Sensory adaptation can shape how we perceive the world. In this thesis, we showed that the perception of space in touch is pliable and subject to the influence of adaptation. Psychophysical testing in human participants showed that vibratory adaptation induced an illusion that expanded the perceived distance between stimuli on the skin. This illusion provides clues into how information about space in touch is normally processed and interpreted by the brain. In addition, we developed a computational model that used a powerful statistical framework – Bayesian inference – to probe touch on a theoretical basis. To the best of our knowledge, the present thesis provides the first combined psychophysical and computational study on the effects of adaptation on tactile spatial perception. Our findings suggest that touch shares some common information processing principles with vision and hearing, and adaptation plays a functionally similar role in mediating this process across the senses.

tactile perception

adaptation

tactile illusion

psychophysics

two-point perception

Bayesian

sensory adaptation

repulsion illusion

Bayes

Bayesian inference

touch

perceptual illusion

human psychophysics

somatosensory

vibrotactile adaptation

anesthesia

Bayesian perceptual model

EMLA

spatial perception

aftereffect