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About Susanne Schmid

Dr. Susanne Schmid is a professor in the department of Anatomy and Cell Biology whose research mainly concerns cell and molecular mechanisms of sensory processes and sensory filtering in the context of neurodevelopmental disorders such as autism.

Children's Health Collaborators: Janis Cardy, Robert Nicolson, and Stephen Renaud

Dr. Susanne Schmid studied Biology in Tübingen (Germany) and São Paulo (Brazil). She was trained as an electrophysiologist (patch-clamp recordings in brain slices) during her PhD working at the University Eye Hospital in Tübingen under Dr. Guenther and Professor Zrenner. Dr. Schmid started her own independent group in 2000 in the Animal Physiology Department (Professor Schnitzler) at the University of Tübingen, Germany. In 2006, she spent a year at the University of Toronto as a Heisenberg Fellow working with John Yeomans, before she moved to Western in 2007.

Dr. Schmid was always interested in synaptic plasticity, first during retinal development, and later, when she founded her own group, in relation to behavioural plasticity and learning. Habituation of startle is an excellent model to explore cellular and molecular mechanisms of learning in mammals. Habituation is also a sensory filtering mechanism, therefore she started to study other sensory filtering mechanisms as well, most importantly prepulse inhibition. Both habituation and prepulse inhibition are also measured in humans and are clinically highly relevant.

Research Interests:
Mammalian brains are complex structures mediating complex behavioural tasks. It is one of the major challenges for modern Neuroscience to find out how the mammalian brain processes sensory information in order to generate the appropriate behavioural response.
Our brain is constantly bombarded with sensory information coming from the ears, eyes, nose, tongue body surface, and interior. Most of this information is filtered pre-attentively in order to allow the brain to allocate its neural resources on focussing on salient information. Many mental disorders and neurodegenerative diseases are associated with impairments of sensory filtering, which is closely related to other cognitive deficits. Our research concentrates on these early stages of sensory information processing and filtering.

Habituation is a form of sensory filtering and also a very essential form of implicit learning; we all perform habituation learning innumerable times during a day without perceiving it. Some psychiatric disorders are accompanied by an impairment of habituation. In order to access the cellular and molecular processes that are responsible for habituation, we use the acoustic startle response and exploratory behaviour in an open field as behavioural models. We have also developed a rodent brain slice preparation that contains a large portion of the startle pathway and allows combining patch-clamp recordings in vitro with pharmacological treatment in vivo. Using this preparation we found that afferent sensory fibres within the startle pathway are subject to synaptic depression when stimulated in a way that mimics their activity during the presentation of startle stimuli. Synaptic depression shares many features with habituation. One specific goal of our research is to explore the molecular mechanism that leads to synaptic depression and to test our hypothesis that this is the cellular mechanism underlying short-term habituation of startle. We aim to completely unravel the cellular and molecular mechanisms of short-term habituation of startle and it will be interesting to see to what extend the same mechanisms underlie habituation of exploratory behavior.

Prepulse Inhibition:
Startle responses are inhibited by a preceding non-startling stimulus (prepulse). Prepulse inhibition (PPI) is considered to represent an ubiquitous sensory filter mechanism in our brain that protects the processing of sensory stimuli. An impairment of PPI is one of the major symptoms in schizophrenia and some other neurological disorders. We explore neurotransmitters, receptors and second messenger pathways that mediate PPI in rodents. Animal models for schizophrenia are included in our experiments in order to examine the difference in signalling in these animals. One focus is on the role of cholinergic neurons in PPI and in sensory filtering in general. Our results will provide more understanding about cellular dysfunction in schizophrenics and will possibly indicate new targets for pharmaceutical intervention. In a side project we also examine disruptions of midbrain cholinergic neurotransmission in Parkinson’s disease.


Present Professor, Western University Department of Psychology
Present Professor, Vice Dean of Basic Medical Sciences, Western University Department of Anatomy and Cell Biology
Present Scientist, Lawson Health Research Institute ‐ Children's Health Research Institute (CHRI)


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Recent Works (37)