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  • Light Adaptation by Stochastic Adaptive Sampling in Fly Photoreceptors---- A Multi-Scale Modelling Approach
  • Reporter:Dr Song Zhuoyi
  • Reporter brief:
  • Location:Room 2201, East Guanghua Building
  • Time:2:00 p.m. on Monday (August.8 2016)
  • Title:  Light Adaptation by Stochastic Adaptive Sampling in Fly Photoreceptors—- A Multi-Scale Modelling Approach

    Time: 2:00  p.m. on Monday (August.8 2016) at Room 2201, East Guanghua Building

    Presenter: Dr Song Zhuoyi | University of Sheffield (UoS), UK

    Abstract: 

    In neuroscience, it is a traditional challenge to understand the input-output relationship of a sensory neuron. In the context of vision, how do a photoreceptor constantly adjust this relationship, so that it could effectively utilise the limited response range to represent the dramatic large input range from starlight to direct sunlight?

    We recently uncovered such mysteries by generating realistic computational models of fly photoreceptors. The models explain how this adaptation process could be understood by a stochastic adaptive sampling principle out of only 4 parameters.

    A Drosophila photoreceptor integrates light information by stochastic adaptive sampling rule. Its photo-sensitive waveguide (rhabdomere) consists of ~30,000 microvilli, each of which is capable of generating single photon responses (quantum bumps). So a fly photoreceptor is essentially a photon counter from a sampling point of view, with each photon counted as a bump.

    In this talk, I will explain how the light adaptation dynamics emerge from the sampling of a huge population of refractory units, how the refractoriness in sampling help to boost contrast changes, and how the neuronal responses are characterised by 4 key sampling parameters. I would also explain how stochasticity in the sampling process contributes to visual information encoding, how a gain control mechanism results in adaptive sampling that approximates contrast constancy.

    At last, I will show that such a stochastic adaptive sampling principle accurately predicts information processing across a range of fly species with different visual ecologies, supporting its general role in encoding sensory information. It will be interesting to examine whether this encoding principle is also applicable to other sensory neurons or to a population of synapses/neurons.

    Bio:

    Dr. Zhuoyi Song is currently a research fellow of computational neuroscience at the University of Sheffield (UoS), UK. Her current work focuses on developing multi-scale modeling and inference framework for understanding signal transduction mechanisms in sensory receptor neurons. She received combined training in both Engineering and Biomedical Science disciplines. She obtained both of her undergraduate and master degree in Electrical Engineering and Control Theory. She then got a Ph.D. in the interdisciplinary area of computational neuroscience at UoS in 2011. She continued her postdoctoral training in Prof. Mikko Juusola’s lab, biomedical Science department, UoS.  In 2013, she received a prestigious 2020 Science research fellowship in UCL, London in computational life science. Her research has been published in Current Biology (IF>10), Journal of Neuroscience (IF>7), etc. She has given many talks at University of Oxford, UCL, etc. She has also received many international awards (>20) for training, including travel grants,  paper prizes and research internships.