Visual transduction is the process by which light, captured by photopigment inside retinal cells, generates an electrical response on the plasma membrane of the cell. It involves interaction and diffusion of substances (so called second messengers) in the cell. A spectacular site about the physiology of the eye is WebVsion. Here is a spectacular micrograph of a fruitfly retina.

We are developing computational models of the protein cascade on the discs, interactions with and diffusive transport of the two primary second messengers, cGMP and Ca²⁺, in the cytosol, and interactions at the outer membrane generating an electrical signal, in response to photons hitting any of the ~1000 "discs" inside a typical vertebrate rod cell.

The numerical models, derived via finite volume discretization, are parallelized via domain decomposition for distributed computation on clusters or networked workstations.

• UPoN 2002 Conference AIP Proceedings reprint (.pdf)
  [ Computations performed on Compaq (Alpha ev67 processors)
    and on IBM pSeries (power 4 processors) clusters at Oak Ridge National Laboratory. ]

• Dynamic Systems and Applications 4, pp.138-145, 2004 reprint (.pdf)

• Systems Biology 152(3): 119-137, Sep 2005 reprint (.pdf)

• Multiphoton response
  • Mississippi State Conference, May 2005, talk slides in html
  • EJDE preprint (in xml, via TtM)
    [ Computations performed on a linux cluster (Opteron 242 processors) at Oak Ridge National Laboratory. ]

• Dynamic Systems and Applications 5, 2008
  • Parameter estimation   preprint   (in xml, via TtM)   reprint   (.pdf)
  • Comparison of models   reprint   (.pdf)