Ronen Segev Senior Lecturer Ph.D. Tel Aviv University, 2002 E-mail: ronensgv@bgu.ac.il Phone (Office): 972 8 647 9226 Phone (Lab): 972 8 647 9223 Fax: 972 8 646 1710 Office: Building 40, Room 405

Background

A fundamental question in neuroscience is how populations of neurons encode information relevant to the behavior of the organism by generating short electrical spikes called action potentials. These spikes, 1-3 ms in duration, are responsible for carrying information throughout the nervous system. An important test bed to study questions regarding the neural code is the retina. This is a very accessible sensory organ due to the extensive knowledge about single cell properties, anatomy and the fact that the function of the system is clear. We study the information encoding in the brain by asking how the retina tells the brain about the outside visual environment.

Current Projects

While the retina is the first stage of processing the visual scene, in order to put the study of the population code used by neuron in a global context, one needs to think about the path of information processing between the visual input at the retina and the motor output of an animal. Studying this path of decision-making by an animal requires appropriate selection of the animal model. In our lab we use the archer fish (Toxotes jaculatrix), which can shoot down insects hanging on foliage above water using a squirt of water from their mouth. The jet of water hits the insect and the insect falls into the water where the fish can feed on it. This remarkable ability relies, among other things, on the information streaming from the retina to the brain. In addition, it is possible to train an archer fish to shoot at an artificial target printed on a paper instead of an insect, making it possible to study the encoding of different features of the external visual environment by the retina. We study information encoding in the archer fish retina using a multi-electrode array technology. In this method, the isolated archer fish retina is placed on a multi-electrode array and then presented with a stimulus that matches the one used in the behavioral task. The multi-electrode array contains 100 to 256 microelectrodes that enable the simultaneous recording from many of ganglion cells. By studying the relation between the stimulus and the retinal response, we can understand the principles of the neural code of the archer fish retina.

Recent Publications

Ronen Segev, Elad Shcneidman, Joe Goodhouse and Michael J. Berry II. (2007) “The Role of Eye Movements in the Retinal Code for a Size Discrimination Task”. J. Neurophysiology  98: 1380–1391. 

R. Segev, J. Goodhouse, J. Puchalla, M.J. Berry II. (2004) “Recording spikes from a large fraction of the ganglion cells in a retinal patch”. Nature Neuroscience  7:1155 – 1162. 

Elad Schneidman, Michael J. Berry II, Ronen Segev and William Bialek. (2006) "Weak pairwise correlations imply strongly correlated network states in a neural population”. Nature 440: 1007-1012. 

Ronen Segev, Jason Puchalla, and Michael J. Berry II. (2006) “The Functional Organization of Ganglion Cells in the Salamander Retina”. J. Neurophysiology  95: 2277–2292. 

Shy Shoham, Daniel H. O'Connor and Ronen Segev. (2006) “How silent is the brain: is there a “dark matter” problem in neuroscience?”, Journal of Comparative Physiology – A 192: 777-784.