The Journal of Neuroscience, October 10, 2007, ():
Identification and Characterization of a Y-Like Primate Retinal Ganglion Cell Type
J. Neurosci. Petrusca et al.
27: 11019
Supplemental Data
Files in this Data Supplement:
- supplemental material
-
s1 (Supplementary movie 1): animated version of figure 2a. Electrophysiological image of a parasol cell showing the average electrical activity of the cell around the time it generates a spike, projected onto the two-dimensional plane of the multielectrode array. The location of each circle corresponds to an electrode location; the circle diameter is proportional to the absolute signal amplitude recorded on the electrode (electrodes with amplitudes below 5 microvolts are not shown). The animation begins 0.9 ms before the peak of the spike and ends 4.1 ms after the spike peak. The time interval between frames is 50 microsec. The propagation of the signal along the axon can be seen.
- supplemental material
-
s2 (Supplementary movie 2): animated version of figure 2b. Electrophysiological image of an upsilon cell showing the average electrical activity of the cell around the time it generates a spike, projected onto the two-dimensional plane of the multielectrode array. The location of each circle corresponds to an electrode location; the circle diameter is proportional to the absolute signal amplitude recorded on the electrode (electrodes with amplitudes below 5 microvolts are not shown). The animation begins 0.9 ms before the peak of the spike and ends 4.1 ms after the spike peak. The time interval between frames is 50 microsec. The propagation of the signal along the axon can be seen.
- supplemental material
-
s3 (Supplementary movie 3): animated version of figure 2c. Electrophysiological image of a spiking amacrine cell showing the average electrical activity of the cell around the time it generates a spike, projected onto the two-dimensional plane of the multielectrode array. The location of each circle corresponds to an electrode location; the circle diameter is proportional to the absolute signal amplitude recorded on the electrode (electrodes with amplitudes below 5 microvolts are not shown). The animation begins 0.9 ms before the peak of the spike and ends 4.1 ms after the spike peak. The time interval between frames is 50 microsec. (For clarity, the circle diameters were truncated such that the circles do not overlap.) The propagation of signals outward through the axonal arbour can be seen.
