Spatial asymmetries in cat retinal ganglion cell responses

Gaudiano, Paolo; Przybyszewski, Andrzej W.; Wezel, Richard van; Grind, W. A. van de

doi:10.1007/s004220050467

Cited by 4 publications

(3 citation statements)

References 23 publications

(42 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For ganglion cells, this is illustrated in Figure 11. Gaudiano (1992aGaudiano ( ,b, 1994 and Gaudiano et al (1998) already suggested that receptive field size could play a role in the generation of retinal nonlinearities. Our results support this view, but the push-pull intraretinal connectivity he introduced does not seem to be necessary for nonlinear responses.…”

Section: Nonlinearities In Retinal Neuronal Responsesmentioning

confidence: 99%

The Influence of Different Retinal Subcircuits on the Nonlinearity of Ganglion Cell Behavior

2002

View full text Add to dashboard Cite

Y-type retinal ganglion cells show a pronounced, nonlinear, frequency-doubling behavior in response to modulated sinewave gratings. This is not observed in X-type cells. The source of this spatial nonlinear summation is still under debate. We have designed a realistic biophysical model of the cat retina to test the influence of different retinal cell classes and subcircuits on the linearity of ganglion cell responses. The intraretinal connectivity consists of the fundamental feedforward pathway via bipolar cells, lateral horizontal cell connectivity, and two amacrine circuits. The wiring diagram of X- and Y-cells is identical apart from two aspects: (1) Y-cells have a wider receptive field and (2) they receive input from a nested amacrine circuit consisting of narrow- and wide-field amacrine cells. The model was tested with contrast-reversed gratings. First and second harmonic response components were determined to estimate the degree of nonlinearity. By means of circuit dissection, we found that a high degree of the Y-cell nonlinear behavior arises from the spatial integration of temporal photoreceptor nonlinearities. Furthermore, we found a weaker and less uniform influence of the nested amacrine circuit. Different sources of nonlinearities interact in a multiplicative manner, and the influence of the amacrine circuit is approximately 25% weaker than that of the photoreceptor. The model predicts that significant nonlinearities occur already at the level of horizontal cell responses. Pharmacological inactivation of the amacrine circuit is expected to exert a milder effect in reducing ganglion cell nonlinearity.

show abstract

Section: Nonlinearities In Retinal Neuronal Responsesmentioning

confidence: 99%

The Influence of Different Retinal Subcircuits on the Nonlinearity of Ganglion Cell Behavior

2002

View full text Add to dashboard Cite

show abstract

“…Over the last four decades, several computational models have been proposed to explain the function of the retina as a whole, or of particular cell classes, in a variety of species (e.g., Rodieck 1965;Rodieck and Stone 1965a,b;Enroth-Cugell and Shapley 1973;Richter and Ullman 1982;Dawis et al 1984;Kruk and Wrobel 1986;Enroth-Cugell and Freeman 1987;Victor 1987a,b;Maguire et al 1989a;Ö g˘men and Gagne´1990b;Werblin 1991;Gaudiano 1992aGaudiano ,b,1994Maguire 1995;Shah and Levin 1996a,b;Gaudiano et al 1998;Awatramani et al 1997;Berry et al 1999;Wu et al 2000;Kamermans et al 2001). One emerging computational principle is that light adaptation is carried out by two complementary mechanisms: one is the control of transduction/transmission gain over time (temporal adaptation) (e.g., Grabowski et al 1972;Boynton and Whitten 1970;Dowling and Ripps 1972;Baylor et al 1974a,b;Carpenter and Grossberg 1981), and the second is the control of the activity distribution over the retinal network via spatial interactions among retinotopically neighboring cells (spatial adaptation) (Rodieck 1965;Rodieck and Stone 1965a,b;Richter and Ullman 1982;Fleet et al 1985;Enroth-Cugell and Freeman 1987;Ö g˘men and Gagne1 990b;Smirnakis et al 2000).…”

Section: Introductionmentioning

confidence: 99%

Neural computations in the tiger salamander and mudpuppy outer retinae and an analysis of GABA action from horizontal cells

Yang

Öğmen

Maguire³

2003

Biol. Cybern.

View full text Add to dashboard Cite

A neural network architecture based on the neural anatomy and function of retinal neurons in tiger salamander and mudpuppy retinae is proposed to study basic aspects of early visual information processing. The model predictions for the main response characteristics of retinal neurons are found to be in agreement with neurophysiological data, including the antagonistic role of horizontal cells in the outer plexiform layer. The examination of possible c-aminobutyric acid (GABA) action from horizontal cells suggests that GABA A alone, GABA B alone, or their weighted combination can generate the response characteristics observed in bipolar cells.

show abstract

“…The push-pull mechanism in Y-cells is far away from equilibrium and therefore signal summation is strongly nonlinear with different. dynamics than X-c:ells [3,4]. In LGN the different.…”

Section: Introductionmentioning

confidence: 99%

Brain Differently Changes its Algorithms in Parallel Processing of Visual Information

Przybyszewski

Pollen

2000

Intelligent Information Systems

Self Cite

View full text Add to dashboard Cite

Abstract. Feedback from the visual cortex (Vl) to the Lateral G(-miculate Nucleus (LGN) in macaque monkey increase contrast gain of LGN neurons for black and white (B&VV) and for color (C) stimuli. LGN parvocellular cells responses to B&\i\1 gratings are enhanced by feedback multiplicatively and in contrast independent manner. However, in magnocellular neurons corticofngal pathways enhance cells responses in a contrast~dependent non-linear manner. For C stimuli cortical feedback enhances parvocellular neurons responses in a very strong contrast-dependent manner. Ba...<;ed on these results [13] we propose a model which includes excitatory and inhibitory effects on cells activity (shunting equations) in retina and LGN while taking into account the anatomy of cortical feedback connections. The main mechanisms related to different algorithms of the data processing in the visual brain are differences in feedback properties from Vl to parvocellular (PC) and to magnocdlula.r (MC) neurons. Descending pathways from Vl change differently receptive field (RF) structur(~ of PC and MC cells. For B&W stimuli, in PC cells feedback changes gain similarly in the RF center and in the RF surround, leaving PC RF structure invariant. However, feedback influence ?viC cells in two ways: directly and throughLGN intcrneurons, which together changes gain and si,es of their RF center differently than gain and size of the RF surround. For C stimuli PC cells operate like M C cells for B& \'f...T. The first mechanism extracts from t.he stimulus an important features in a independent way from other stimulus parameters 1 whereas the second channel changes its tuning properties as a function of other stimulus attributes like contrast and/or spatial extension. The model suggests novel idea about the possible functional role of PC and MC pathways.

show abstract

Spatial asymmetries in cat retinal ganglion cell responses

Cited by 4 publications

References 23 publications

The Influence of Different Retinal Subcircuits on the Nonlinearity of Ganglion Cell Behavior

The Influence of Different Retinal Subcircuits on the Nonlinearity of Ganglion Cell Behavior

Neural computations in the tiger salamander and mudpuppy outer retinae and an analysis of GABA action from horizontal cells

Brain Differently Changes its Algorithms in Parallel Processing of Visual Information

Contact Info

Product

Resources

About