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Literature DB >> 4052498

Modelling the effects of a negative feedback circuit from horizontal cells to cones on the impulse responses of cones and horizontal cells in the catfish retina.

Abstract

A model of the cone-L-HC circuit for the catfish retina is presented with the following features: the outer segment consists of a compression factor and 7 low-pass filters in tandem; the cone pedicle consists of an internal negative feedback circuit in series with a low-pass filter; and the L-HC consists of a low-pass filter and forms a negative feedback circuit with the cone pedicle. By proper adjustment of the various time constants of the low-pass filters and the gain factors, the impulse responses for cones and L-HCs of the catfish retina (and turtle) can be duplicated. The negative feedback gain increases with increasing levels of mean illuminance which causes the monophasic impulse responses to become faster, biphasic and decrease in amplitude, i.e. in gain. This is an expression of the Weber-Fechner law.

Entities: Species

Mesh：

Year: 1985 PMID： 4052498 DOI： 10.1007/BF00355753

Source DB: PubMed Journal: Biol Cybern ISSN： 0340-1200 Impact factor: 2.086

22 in total

1. Dynamic characteristics of the receptive field of L-cells in the carp retina.

Authors: K Fukurotani; K I Hara; Y Oomura
Journal: Vision Res Date: 1975-12 Impact factor: 1.886

2. Nonlinear analysis and synthesis of receptive-field responses in the catfish retina. 3. Two-input white-noise analysis.

Authors: P Z Marmarelis; K I Naka
Journal: J Neurophysiol Date: 1973-07 Impact factor: 2.714

Modelling the effects of a negative feedback circuit from horizontal cells to cones on the impulse responses of cones and horizontal cells in the catfish retina.

1. Dynamic characteristics of the receptive field of L-cells in the carp retina.

2. Nonlinear analysis and synthesis of receptive-field responses in the catfish retina. 3. Two-input white-noise analysis.

3. Interactions leading to horizontal cell responses in the turtle retina.

4. Retinal light adaptation--evidence for a feedback mechanism.

5. A white-noise analysis of responses and receptive fields of catfish cones.

6. Adaptation in catfish retina.

7. Spatial organizations of catfish retinal neurons. II. Circular stimulus.

8. Modeling of the vertebrate visual system. I. Wiring diagram of the cone retina.

9. Effects of background and spatial pattern on incremental sensitivity of catfish horizontal cells.

10. Dynamics of turtle horizontal cell response.

1. Simulated bipolar cells in fovea of human retina. I. Computer simulation.

2. Differential encoding of spatial information among retinal on cone bipolar cells.

3. Dynamics of chromatic adaptation in cones of freshwater turtle.

4. Effects of electrical coupling on the cone-horizontal cell circuit in the catfish retina.

5. Dynamics of the cone-horizontal cell circuit in the turtle retina.

6. Dynamics of L-type bipolar and phasic amacrine cells in the vertebrate cone retina.

7. Dynamics of chromaticity horizontal cells in the freshwater turtle retina.

8. Distribution of mammalian-like melanopsin in cyclostome retinas exhibiting a different extent of visual functions.