Dynamics of turtle horizontal cell response

The small- and large-field (cone) horizontal cells produce similar dynamic responses to a stimulus whose mean luminance is modulated by a white-noise signal. Nonlinear components increase with an increase in the mean luminance and may produce a mean square error (MSE) of up to 15%. Increases in the mean luminance of the field stimulus bring about three major changes: the incremental sensitivity defined by the amplitude of the kernels decreases in a Weber-Fechner fashion; the waveforms of the kernels are transformed from monophasic (integrating) to biphasic (differentiating); the peak response time of the kernels becomes shorter and the cells respond to much higher-frequency inputs. The dynamics of the horizontal cell response also depend on the area of the retina stimulated. Smaller spots of light produce monophasic kernels of a longer peak response time. The presence of a steady background produces three major changes in the spot kernels: the kernel's amplitude becomes larger (incremental sensitivity increases); the peak response times become shorter; the waveform of the kernels changes in a fashion similar to that observed with an increase in the mean luminance of the field stimulus. A similar enhancement in the incremental sensitivity by a steady background has also been observed in catfish, which shows that this phenomenon is a common feature of the horizontal cells in the lower vertebrate retina.

• Publication year

  1985

• Venue

  The Journal of General Physiology

• Publication date

  1985-09-01

• Fields of study

  Biology, Medicine, Physics

• Identifiers
  DOI 10.1085/JGP.86.3.423PMID 4056733PMCID 2228800
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• No claims are published for this paper.

• No concepts are published for this paper.

• Signal transmission in the catfish retina. I. Transmission in the outer retina.

  1985influential reference
• Retinal light adaptation—evidence for a feedback mechanism

  1984cited by this paper
• Effects of background and spatial pattern on incremental sensitivity of catfish horizontal cells.

  1984cited by this paper
• Spatial and temporal properties of luminosity horizontal cells in the turtle retina

  1983cited by this paper
• gamma-Aminobutyric acid antagonists decrease junctional communication between L-horizontal cells of the retina.

  1982cited by this paper
• Center-surround antagonistic organization in small-field luminosity horizontal cells of turtle retina.

  1981cited by this paper
• Linear information processing in the retina: a study of horizontal cell responses.

  1981cited by this paper
• Sustained feedback effects of L-horizontal cells on turtle cones

  1980cited by this paper
• Spatial organization of catfish retinal neurons. I. Single- and random-bar stimulation.

  1980influential reference
• Adaptation in catfish retina.

  1979cited by this paper
• gamma-Aminobutyric acid: a neurotransmitter candidate for cone horizontal cells of the catfish retina.

  1978cited by this paper
• Horizontal cells of the turtle retina. I. Light microscopy of golgi preparations

  1978cited by this paper
• The response of cat horizontal cells to flicker stimuli of different area, intensity and frequency

  1977cited by this paper
• Morphological and functional identifications of catfish retinal neurons. III. Functional identification.

  1975cited by this paper
• Sensitization and centre‐surround antagonism in Necturus retina

  1974cited by this paper
• C- and L-type horizontal cells in the turtle retina.

  1974cited by this paper
• Detection and resolution of visual stimuli by turtle photoreceptors

  1973cited by this paper
• Nonlinear analysis and synthesis of receptive-field responses in the catfish retina. 3. Two-input white-noise analysis.

  1973cited by this paper
• Colour‐dependence of cone responses in the turtle retina

  1973cited by this paper
• Two types of luminosity horizontal cells in the retina of the turtle

  1973cited by this paper
• Inactivation of Horizontal Cells in Turtle Retina by Glutamate and Aspartate

  1972influential reference
• White-Noise Analysis of a Neuron Chain: An Application of the Wiener Theory

  1972cited by this paper
• Theory of flicker and transient responses. I. Uniform fields.

  1971cited by this paper
• Factors influencing the time course of S‐potentials resulting from brief flashes

  1969cited by this paper
• The generation and spread of S‐potentials in fish (Cyprinidae)

  1967cited by this paper
• S‐potentials from colour units in the retina of fish (Cyprinidae)

  1966cited by this paper
• The Ferrier Lecture, 1962 Visual adaptation

  1965cited by this paper
• VISUAL ADAPTATION.

  1965cited by this paper
• Increment thresholds at low intensities considered as signal/noise discriminations

  1957cited by this paper
• The sensitivity performance of the human eye on an absolute scale.

  1948cited by this paper

• A dark decrement for enhanced dynamic sensitivity of retinal photoreceptors.

  2020cites this paper
• Functional properties of spontaneous excitatory currents and encoding of light/dark transitions in horizontal cells of the mouse retina

  2015cites this paper
• the Cone/Horizontal Cell Synapse in Goldfish Retina The Open- and Closed-Loop Gain-Characteristics of

  2015cites this paper
• A spectral model for signal elements isolated from zebrafish photopic electroretinogram

  2009cites this paper
• Linear and nonlinear systems analysis of the visual system: why does it seem so linear? A review dedicated to the memory of Henk Spekreijse.

  2009cites this paper
• Generation and transformation of second-order nonlinearity in catfish retina

  2006cites this paper
• Model of the cone-horizontal cell circuit in the catfish retina

  2004cites this paper
• Retinal information processing and ambient illumination.

  2001cites this paper
• Endogenous zinc as a neuromodulator in vertebrate retina: evidence from the retinal slice.

  2001cites this paper
• The open- and closed-loop gain-characteristics of the cone/horizontal cell synapse in goldfish retina.

  2000cites this paper
• Spectral and dynamic properties of cone/horizontal cell interaction in goldfish retina

  2000cites this paper
• The Open- and Closed-Loop Gain-Characteristics of the Cone/Horizontal Cell Synapse in Goldfish Retina

  2000cites this paper
• Temporal aspects of neural coding in the retina and lateral geniculate.

  1999cites this paper
• Spatio‐temporal receptive fields in carp retinal horizontal cells

  1998cites this paper
• Processing of color- and noncolor-coded signals in the gourami retina. II. Amacrine cells.

  1997cites this paper
• Processing of color- and noncolor-coded signals in the gourami retina. I. Horizontal cells.

  1997influential citation
• Processing of color- and noncolor-coded signals in the gourami retina. III. Ganglion cells.

  1997cites this paper
• Gain control of synaptic transfer from second- to third-order neurons of cockroach ocelli

  1996cites this paper
• Contrast gain control in the lower vertebrate retinas [published erratum appears in J Gen Physiol 1995 Aug;106(2):following 388]

  1995cites this paper
• Background contrast modulates kinetics and lateral spread of responses to superimposed stimuli in outer retina

  1995cites this paper
• Information Processing in the Insect Ocellar System: Comparative Approaches t o the Evolution of Visual Processing and Neural Circuits a a This chapter is dedicated to Prof. Hideki Tateda, Shimonoseki City University, Japan.

  1995cites this paper
• Modulation of synaptic transfer between retinal cones and horizontal cells by spatial contrast

  1994influential citation
• White noise analysis of a chromatic type horizontal cell in the Xenopus retina

  1994influential citation
• White-noise analysis in the neuron network of the vertebrate retina

  1993cites this paper
• Equivalent Sine Wave Frequency for Interpretation of Responses to Frequency-Swept Sinusoids Defined: an Algorithm From Studies in Skate Ganglion Cells.

  1993cites this paper
• Response dynamics and directional properties of nonspiking local interneurons in the cockroach cercal system

  1993cites this paper
• Response Dynamics and Directional Properties Interneurons in the Cockroach Cereal System

  1993cites this paper
• Membrane currents of horizontal cells isolated from turtle retina.

  1992cites this paper
• Sensitivity transformation for vertebrate vision

  1991cites this paper
• Light adaptation in turtle cones. Testing and analysis of a model for phototransduction.

  1991cites this paper
• White noise analysis of graded response in a wind-sensitive, nonspiking interneuron of the cockroach

  1991cites this paper
• Effects of synaptic blocking agents on the depolarizing responses of turtle cones evoked by surround illumination

  1990cites this paper
• Light adaptation in the primate retina: Analysis of changes in gain and dynamics of monkey retinal ganglion cells

  1990cites this paper
• Interpretation Of Wiener Kernels

  1990cites this paper
• Background-induced flicker enhancement in cat retinal horizontal cells. I. Temporal and spectral properties.

  1990cites this paper
• Nonlinear signal transmission between second- and third-order neurons of cockroach ocelli

  1990cites this paper
• Background-induced flicker enhancement in cat retinal horizontal cells. II. Spatial properties.

  1990cites this paper
• Physiological and pharmacological analysis of suppressive rod-cone interaction in Necturus retina [corrected].

  1989cites this paper
• Analysis of vertebrate eye movements following intravitreal drug injections. III. Spontaneous nystagmus is modulated by the GABAa receptor.

  1989cites this paper
• Dynamics of Second-Order Neurons of Cockroach Ocelli

  1989cites this paper
• Chapter 6 Neuron network in catfish retina: 1968–1987

  1988cites this paper
• Light adaptation in the turtle retina: embedding a parametric family of linear models in a single nonlinear model

  1988cites this paper
• White-noise analysis in visual neuroscience

  1988cites this paper
• Dissection of the neuron network in the catfish inner retina. II. Interactions between ganglion cells.

  1988cites this paper
• Dynamics of skate horizontal cells

  1988influential citation
• The cellular basis for suppressive rod–cone interaction

  1988cites this paper
• Dynamic relationship between the slow potential and spikes in cockroach ocellar neurons

  1988cites this paper
• Dynamics of the ganglion cell response in the catfish and frog retinas

  1987influential citation
• Dynamics of turtle cones

  1987cites this paper
• Signal transmission in the catfish retina. V. Sensitivity and circuit.

  1987cites this paper
• Nonlinear analysis: mathematical theory and biological applications.

  1986cites this paper
• White-noise analysis in retinal physiology.

  1986cites this paper
• Dynamics of cockroach ocellar neurons

  1986influential citation
• 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

  1985cites this paper
• Field adaptation in the horizontal cells. Rushtonian transformation.

  1985cites this paper
• Visual sensitivity and Wiener kernels.

  1985cites this paper