Jove
Visualize
Contact Us
JoVE
x logofacebook logolinkedin logoyoutube logo
ABOUT JoVE
OverviewLeadershipBlogJoVE Help Center
AUTHORS
Publishing ProcessEditorial BoardScope & PoliciesPeer ReviewFAQSubmit
LIBRARIANS
TestimonialsSubscriptionsAccessResourcesLibrary Advisory BoardFAQ
RESEARCH
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchive
EDUCATION
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualFaculty Resource CenterFaculty Site
Terms & Conditions of Use
Privacy Policy
Policies

Related Concept Videos

The Retina01:32

The Retina

The retina is a layer of nervous tissue at the back of the eye that transduces light into neural signals. This process, called phototransduction, is carried out by rod and cone photoreceptor cells in the back of the retina.
Anatomy of the Eyeball01:20

Anatomy of the Eyeball

The eye is a spherical, hollow structure composed of three tissue layers. The outer layer — the fibrous tunic, comprises the sclera — a white structure — and the cornea, which is transparent. The sclera encompasses some of the ocular surface, most of which is not visible. However, the 'white of the eye' is distinctively visible in humans compared to other species. The cornea, a clear covering at the front of the eye, enables light penetration. The eye's middle layer, the vascular tunic,...
Vision01:24

Vision

Vision is the result of light being detected and transduced into neural signals by the retina of the eye. This information is then further analyzed and interpreted by the brain. First, light enters the front of the eye and is focused by the cornea and lens onto the retina—a thin sheet of neural tissue lining the back of the eye. Because of refraction through the convex lens of the eye, images are projected onto the retina upside-down and reversed.
Photoreceptors and Visual Pathways01:22

Photoreceptors and Visual Pathways

At the molecular level, visual signals trigger transformations in photopigment molecules, resulting in changes in the photoreceptor cell's membrane potential. The photon's energy level is denoted by its wavelength, with each specific wavelength of visible light associated with a distinct color. The spectral range of visible light, classified as electromagnetic radiation, spans from 380 to 720 nm. Electromagnetic radiation wavelengths exceeding 720 nm fall under the infrared category, whereas...
Parallel Processing01:20

Parallel Processing

The brain processes sensory information rapidly due to parallel processing, which involves sending data across multiple neural pathways at the same time. This method allows the brain to manage various sensory qualities, such as shapes, colors, movements, and locations, all concurrently. For instance, when observing a forest landscape, the brain simultaneously processes the movement of leaves, the shapes of trees, the depth between them, and the various shades of green. This enables a quick and...
Color Vision01:24

Color Vision

Color perception begins in the retina, the light-sensitive layer at the back of the eye. Two main theories explain how colors are seen: the trichromatic theory and the opponent-process theory. The trichromatic theory, proposed by Thomas Young in 1802 and extended by Hermann von Helmholtz in 1852, suggests that color vision is based on three types of cone receptors in the retina. These cones are sensitive to different but overlapping ranges of wavelengths corresponding to red, blue, and green.

You might also read

Related Articles

Articles linked to this work by shared authors, journal, and citation graph.

Sort by
Same author

Signals for color and achromatic contrast in the goldfish inner retina.

Visual neuroscience·2014
Same author

Zebrafish inner retina: local signals for spatial position, luminance, and color contrast.

Visual neuroscience·2012
Same author

Center/surround organization of retinal bipolar cells: High correlation of fundamental responses of center and surround to sinusoidal contrasts.

Visual neuroscience·2011
Same author

Introducing Robert F. Miller, the 2008 recipient of the Proctor Medal.

Investigative ophthalmology & visual science·2008
Same author

Retinal bipolar cells: temporal filtering of signals from cone photoreceptors.

Visual neuroscience·2007
Same author

Natural images and contrast encoding in bipolar cells in the retina of the land- and aquatic-phase tiger salamander.

Visual neuroscience·2006
Same journal

Support for the efficient coding account of visual discomfort.

Visual neuroscience·2024
Same journal

Visual Field Asymmetries in Responses to ON and OFF Pathway Biasing Stimuli.

Visual neuroscience·2024
Same journal

Pattern reversal chromatic VEPs like onsets, are unaffected by attentional demand.

Visual neuroscience·2024
Same journal

The interaction between luminance polarity grouping and symmetry axes on the ERP responses to symmetry.

Visual neuroscience·2024
Same journal

Electroretinographic responses to periodic stimuli in primates and the relevance for visual perception and for clinical studies.

Visual neuroscience·2024
Same journal

Synaptotagmin-9 in mouse retina.

Visual neuroscience·2024
See all related articles

Related Experiment Video

Updated: Jun 6, 2026

Simultaneous Whole-cell Recordings from Photoreceptors and Second-order Neurons in an Amphibian Retinal Slice Preparation
11:39

Simultaneous Whole-cell Recordings from Photoreceptors and Second-order Neurons in an Amphibian Retinal Slice Preparation

Published on: June 1, 2013

Contrast processing by ON and OFF bipolar cells.

Dwight A Burkhardt1

  • 1Department of Psychology, University of Minnesota, Minneapolis, Minnesota 55455, USA. burkh001@umn.edu

Visual Neuroscience
|November 25, 2010
PubMed
Summary
This summary is machine-generated.

This study reveals that retinal bipolar cells exhibit similar contrast processing for ON and OFF pathways, challenging previous views. These cells demonstrate nonlinear responses and efficient coding of natural image contrasts.

More Related Videos

Recording Light-evoked Postsynaptic Responses in Neurons in Dark-adapted, Mouse Retinal Slice Preparations Using Patch Clamp Techniques
10:30

Recording Light-evoked Postsynaptic Responses in Neurons in Dark-adapted, Mouse Retinal Slice Preparations Using Patch Clamp Techniques

Published on: February 11, 2015

Split Retina as an Improved Flatmount Preparation for Studying Inner Nuclear Layer Neurons in Vertebrate Retina
07:53

Split Retina as an Improved Flatmount Preparation for Studying Inner Nuclear Layer Neurons in Vertebrate Retina

Published on: January 16, 2024

Related Experiment Videos

Last Updated: Jun 6, 2026

Simultaneous Whole-cell Recordings from Photoreceptors and Second-order Neurons in an Amphibian Retinal Slice Preparation
11:39

Simultaneous Whole-cell Recordings from Photoreceptors and Second-order Neurons in an Amphibian Retinal Slice Preparation

Published on: June 1, 2013

Recording Light-evoked Postsynaptic Responses in Neurons in Dark-adapted, Mouse Retinal Slice Preparations Using Patch Clamp Techniques
10:30

Recording Light-evoked Postsynaptic Responses in Neurons in Dark-adapted, Mouse Retinal Slice Preparations Using Patch Clamp Techniques

Published on: February 11, 2015

Split Retina as an Improved Flatmount Preparation for Studying Inner Nuclear Layer Neurons in Vertebrate Retina
07:53

Split Retina as an Improved Flatmount Preparation for Studying Inner Nuclear Layer Neurons in Vertebrate Retina

Published on: January 16, 2024

Area of Science:

  • Neuroscience
  • Vision Science
  • Retinal Physiology

Background:

  • Current understanding of retinal bipolar cells relies on rod-dominant, dark-adapted flash responses in isolated retinas.
  • Limited quantitative data exists on contrast processing in intact, light-adapted retinas.

Purpose of the Study:

  • To summarize quantitative findings on contrast processing in cone-driven bipolar cells in the intact light-adapted retina.
  • To investigate the similarities and differences in contrast responses between ON and OFF bipolar cells.
  • To characterize the nonlinearities, dynamic range, and receptive field organization of bipolar cells.

Main Methods:

  • Intracellular recordings from over 400 cone-driven bipolar cells in the tiger salamander.
  • Analysis of contrast responses in light-adapted conditions.
  • Comparison of ON and OFF bipolar cell populations.

Main Results:

  • ON and OFF bipolar cells show surprisingly similar contrast responses, questioning their selective roles in positive/negative contrast processing.
  • Responses are highly nonlinear, with high gain for small contrasts and saturation at higher contrasts.
  • Bipolar cells exhibit efficient coding for natural image contrasts, with diverse response properties and dynamic ranges matching natural scenes.
  • Receptive fields display symmetry between center and surround for same-polarity responses.
  • A 30 ms latency difference exists between ON and OFF cells, potentially due to G-protein cascades.
  • At least 11 signal transformations occur between cone and bipolar cell voltage responses.

Conclusions:

  • The functional distinction between ON and OFF pathways for contrast processing may need refinement.
  • Retinal bipolar cells are highly adapted for efficient and nonlinear processing of visual information in natural environments.
  • Significant signal transformations occur within the inner retina, highlighting the complexity of visual processing.