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The visual system

The visual system. Ch 6. In general, our visual system represents the world:. Imperfectly Accurately Better than reality. Light. Photons – discrete particles of energy travel through space at 300,000 kilometers/sec (186,000 miles/sec) Waves of electromagnetic energy

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The visual system

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  1. The visual system Ch 6

  2. In general, our visual system represents the world: Imperfectly Accurately Better than reality

  3. Light • Photons – discrete particles of energy • travel through space at 300,000 kilometers/sec (186,000 miles/sec) • Waves of electromagnetic energy • 380 to 760 nanometers in length

  4. Electromagnetic spectrum nm = nanometer

  5. What other animals see… Honeybees can see Ultraviolet light Rattlesnakes can see infrared light

  6. Rats can see ultraviolet light

  7. Properties of light and perception In general: • Wavelength – color (hue) perception • Intensity – brightness perception • Saturation – purity perception

  8. Light enters the eye • through the pupil • size of the pupil is regulated by the iris • The lens focuses light on the retina Note: that the retinal image is upside down.

  9. Pupil size • Adjusted in response to changes in illumination, which is a tradeoff between: • Sensitivity – ability to detect the presence of dimly lit objects • Acuity – ability to see the details of objects • When illumination is high, pupils are constricted allowing a greater depth of focus of the image falling on the retina • When illumination is low, pupils dilate in response to low activation of receptors allowing more light to enter the eye but sacrificing acuity and depth of focus

  10. Ones to know Anatomy of the eye Ligament

  11. Accomodation • Process of adjusting the configuration of the lens to bring images into focus on the retina • Focus on a near object • ciliary muscles contract • putting less tension on the ligaments • allowing the lens to take its natural cylindrical shape • thus increasing its ability to refract (bend) light • Focus on a distant object • Ciliary muscles relax • Increasing tension on the ligaments • flattens the lens • thus decreasing its ability to refract (bend) light

  12. Binocular disparity • The difference in the positions of the same image on the two retinas • Is greater for close objects (eyes must converge or turn slightly inward) • The degree of binocular disparity enables the visual system to construct 3-D perception from two 2-D retinal images

  13. The retina • Composed of 5 layers of neurons • Receptors (photoreceptors) • 1 rod • 3 cones • Horizontal cells (2 subtypes) • Bipolar cells (10 subtypes) • Amacrine cells (25-30 subtypes) • Ganglion cells (10-15 subtypes)

  14. The cellular structure of the retina • Appears to be inside-out • Light passes through the 4 cell layers before reaching the receptors • After receptor activation, signals are transmitted back out to the ganglion cells whose axons project across inside surface of the retina, gathering at the optic disk where the optic nerve begins as the ganglion cell axons leave the eye.

  15. Two visual problems result from the inside out arrangement: • Incoming light is distorted as it passes through the cell layers • There is a blind spot (no receptors or cells) at the optic disk where the axons gather to exit the eye

  16. Solutions • The fovea is an area (0.33 cm diameter) in the center of the retina where there is a thinning of the retinal ganglion cell layer. • Less distortion of light • Specialized for high-acuity vision (seeing details) • Completion – the visual system uses information from receptors around the blind spot to fill in the gap in the retinal image.

  17. photopic and scotopic vision The two systems are “wired” differently • Cones – low degree of convergence (a single ganglion cell receives signals from a few cones). • Rods – high degree of convergence (a single ganglion cell receives signals from hundreds of rods).

  18. photopic and scotopic vision • Cones are concentrated in the fovea, which contains no rods. • Rods are concentrated 20 degrees from the fovea and in the nasal hemiretina (retina half of both eyes near the nose).

  19. Spectral sensitivity curve • In general, more intense light appears brighter. However, wavelength also has an effect on the perception of brightness. A graph of the relative brightness of lights of the same intensity but at different wavelengths is called a spectral sensitivity curve (see Pinel p. 138).

  20. Spectral sensitivity curves • There are two spectral sensitivity curves. • The photopic spectral sensitivity curve has a peak brightness at 555 nm (yellow-green) • The scotopic spectral sensitivity curve has a peak brightness at 507 nm (green-blue) • The Purkinje effect – walking through his garden, Purkinje noticed that his yellow and red flowers were brighter than the blues ones just before dusk; just a few minutes later the trend was reversed (blue flowers appeared as brighter greys).

  21. Transduction - Conversion of one form of energy to another. • Visual transduction – conversion of light to neural signals. • Rhodopsin – the red pigment in rods becomes bleached when exposed to light. • It is a G-protein-linked receptor that responds to light.

  22. Light activation of rods: Light bleaches rhodopsin molecules. cGMP is broken down, closing sodium channels Sodium ions cannot enter the rod resulting in hyperpolarization. Glutamate release is reduced Transduction of light by rods demonstrates that signals can be transmitted through neural systems by inhibition.

  23. From retina to primary visual cortex • Pathway: retina  lateral geniculate nucleus (LGN)  primary visual cortex • ~90% of axons of retinal ganglion cells make up this pathway • LGN channels • Parvocellular (P layers) run through top 4 layers of LGN – responsive to color and fine detail (input from cones) • Magnocellular (M layers) run through bottom 2 layers of LGN – responsive to movement (input from rods) • Most LGN neurons that project to primary visual cortex (V1, striate cortex) terminate in the lower part of cortical layer IV

  24. Is retinotopic – each level is organized like a map of the retina Temporal hemiretina does not cross Nasal hemiretina crosses Right visual fields of Both eyes Left visual fields of Both eyes Bottom of visual field to dorsal cortex Top of visual field to ventral cortex Note that 25% of V1 is dedicated to fovea

  25. Saccades • The eye continually scans the visual field and makes a series of brief fixations (3/sec) connected by quick eye movements called saccades. • The fixations are integrated to produce greater color and detail than the restricted foveal region can produce if it remained stationary • stabilized retinal images, projected from a contact lens that moves with the eye; image disappears in a few seconds.

  26. Brief fixations associated with saccades while a person views different pictures Making visual saccades to items of interest is a function of the superior colliculus

  27. Visual fields Hemi-retinas Optic chiasm LGN P layers M layers Optic radiations Striate (primary visual) cortex Retina-geniculate-striate pathways

  28. LGN

  29. Hubel and Wiesel

  30. Receptive fields • On-center cell • Off-center cell Both respond best to contrast

  31. Both types of cells respond best to contrast

  32. Simple cortical cells • Neurons from lower layer IV of striate cortex are exceptions compared to all other striate neurons, which are categorized as simple or complex: • Simple cells • Have “on” and “off” regions • Are monocular • Borders of “on” and “off” regions are straight lines rather than circles (rectangular receptive fields) • Respond best when it’s preferred straight edge is in a particular orientation and position

  33. Complex cortical cells • Are more numerous • Have rectangular receptive fields • Respond best to straight line stimuli in a specific orientation • Unresponsive to diffuse light • Differ from simple cells in 3 important ways: • Larger receptive fields • No “on-off” regions – responds best to a straight edge stimulus of a particular orientation swept across the receptive field (fires continuously) • Many complex cells are binocular (respond to stimulation of either eye and will respond more robustly to stimulation of both eyes simultaneously).

  34. 1 right eye 2 right eye 3 right eye 4 right eye 1 right eye 2 right eye 3 left eye 4 left eye Columnar organization of V1 Vertical electrode tract Horizontal electrode tract

  35. Hubel & Wiesel’smodel of the columnar organization of the primary visual cortex • Big block of tissue analyzes signals from one area of the visual field • Sub-blocks analyze signals from the left and right eyes • Slices of block prefer lines in a particular orientation

  36. Spatial-frequency theory Striate neurons respond even more robustly to sine-waves place at a particular angle compared to straight lines and edges

  37. Component theory of color vision • Three kinds of color receptors (cones) each with a different spectral sensitivity • Color of a particular stimulus is determined by the ratio of activity in the three kinds of receptors

  38. Opponent-process theory of color vision • Two different classes of cells in the visual system for encoding color • One class of cells signaled red by changing its activity in one direction and green by changing its activity in the opposite direction • Another class signaled blue and its complement, yellow.

  39. Which theory is correct? The Answer: both (and a third one) • Cones code color on a purely component basis (different photopigments maximally sensitive to low, medium and high wavelengths of light) • Opponent processing of color occurs at all other levels of the retina-geniculate-striate system

  40. Retinex theory of color vision • Color is determined by reflectance – the proportion of light of different wavelengths a surface reflects • Reflected light changes based on different illumination • The efficiency of light absorbed and reflected by a surface is constant. • The visual system compares the light reflected by adjacent surfaces in at least 3 different wavelength bands.

  41. Principles of sensory system organization Three different types of sensory cortex: • Primary sensory cortex – receives most of its input from thalamic relays • Secondary sensory cortex – receives most of its input from the primary sensory cortex of a system • Association cortex – receives input from more than one sensory system

  42. Hierarchical organization Damage to different parts of the system Receptors – total blindness Primary sensory cortex – blindsight (Grahm) Secondary sensory cortex - Dr. P, the man who mistook his wife for a hat Analysis Analysis Association Cortex Complex Specific Secondary Sensory Cortex Primary Sensory Cortex Thalamic Relay Nuclei Receptors Simple General

  43. Sensory system organization Former Model (1960s) Current Model Association Cortex AS AS AS AS Secondary Sensory Cortex SSC SSC SSC SSC SSC SSC Primary Sensory Cortex PSC PSC PSC TRN TRN Thalamic Relay Nuclei Receptors R (functionally homogeneous and serial) (functionally segregated and parallel)

  44. Two Visual Streams

  45. Two Visual streams: Two theories • ‘What’ versus ‘Where’ (Ungerleider & Mishkin, 1982) – kinds of information processed • Ventral pathway – perception of what an object is • Dorsal pathway – perception of where the object is located

  46. Two Visual streams: Two theories • ‘What’ versus ‘How’ (Milner & Goodale, 1993) – the use to which information is put. • Ventral pathway – conscious perception of objects • Dorsal pathway – direct behavioral interactions with objects

  47. Visual agnosia • Gnosis means “to know” • Visual agnosics can see stimuli but do not know what they are • Object agnosia • Color agnosia • Movement agnosia (akinetopsia) • Face agnosia (prosopagnosia)

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