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The Eye: I. Optics of Vision

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Title: The Eye: I. Optics of Vision


1
The Eye I. Optics of Vision
  • Faisal I. Mohammed , MD, PhD

2
Objectives
  • Describe the visual receptors
  • List the types of lenses and recognize how they
    work
  • Determine the power of lenses
  • Describe accommodation for near vision and far
    vision
  • Recognize nearsightedness and farsightedness and
    determine its correction
  • Describe visual acuity and its abnormalities
  • Determine intraocular pressure and glaucoma

3
Refractive Index
  • Speed of light in air 300,000 km/sec.
  • Light speed decreases when it passes through a
    transparent substance.
  • The refractive index is the ratio of the speed of
    light in air to the speed of light in the
    substance.
  • e.g., speed of light in substance 200,000
    km/sec, R.I. 300,000/200,000 1.5.

4
Refraction of Light
  • Bending of light rays by an angulated interface
    with different refractive indices.
  • The degree of refraction increases as the
    difference in R.I. increases and the degree of
    angulation increases.
  • The features of the eye have different R.I. and
    cause light rays to bend.
  • These light rays are eventually focused on the
    retina.

5
Light Refraction
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8
Refractive Principles of a Lens
  • Convex lens focuses light rays (converging lens)

9
Refractive Principles of a Lens
  • Concave lens diverges light rays (diverging lens)

10
Spherical Lens (Focal points)
Cylindrical Lens (Focal line)
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12
The Refractive Power of a Lens
Figure 49-8 Guyton and Hall
13
Focusing Power of the Eye
  • Most of the refractive power of the eye results
    from the surface of the cornea.
  • a diopter is a measure of the power of a lens
  • 1 diopter is the ability to focus parallel light
    rays at a distance of 1 meter, it is a measure of
    power of lenses
  • Diopter 1/ focal length in meters i.e the
    power of a lens with focal length 0.5 meter is 2
    (more convex)
  • the retina is considered to be 17 mm behind the
    refractive center of the eye
  • therefore, the eye has a total refractive power
    of 59 diopters (1000/17)

14
Image formation on the retina-requirements
  • Light refraction or bending the light by the
    refractive media Cornea, Aqueous humor, Lens
    and Vitreous humor
  • Accommodation An increase in the curvature of
    the lens for near vision,
  • The near point of vision is the minimum distance
    from the eye an object can be clearly focused
    with maximum accommodation
  • Constriction (meiosis) and dilation (Mydriasis)
    of the pupil
  • Convergence and divergence of the eyes for
    binocular vision

15
Accommodation
  • Refractive power of the lens is 20 diopters.
  • Refractive power can be increased to 34 diopters
    by changing shape of the lens - making it fatter
    (more convex).
  • This is called accommodation.
  • Accommodation is necessary to focus the image on
    the retina.
  • Normal image on the retina is upside down.

16
Mechanism of Accommodation
  • A relaxed lens is almost spherical in shape.
  • Lens is held in place by suspensory ligament
    which under normal resting conditions causes the
    lens to be almost flat.
  • Contraction of an eye muscle attached to the
    ligament pulls the ligament forward and causes
    the lens to become fatter (more convex) which
    increases the refractive power of the lens.
  • Under control of the parasympathetic nervous
    system.

17
Mechanism of Accommodation
Contraction pulls ligament forward relaxing
tension on suspensory ligament making the lens
fatter
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20
Presbyopia The Inability to Accommodate
  • Caused by progressive denaturation of the
    proteins of the lens.
  • Makes the lens less elastic.
  • Begins about 40-50 years of age.

21
Errors of Refraction
Normal vision
22
Correction of Vision
Myopia corrected with concave lens
23
Errors of Refraction
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Other Errors of Vision
  • Astigmatism
  • unequal focusing of light rays due to an oblong
    shape of the cornea
  • Cataracts
  • cloudy or opaque area of the lens
  • caused by coagulation of lens proteins

26
Visual Acuity Test
The diameter of the cones in the fovea is ? 1.5
?m
27
Visual Acuity depends on the density of
receptors (primarily Cones)
  • 6/6
  • ability to see letters of a given size at 6
    meters
  • 6/12
  • what a normal person can see at 12 meters, this
    person must be at 6 meters to see.
  • 6/60
  • what a normal person can see at 60 meters, this
    person must be at 6 meters to see.

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29
Fluid System of the Eye
  • Intraocular fluid keeps the eyeball round and
    distended.
  • 2 fluid chambers
  • aqueous humor which is in front of the lens
  • freely flowing fluid
  • vitreous humor which is behind the lens
  • gelatinous mass with little flow of fluid

30
Formation and Flow of Fluid in the Eye
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Formation of Aqueous Humor
  • Produced by the ciliary processes of the ciliary
    body at a rate of 2-3 microliters/min.
  • Flows between the ligaments of the lens, through
    the pupil into the anterior chamber, goes between
    the cornea and the iris, through a meshwork of
    trabeculae to enter the canal of schlemm which
    empties into aqueous veins and then into
    extraocular veins.

33
Intraocular Pressure
  • Normally 15 mm Hg with a range of 12-20 mm Hg.
  • The level of pressure is determined by the
    resistance to outflow of aqueous humor in the
    canal of schlemm.
  • increase in intraocular pressure caused by an
    increase in resistance to outflow of aqueous
    humor through a network of trabeculae in the
    canal of schlemm (Glaucoma)
  • can cause blindness due to compression of the
    axons of the optic nerve

34
Thank You
35
The Eye II. Receptor and Neural Function of the
Retina
  • Faisal I. Mohammed, MD,PhD

36
Objectives
  • Describe visual receptors and characterize them
  • List the layers of the retina and its cellular
    makeup
  • Explain visual transduction mechanism
  • Outline light and dark adaptation
  • Describe vitamin A importance for vision
  • Explain color blindness

37
Retina
  • light sensitive portion of the eye
  • contains cones for day and color vision
  • contains rods for night vision
  • contains neural architecture
  • light must pass through the neural elements to
    strike the light sensitive rods and cones

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The Fovea
  • A small area at the center of the retina about 1
    sq millimeter
  • The center of this area, the central fovea,
    contains only cones
  • these cones have a special structure
  • aid in detecting detail
  • In the central fovea the neuronal cells and blood
    vessels are displaced to each side so that the
    light can strike the cones directly.
  • This is the area of greatest visual acuity

43
Rods, Cones and Ganglion Cells
  • Each retina has 100 million rods and 3 million
    cones and 1.6 million ganglion cells.
  • 60 rods and 2 cones for each ganglion cell
  • At the central fovea there are no rods and the
    ratio of cones to ganglion cells is 11.
  • May explain the high degree of visual acuity in
    the central retina

44
Rods Cones
  • lower sensitivity specialized for day vision
  • less photopigment
  • less amplification (less divergence 11 is more)
  • saturate with intense light
  • fast response, short integration time
  • more sensitive to direct axial rays
  • high sensitivity specialized for night vision
  • more photopigment
  • high amplification single photon detection
  • saturate in daylight
  • slow response, long integration time
  • more sensitive to scattered light

45
Rods Cones
  • low acuity highly convergent retinal pathways,
    not present in central fovea
  • achromatic one type of rod pigment
  • high acuity less convergent retinal pathways,
    concentrated in central fovea
  • trichromatic three types of cones, each with a
    different pigment that is sensitive to a
    different part of the visible spectrum, Red,
    Green and Blue

46
Structure of the Rods and Cones
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Pigment Layer of Retina
  • Pigment layer of the retina is very important
  • Contains the black pigment melanin
  • Prevents light reflection in the globe of the eye
  • Without the pigment there would be diffuse
    scattering of light rather than the normal
    contrast between dark and light.
  • This is what happens in albinos (genetic absence
    of melanocyte activity)
  • poor visual acuity because of the scattering of
    light

49
Photochemistry of Vision
  • Rods and cones contain chemicals that decompose
    on exposure to light.
  • This excites the nerve fibers leading from the
    eye.
  • The membranes of the outer-segment of the rods
    contain rhodopsin or visual purple.
  • Rhodopsin is a combination of a protein called
    scotopsin and a pigment, retinal (Vitamin A
    derivative)
  • The retinal is in the cis configuration.
  • Only the cis configuration can bind with
    scotopsin to form rhodopsin.

50
Light and Rhodopsin
  • When light is absorbed by rhodopsin it
    immediately begins to decompose.
  • Decomposition is the result of photoactivation of
    electrons in the retinal portion of rhodopsin
    which leads to a change from the cis form of the
    retinal to the trans form of the molecule.
  • Trans retinal has the same chemical structure but
    is a straight molecule rather than an angulated
    molecule.
  • This configuration does not fit with the binding
    site on the scotopsin and the retinal begins to
    split away.
  • In the process of splitting away a number of
    intermediary compounds are formed.

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52
Rhodopsin Cycle
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54
Mechanism for Light to Decrease Sodium Conductance
  • cGMP is responsible for keeping Na channel in
    the outer segment of the rods open.
  • Light activated rhodopsin (metarhodopsin II)
    activates a G-protein, transducin.
  • Transducin activates cGMP phosphodiesterase which
    destroys cGMP.
  • Rhodopsin kinase deactivates the activated
    rhodopsin (which began the cascade) and cGMP is
    regenerated re-opening the Na channels.

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The Dark Current
57
The Dark Current
When rhodopsin decomposes in response to light it
causes a hyperpolarization of the rod by
decreasing Na permeability of the outer segment.
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Rod Receptor Potential (Contd)
  • When rhodopsin decomposes it causes a
    hyperpolarization of the rod by decreasing Na
    permeability of the outer segment.
  • The Na pump in the inner segment keeps pumping
    Na out of the cell causing the membrane
    potential to become more negative
    (hyperpolarization).
  • The greater the amount of light the greater the
    electronegativity.

60
The Rod Receptor Potential
  • Normally about -40 mV
  • Normally the outer segment of the rod is very
    permeable to Na ions.
  • In the dark an inward current (the dark current)
    carried by the Na ions flows into the outer
    segment of the rod.
  • The current flows out of the cell, through the
    efflux of K, ions in the inner segment of the
    rod.

61
Duration and Sensitivity of the Receptor Potential
  • A single pulse of light causes activation of the
    rod receptor potential for more than a second.
  • In the cones these changes occur 4 times faster.
  • Receptor potential is proportional to the
    logarithm of the light intensity.
  • very important for discrimination of the light
    intensity

62
Role of Vitamin A
  • Vitamin A is the precursor of all-trans-retinal,
    the pigment portion of rhodopsin.
  • Lack of vitamin A causes a decrease in retinal.
  • This results in a decreased production of
    rhodopsin and a lower sensitivity of the retina
    to light or night blindness.

63
Dark and Light Adaptation
  • In light conditions most of the rhodopsin has
    been reduced to retinal so the level of
    photosensitive chemicals is low.
  • In dark conditions retinal is converted back to
    rhodopsin.
  • Therefore, the sensitivity of the retinal
    automatically adjusts to the light level.
  • Opening and closing of the pupil also contributes
    to adaptation because it can adjust the amount
    entering the eye.

64
Dark Adaptation and Rods and Cones
65
Importance of Dark and Light Adaptation
  • The detection of images on the retina is a
    function of discriminating between dark and light
    spots.
  • It is important that the sensitivity of the
    retina be adjusted to detect the dark and light
    spots on the image.
  • Enter the sun from a movie theater, even the dark
    spots appear bright leaving little contrast.
  • Enter darkness from light, the light spots are
    not light enough to register.

66
Dark Adaptation
  • Gradual increase in photoreceptor sensitivity
    when entering a dark room.
  • Maximal sensitivity reached in 20 min.
  • Increased amounts of visual pigments produced in
    the dark.
  • Increased pigment in cones produces slight dark
    adaptation in 1st 5 min.
  • Increased rhodopsin in rods produces greater
    increase in sensitivity.
  • 100,000-fold increase in light sensitivity in
    rods.

67
Color Vision
  • Color vision is the result of activation of
    cones.
  • 3 types of cones
  • blue cone
  • green cone
  • red cone
  • The pigment portion of the photosensitive
    molecule is the same as in the rods, the protein
    portion is different for the pigment molecule in
    each of the cones.
  • Makes each cone receptive to a particular
    wavelength
  • of light

68
Each Cone is Receptive to a Particular Wavelength
of Light
Rods
69
Color Blindness
  • lack of a particular type of cone
  • genetic disorder passed along on the X chromosome
  • occurs almost exclusively in males (blue color
    blindness is usually autosomal recessive gene but
    it is rare)
  • about 8 of women are color blindness carriers
  • most color blindness results from lack of the red
    or green cones
  • lack of a red cone, protanope.
  • lack of a green cone, deuteranope.

70
Color Blindness Charts
Normal read 74, Red-Green read it 21
Normal read it 42, Red blind read 2, Green blind
read it 4
71
Neural Organization of the Retina
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Signal Transmission in the Retina
  • Transmission of signals in the retina is by
    electrotonic conduction.
  • Allows graded response proportional to light
    intensity.
  • The only cells that have action potentials are
    ganglion cells and amacrine cells.
  • send signals all the way to the brain

74
Lateral Inhibition to Enhance Visual Contrast
  • horizontal cells connect laterally between the
    rods and cones and the bipolar cells
  • output of horizontal cells is always inhibitory
  • prevents the lateral spread of light excitation
    on the retina
  • have an excitatory center and an inhibitory
    surround
  • essential for transmitting contrast borders in
    the visual image

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Function of Amacrine Cells
  • About 30 different types
  • Some involved in the direct pathway from rods to
    bipolar to amacrine to ganglion cells
  • Some amacrine cells respond strongly to the onset
    of the visual signal, some to the extinguishment
    of the signal
  • Some respond to movement of the light signal
    across the retina
  • Amacrine cells are a type of interneuron that aid
    in the beginning of visual signal analysis.

77
Three Types of Ganglion Cells
  • W cells (40) receive most of their excitation
    from rod cells.
  • sensitive to directional movement in the visual
    field
  • X cells (55) small receptive field, discrete
    retinal locations, may be responsible for the
    transmission of the visual image itself, always
    receives input from at least one cone, may be
    responsible for color transmission.
  • Y cells (5) large receptive field respond to
    instantaneous changes in the visual field.

78
Excitation of Ganglion Cells
  • spontaneously active with continuous action
    potentials
  • visual signals are superimposed on this
    background
  • many excited by changes in light intensity
  • respond to contrast borders, this is the way the
    pattern of the scene is transmitted to the brain

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