Visual Physiology Notes (3) PDF 1-8

Summary

These notes provide a thorough explanation of how the eye works with diagrams. They explore light refraction, accommodation, and the cascade of phototransduction. Ideal for learning about visual processes.

Full Transcript

THE EYE: VISION
Vision is the process by which light is reflected from objects within our environment. Vision is
translated by three steps including (1) the need for light to enter the eye and be focused on the retina by
the lens, (2) the ability of photoreceptors cells within the retina to transduce the signal into an electrical
signal, and (3) the processing of the electrical signal by neural pathways.

The eye is protected by a bony orbit and is innervated by six eye muscles controlled by the cranial
nerves III (oculomotor), IV (trochlear), and VI (abducens). The external eye also consists of both an upper
and lower eyelid, along with a lacrimal gland. The lacrimal gland produces tears via innervation by
cranial nerve VII (facial).

The eye is a hollow structure that is composed of two fluid filled compartments that are separated
by the lens structure. The external most compartment is filled with a substance called aqueous humor,
which is a plasma-like fluid generated by ciliary epithelium. The posterior chamber (behind the lens) is
called the vitreous chamber and holds the vitreous body. This is a clear and gelatinous matrix that
maintains the shape of the eyeball.

The eyeball is covered by sclera connective tissue, under which the retinal layer lies. The inner
vitreous chamber is also infiltrated with blood vessels by entry and exit through the optic disc, and an
optic nerve. Other features of the eye include the pupil which can change in diameter in response to
changes in light, the cornea which is a transparent disc of tissue that is continuous with the sclera and the
ciliary muscles. Nerves (optic nerve) exit through the optic disc.

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Light first enters the cornea (transparent disc continuous with the sclera) and passes through the
aqueous humor. From here light must pass through the pupil and lens and then ultimately focus on the
retina, a layer within the internal eye that is light sensitive and contains photoreceptors that are capable
are converting light into electrical signals. Light entering the eye is modified in two distinct ways. The
first being by the amount of light that is allowed to enter, a result of pupil size. The second being how the
light is focused and the changes to lens shape. For the purpose of this question, let us focus only on the
pupil.

From physics you should recall that light passing through any medium that isn’t uniform tends to
bend in different directions. For example, think of light entering a prism and being sent out the opposite
side at a different angle than how it entered. Refraction is encountered within the visual system at two
points. The cornea is responsible for some degree of refraction, while the lens is the other structure
capable of bending light rays. Because the shape of the cornea cannot easily be adjusted, for the purposes
of refraction we will address the lens only. This is because the lens has the ability to modify its shape
through the existence of accessory elastic elements and muscles.

Refraction, the degree at which light will bend, is influenced by two factors. These are the result of
the change in medium the light is entering into (e.g., from air to fluid) and also the angle at which the light
rays approach the surface they are attempting to pass through. Parallel light rays passing through a
uniform rectangular lens will remain parallel and exit similarly on the opposite side. Meanwhile, a
concave lens will take parallel light rays and scatter them upon exiting. A convex lens does the opposite
and modifies parallel light rays entering the lens so that they converge towards a common point, referred
to as a focal point.

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Parallel light rays that are coming from a far distance (usually greater than 20 feet) pass through a
convex lens to converge onto a focal point. However, the focal point exists in the back-center of the retina
and to make it possible for the proper focal point placement (and focal length), the lens of the eye has to
be adjusted in shape. For far distances, the lens will flatten so that the focal point falls on the retina.
For closer objects (less than 20 feet), parallel rays also pass through our convex lens. However, the
convergence from this close distance provides a focal point that would extend beyond the retina.
Therefore, the lens shape has to be modified so that it is more rounded (shortening the focal length),
allowing the focal point to fall directly on the back of the retina.

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Lens shape is modified through the action of both the ciliary muscle and the zonule (ligaments
attaching the lens to the ciliary muscle). The process of changing lens shape is referred to as
accommodation. Under normal circumstances the lens appears normal. However, when it is necessary to
flattened the lens (as it may be to view distant objects), the ciliary muscles relax while the zonules gain
tone. On the other hand, to change the lens to a more rounded shape, the ciliary muscles must contract
while allowing the zonules to slacken.

Accommodation is an ability that declines with age leading to presbyopia in older individuals,
requiring the use of reading glasses to see close objects.

Visual deficits: Hyperopia is far-sightedness and results from when the focal point falls behind the
retina. Myopia is near-sightedness and results from when the focal point falls in front of the retina. These
can be corrected for with convex and concave lenses, respectively.

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Phototransduction: This occurs within the retina, which is the sensory organ of the eye. The retina,
however, only senses as small fraction of total light (within the wavelengths of 400 nm to 750 nm).
Photoreceptors on the retina are responsible for the transduction of the light stimulus into a change in
membrane potential.

Retinal cells are arranged in the opposite order than what one might expect. You may expect the
retinal cells to be the first exposed to light rays, however, light must act through a number of other cells
in order to reach photoreceptors. For example, the cells that sit between the light stimulus and the
photoreceptor cells include ganglion, bipolar, amacrine, and horizontal cells. In the fovea, however,
photoreceptors have direct access to light and therefore reflect an area of the retina with the most visual
acuity.

Convergence is observed within the retina. For example, many photoreceptor cells (15-45)
synapse onto one bipolar neuron. Bipolar neurons further converge onto ganglion cells. The axons of
these ganglion cells form the optic nerve and exit the eye through the optic disc (the area of the eye
where we experience a blind-spot). In the fovea, however, there is no convergence. Instead, there is a 1:1
ratio of photoreceptor cells to bipolar cells. Cell types including horizontal and amacrine cells enhance
the signal processing that occurs between bipolar and ganglion cells.

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Photoreceptors transduce light into electrical signals and come in the form of rods and cones. The
ratio of rods to cones is 20:1 except for in the fovea where only cones are present. This high density of
cones in the fovea allows it to provide an enhanced visual acuity (sharpness). Rods function in low light
and are best suited for nighttime vision, while cones are responsible for color vision and the sharpness
(acuity) of our vision. Both of these, though, have the same basic structure. They consist of an outer,
inner, and base segment which each have different functions in phototransduction. The outer segment is
the tip of the photoreceptor cell and is embedded into the pigment membrane. The pigment membrane
absorbs extraneous light that isn’t absorbed by the photoreceptors, preventing an interference in visual
processing. The outer segment also consists of a series of stacked discs in which the visual pigments are
located. The inner segment of the photoreceptor cell is where the organelles associated with the
production of ATP and photopigments are located. These, therefore, have increased numbers of
mitochondria. The base segment of the photoreceptor cell is where the photoreceptor synapses onto the
bipolar neurons.

Visual pigments within the outer disk segments of the photoreceptor cells are responsible for
transducing light into changes in membrane potential. The visual pigment for rod cells is rhodopsin,
while cones have three pigments that are similar in structure and function to rhodopsin but respond to
different color wavelengths. These colors are red, green, and blue. We recognize color by the wavelengths
that excite specific cone receptors (e.g., green grass is transmitted by green wavelengths). Combinations
or fusions of colors are interpreted by the brain as a mix of signals that come from the three different
cone pigments. The distribution of rods and cones across the retinal epithelium are provided below.
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Cascade of phototransduction in rods: In rods, rhodopsin is a molecule that becomes activated in
response to light. First though, you need to understand that opsin is part of the molecule that is a protein
and is embedded within the discs of the outer segment of the rod and retinal is a vitamin A derivative that
absorbs light. In the absence of light retinal is bound to opsin. In the presence of light, retinal dissociates
from opsin, a processed called bleaching.

Photoreceptor cells express potassium channels that move potassium out of the cell. In the
absence of light when rhodopsin is inactive, there is an accumulation of cyclic GMP (cGMP) that allows
cation channels to allow sodium entry into the cell. This offsets the potassium leak and results in a
slightly depolarized potential (-40 mV). The depolarized photoreceptor will release of neurotransmitter
(glutamate) onto bipolar cells.

When light activates rhodopsin, the opsin molecule interacts with transducin protein. Transducin
leads to reductions in cGMP by activating a phosphodiesterase. This ultimately closes cation channels
responsible for sodium and calcium influx, but the potassium efflux still remains. The final result is a
hyperpolarized cell with a membrane potential of around -70 mV. This hyperpolarized potential results
in a reduction of neurotransmitter release onto bipolar neurons.

It is important to recognize, however, that these are not all or none processes. Responses can be
graded by the intensity of light received by the photoreceptor cells. Also important to recognize is the
necessity of these photoreceptors to recover from bleaching. In this way, retinal must be converted back
to its inactive form to recombine with opsin. This presents a time delay for the receptors to adjust and is
best exemplified by what occurs when you walk into a dark room from a bright sunny day…..you can’t see
a thing and it takes a moment to adjust.

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Signal processing occurs in the bipolar cells following the release of glutamate onto them by
photoreceptor cells. These bipolar cells have two distinct responses. The first response is considered the
light-on response where the bipolar neuron is inhibited by glutamate release in the dark and activated by
release in the light. In light-off bipolar cells, excitation occurs by glutamate release in the dark while the
cell is inhibited by this release in the light. This is an example of how one stimulus creates two different
responses. Bipolar neurons can either excite or inhibit ganglion cells.
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Ganglion cell bodies from the retina extend into axons that collectively make up the optic nerve.
The optic nerves of each eye cross at the optic chiasm; however, they also pass along information to each
side of the brain that represents each eye. From the optic chiasm visual information is sent to the lateral
geniculate body of the thalamus and then to the visual cortex, where orientation and mapping within the
retina are conserved.

Visual information from the lateral geniculate nucleus is also sent to the pretectum (specifically
the Edinger Westphal nucleus), a region of the brain responsible for constricting the pupils in response to
light. This information leaves thenuclei via the parasympathetic fibers of the oculomotor nerve (CNIII) to
reduce the amount of light entering BOTH eyes. This is referred to as the pupillary reflex.

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