Guyton and Hall Physiology Chapter 50 - The Eye I. PDF

Summary

This document details the physical principles of optics, focusing on light refraction and the optical system of the human eye. It explores the concepts of refractive indices, lenses (convex and concave), and how they work to form images.

Full Transcript

CHAPTER 50

UNIT X
The Eye: I. Optics of Vision

PHYSICAL PRINCIPLES OF OPTICS ratio of the two refractive indices of the two transparent
media; and (2) the degree of angulation between the inter-
Understanding the optical system of the eye requires face and the entering wave front.
familiarity with the basic principles of optics, including
such factors as the physics of light refraction, focusing, Application of Refractive Principles to Lenses
and depth of focus. A brief review of these physical prin- Convex Lens Focuses Light Rays. Figure 50-2 shows
ciples is presented in this chapter, followed by discussion parallel light rays entering a convex lens. The light rays
of the optics of the eye. passing through the center of the lens strike the lens ex-
actly perpendicular to the lens surface and, therefore, pass
Refraction of Light through the lens without being refracted. Toward either
edge of the lens, however, the light rays strike a progres-
Refractive Index of a Transparent Substance. Light rays sively more angulated interface. The outer rays bend more
travel through air at a velocity of about 300,000 km/sec, but and more toward the center, which is called convergence of
they travel much slower through transparent solids and liq-
uids. The refractive index of a transparent substance is the
A
ratio of the velocity of light in air to the velocity in the sub-
stance. The refractive index of air is 1.00. Thus, if light trav-
els through a particular type of glass at a velocity of 200,000
km/sec, the refractive index of this glass is 300,000 divided
by 200,000, or 1.50.
Refraction of Light Rays at an Interface Between Two
Media With Different Refractive Indices. When light rays Wave fronts Glass
traveling forward in a beam (as shown in Figure 50-1A) B
strike an interface that is perpendicular to the beam, the
rays enter the second medium without deviating from their
course. The only effect that occurs is decreased velocity of
transmission and shorter wavelength, as shown in the fig-
ure by the shorter distances between wave fronts.
If the light rays pass through an angulated interface, as
shown in Figure 50-1B, the rays bend if the refractive in- Figure 50-1. Light rays entering a glass surface perpendicular to the
dices of the two media are different from each other. In this light rays (A) and a glass surface angulated to the light rays (B). This
figure, the light rays are leaving air, which has a refractive in- figure demonstrates that the distance between waves after they en-
dex of 1.00, and are entering a block of glass having a refrac- ter the glass is shortened to about two-thirds that in air. It also shows
tive index of 1.50. When the beam first strikes the angulated that light rays striking an angulated glass surface are bent.
interface, the lower edge of the beam enters the glass ahead
of the upper edge. The wave front in the upper portion of
the beam continues to travel at a velocity of 300,000 km/sec,
whereas that which entered the glass travels at a velocity of
200,000 km/sec. This difference in velocity causes the upper
portion of the wave front to move ahead of the lower portion
so that the wave front is no longer vertical but is angulated
to the right. Because the direction in which light travels is al-
ways perpendicular to the plane of the wave front, the direc-
tion of travel of the light beam bends downward. Light from
Focal length
This bending of light rays at an angulated interface is distant source
known as refraction. Note particularly that the degree of Figure 50-2. Bending of light rays at each surface of a convex spheri-
refraction increases as a function of the following: (1) the cal lens showing that parallel light rays are focused to a focal point.

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UNIT X The Nervous System: B. The Special Senses

A

Light from
distant source

Figure 50-3. Bending of light rays at each surface of a concave
spherical lens showing that parallel light rays are diverged.

the rays. Half the bending occurs when the rays enter the B
lens, and half occurs as the rays exit from the opposite side.
If the lens has exactly the proper curvature, parallel light
rays passing through each part of the lens will be bent ex-
actly enough so that all the rays will pass through a single
point, called the focal point.
Concave Lens Diverges Light Rays. Figure 50-3 shows
the effect of a concave lens on parallel light rays. The rays
that enter the center of the lens strike an interface that is
perpendicular to the beam and, therefore, do not refract.
The rays at the edge of the lens enter the lens ahead of the
rays in the center. This effect is opposite to the effect in
Figure 50-4. A, Point focus of parallel light rays by a spherical con-
the convex lens, and it causes the peripheral light rays to vex lens. B, Line focus of parallel light rays by a cylindrical convex lens.
diverge from the light rays that pass through the center of
the lens. Thus, the concave lens diverges light rays, but the cylindrical lenses at right angles to each other. The vertical
convex lens converges light rays. cylindrical lens converges the light rays that pass through
Cylindrical Lens Bends Light Rays in Only One Plane— the two sides of the lens, and the horizontal lens converges
Comparison With Spherical Lenses. Figure 50-4 shows the top and bottom rays. Thus, all the light rays come to
both a convex spherical lens and a convex cylindrical lens. a single point focus. In other words, two cylindrical lenses
Note that the cylindrical lens bends light rays from the two crossed at right angles to each other perform the same func-
sides of the lens but not from the top or the bottom—that tion as one spherical lens of the same refractive power.
is, bending occurs in one plane but not the other. Thus,
parallel light rays are bent to a focal line. Conversely, light Focal Length of a Lens
rays that pass through the spherical lens are refracted at all The distance beyond a convex lens at which parallel rays
edges of the lens (in both planes) toward the central ray, converge to a common focal point is called the focal length
and all the rays come to a focal point. of the lens. The diagram at the top of Figure 50-6 demon-
The cylindrical lens is well demonstrated by using a test strates this focusing of parallel light rays.
tube full of water. If the test tube is placed in a beam of sun- In the middle diagram, the light rays that enter the con-
light and a piece of paper is brought progressively closer to vex lens are not parallel but are diverging because the origin
the opposite side of the tube, a certain distance will be found of the light is a point source not far away from the lens.
at which the light rays come to a focal line. The spherical lens Because these rays are diverging outward from the point
is demonstrated by an ordinary magnifying glass. If such a source, they do not focus at the same distance away from
lens is placed in a beam of sunlight, and a piece of paper is the lens as do parallel rays. In other words, when rays of
brought progressively closer to the lens, the light rays will light that are already diverging enter a convex lens, the dis-
impinge on a common focal point at an appropriate distance. tance of focus on the other side of the lens is farther from
Concave cylindrical lenses diverge light rays in only one the lens than the focal length of the lens for parallel rays.
plane in the same manner that convex cylindrical lenses The bottom diagram of Figure 50-6 shows light rays
converge light rays in one plane. Figure 50-5A shows how diverging toward a convex lens that has far greater curva-
light is focused from a point source to a line focus by a cy- ture than that of the other two lenses in the figure. In this
lindrical lens. diagram, the distance from the lens at which the light rays
Combination of Two Cylindrical Lenses at Right Angles come to focus is exactly the same as that from the lens in the
Equals a Spherical Lens. Figure 50-5B shows two convex first diagram, in which the lens is less convex but the rays

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 CHAPTER 50 The Eye: I. Optics of Vision

A entering it are parallel. This demonstrates that both parallel
Line focus rays and diverging rays can be focused at the same distance
beyond a lens, provided that the lens changes its convexity.

Formation of an Image by a Convex Lens
Figure 50-7A shows a convex lens with two point sources

UNIT X
of light to the left. Because light rays pass through the center
of a convex lens without being refracted in either direction,
the light rays from each point source of light are shown to
Point source of light come to a point focus on the opposite side of the lens di-
rectly in line with the point source and the center of the lens.
Any object in front of the lens is, in reality, a mosaic of
point sources of light. Some of these points are very bright
and some are very weak, and they vary in color. Each point
source of light on the object comes to a separate point focus
on the opposite side of the lens in line with the lens center.
If a white sheet of paper is placed at the focus distance from
the lens, one can see an image of the object, as demonstrat-
ed in Figure 50-7B. However, this image is upside down
with respect to the original object, and the two lateral sides
B Point source of light of the image are reversed. The lens of a camera focuses im-
ages on film via this method.
Point focus
Measurement of the Refractive Power of a Lens—
Diopter
Figure 50-5. A, Focusing of light from a point source to a line focus The more a lens bends light rays, the greater is its “refrac-
by a cylindrical lens. B, Two cylindrical convex lenses at right angles to tive power.” This refractive power is measured in terms
each other, demonstrating that one lens converges light rays in one of diopters. The refractive power in diopters of a convex
plane, and the other lens converges light rays in the plane at a right lens is equal to 1 meter divided by its focal length. Thus, a
angle. The two lenses combined give the same point focus as that spherical lens that converges parallel light rays to a focal
obtained with a single spherical convex lens. point 1 meter beyond the lens has a refractive power of
+1 diopter, as shown in Figure 50-8. If the lens is capable
of bending parallel light rays twice as much as a lens with
a power of +1 diopter, it is said to have a strength of +2
diopters, and the light rays come to a focal point 0.5 me-
ter beyond the lens. A lens capable of converging parallel
light rays to a focal point only 10 centimeters (0.10 meter)
beyond the lens has a refractive power of +10 diopters.
The refractive power of concave lenses cannot be stated in
terms of the focal distance beyond the lens because the light
rays diverge rather than focus to a point. However, if a concave
lens diverges light rays at the same rate that a 1-diopter convex
lens converges them, the concave lens is said to have a dioptric
Light from distant source strength of −1. Likewise, if the concave lens diverges light rays
as much as a +10-diopter lens converges them, this lens is said
to have a strength of −10 diopters.
Focal Concave lenses “neutralize” the refractive power of con-
points
vex lenses. Thus, placing a 1-diopter concave lens imme-
diately in front of a 1-diopter convex lens results in a lens
Point source system with zero refractive power.
The strengths of cylindrical lenses are computed in
the same manner as the strengths of spherical lenses, ex-
cept that the axis of the cylindrical lens must be stated
in addition to its strength. If a cylindrical lens focuses
parallel light rays to a line focus 1 meter beyond the lens,
it has a strength of +1 diopter. Conversely, if a cylindri-
Figure 50-6. The two upper lenses of this figure have the same focal
length, but the light rays entering the top lens are parallel, whereas cal lens of a concave type diverges light rays as much as
those entering the middle lens are diverging. The effect of parallel a +1-diopter cylindrical lens converges them, it has a
versus diverging rays on the focal distance is shown. The bottom lens strength of −1 diopter. If the focused line is horizontal,
has far more refractive power than either of the other two lenses (i.e., its axis is said to be 0 degrees. If it is vertical, its axis is
it has a much shorter focal length), demonstrating that the stronger 90 degrees.
the lens, the nearer to the lens is the focal point.

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UNIT X The Nervous System: B. The Special Senses

A

Point sources Focal points

B

Figure 50-7. A, Two point sources of light focused at two separate points on opposite sides of the lens.
B, Formation of an image by a convex spherical lens.

Total refractive power = 59 diopters
1
diopter

Image Object
2
diopters

Vitreous Lens Aqueous Cornea Air
10 humor 1.40 humor 1.38 1.00
diopters 1.34 1.33
Figure 50-9. The eye as a camera. The numbers are the refractive
indices.
1 meter
Figure 50-8. Effect of lens strength on the focal distance.
is considered to exist, with its central point 17 millimeters
in front of the retina and a total refractive power of 59 di-
OPTICS OF THE EYE
opters when the lens is accommodated for distant vision.
The lens system of the eye (Figure 50-9) is composed of About two-thirds of the 59 diopters of refractive power
four refractive interfaces: (1) the interface between air of the eye is provided by the anterior surface of the cor-
and the anterior surface of the cornea; (2) the interface nea (not by the eye lens). The principal reason for this
between the posterior surface of the cornea and the aque- phenomenon is that the refractive index of the cornea is
ous humor; (3) the interface between the aqueous humor markedly different from that of air, whereas the refractive
and the anterior surface of the lens of the eye; and (4) the index of the eye lens is not greatly different from the indi-
interface between the posterior surface of the lens and the ces of the aqueous humor and vitreous humor.
vitreous humor. The internal index of air is 1, the cornea, The total refractive power of the internal lens of the eye,
1.38, the aqueous humor, 1.33, the crystalline lens (on as it normally lies in the eye surrounded by fluid on each
average), 1.40, and the vitreous humor, 1.34. side, is only 20 diopters, about one third the total refractive
power of the eye. However, the importance of the internal
Consideration of All Refractive Surfaces of the Eye as
lens is that in response to nervous signals from the brain,
a Single Lens—The “Reduced” Eye. If all the refractive
its curvature can be increased markedly to provide “accom-
surfaces of the eye are added together algebraically and
modation,” which is discussed later in the chapter.
then considered to be one single lens, the optics of the nor-
mal eye may be simplified and represented schematically Formation of an Image on the Retina. In the same man-
as a “reduced eye.” This representation is useful in simple ner that a glass lens can focus an image on a sheet of paper,
calculations. In the reduced eye, a single refractive surface the lens system of the eye can focus an image on the retina.

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 CHAPTER 50 The Eye: I. Optics of Vision

The image is inverted and reversed with respect to the object. Sclerocorneal Cornea
However, the mind perceives objects in the upright position junction
despite the upside-down orientation on the retina because
Meridional
the brain is trained to consider an inverted image as normal. fibers
Sclera
MECHANISM OF “ACCOMMODATION”

UNIT X
In children, the refractive power of the lens of the eye
Lens
can be increased voluntarily from 20 diopters to about
34 diopters, which is an “accommodation” of 14 diopters. Suspensory Circular
To make this accommodation, the shape of the lens is ligaments fibers
changed from that of a moderately convex lens to that of Choroid Retina
a very convex lens.
In a young person, the lens is composed of a strong
elastic capsule filled with viscous, proteinaceous, but
transparent fluid. When the lens is in a relaxed state, with Ciliary muscle
no tension on its capsule, it assumes an almost spherical
shape, owing mainly to the elastic retraction of the lens
Suspensory
capsule. However, as shown in Figure 50-10, about 70 Lens ligaments
suspensory ligaments attach radially around the lens, pull-
ing the lens edges toward the outer circle of the eyeball.
These ligaments are constantly tensed by their attach-
ments at the anterior border of the choroid and retina.
The tension on the ligaments causes the lens to remain
Figure 50-10. Mechanism of accommodation (focusing).
relatively flat under normal eye conditions.
Also located at the lateral attachments of the lens liga-
ments to the eyeball is the ciliary muscle, which has two to keep the object constantly in focus. Sympathetic stimu-
separate sets of smooth muscle fibers—meridional fibers lation has an additional effect in relaxing the ciliary muscle,
and circular fibers. The meridional fibers extend from the but this effect is so weak that it plays almost no role in the
peripheral ends of the suspensory ligaments to the cor- normal accommodation mechanism; the neurophysiology
neoscleral junction. When these muscle fibers contract, of this mechanism is discussed in Chapter 52.
the peripheral insertions of the lens ligaments are pulled Presbyopia—Loss of Accommodation by the Lens. As
medially toward the edges of the cornea, thereby releas- a person grows older, the lens grows larger and thicker
ing the ligaments’ tension on the lens. The circular fibers and becomes far less elastic, partly because of progressive
are arranged circularly all the way around the ligament denaturation of the lens proteins. The ability of the lens
attachments so that when they contract, a sphincter-like to change shape decreases with age. The power of accom-
action occurs, decreasing the diameter of the circle of lig- modation decreases from about 14 diopters in a child to
ament attachments; this action also allows the ligaments less than 2 diopters by the time a person reaches 45 to 50
to pull less on the lens capsule. years and to essentially 0 diopters at age 70 years. There-
Thus, contraction of either set of smooth muscle fibers after, the lens remains almost totally nonaccommodating,
in the ciliary muscle relaxes the ligaments to the lens cap- a condition known as presbyopia.
sule, and the lens assumes a more spherical shape, like Once a person has reached the state of presbyopia,
that of a balloon, because of the natural elasticity of the each eye remains focused permanently at an almost con-
lens capsule. stant distance; this distance depends on the physical char-
Accommodation Is Controlled by Parasympathetic acteristics of each person’s eyes. The eyes can no longer
Nerves. Ciliary muscle is controlled almost entirely by par- accommodate for both near and far vision. To see clearly
asympathetic nerve signals transmitted to the eye through both in the distance and nearby, an older person must
the third cranial nerve from the third nerve nucleus in the wear bifocal glasses, with the upper segment focused for
brain stem, as explained in Chapter 52. Stimulation of par- far-seeing and the lower segment focused for near-seeing
asympathetic nerves contracts both sets of ciliary muscle (e.g., for reading).
fibers, which relaxes the lens ligaments, thus allowing the
PUPILLARY DIAMETER
lens to become thicker and increase its refractive power.
With this increased refractive power, the eye focuses on The major function of the iris is to increase the amount of
objects nearer than when the eye has less refractive power. light that enters the eye during darkness and to decrease
Consequently, as a distant object moves toward the eye, the amount of light that enters the eye in daylight. The
the number of parasympathetic impulses impinging on the reflexes for controlling this mechanism are considered in
ciliary muscle must be progressively increased for the eye Chapter 52.

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UNIT X The Nervous System: B. The Special Senses

The amount of light that enters the eye through the
pupil is proportional to the area of the pupil or to the
square of the diameter of the pupil. The pupil of the
human eye can become as small as about 1.5 millimeters Point sources of light
and as large as 8 millimeters in diameter. The quantity of
light entering the eye can change about 30-fold as a result
of changes in pupillary aperture. Lens
Focal point
“Depth of Focus” of the Lens System Increases With Lens
Decreasing Pupillary Diameter. Figure 50-11 shows two
eyes that are exactly alike except for the diameters of the
pupillary apertures. In the upper eye, the pupillary aper- Point sources of light
ture is small and, in the lower eye, the aperture is large. In
front of each of these two eyes are two small point sources
of light; light from each passes through the pupillary aper- Figure 50-11. Effect of small (top) and large (bottom) pupillary aper-
ture and focuses on the retina. Consequently, in both eyes, tures on depth of focus.
the retina sees two spots of light in perfect focus. If the
retina is moved forward or backward to an out of focus po-
sition (dashed lines), the size of each spot will not change
much in the upper eye, but in the lower eye the size of
each spot will increase greatly, becoming a “blur circle.” In
other words, the upper lens system has far greater depth of
focus than the bottom lens system. When a lens system has
Emmetropia
great depth of focus, the retina can be displaced consider-
ably from the focal plane, or the lens strength can change
considerably from normal, and the image will still remain
nearly in sharp focus, whereas when a lens system has a
“shallow” depth of focus, moving the retina only slightly
away from the focal plane causes extreme blurring.
The greatest possible depth of focus occurs when the
pupil is extremely small. The reason for this is that with a Hyperopia
very small aperture, almost all the rays pass through the
center of the lens, and the central most rays are always in
focus, as explained earlier.

Errors of Refraction
See Video 50-1.
Myopia
Emmetropia (Normal Vision). As shown in Figure 50-12,
the eye is considered to be normal, or emmetropic, if parallel Figure 50-12. Parallel light rays focus on the retina in emmetropia,
light rays from distant objects are in sharp focus on the retina behind the retina in hyperopia, and in front of the retina in myopia.
when the ciliary muscle is completely relaxed. This means
that the emmetropic eye can see all distant objects clearly closer and closer to the eye can also be focused sharply un-
with its ciliary muscle relaxed. However, to focus objects til the ciliary muscle has contracted to its limit. In old age,
at close range, the eye must contract its ciliary muscle and when the lens becomes “presbyopic,” a farsighted person is
thereby provide an appropriate degree of accommodation. often unable to accommodate the lens sufficiently to focus
Hyperopia (Farsightedness). Hyperopia, also known as even on distant objects, much less on near objects.
“farsightedness,” is usually due to either an eyeball that is too Myopia (Nearsightedness). In myopia, or “nearsight-
short or, occasionally, to a lens system that is too weak. In edness,” when the ciliary muscle is completely relaxed, the
this condition, as seen in the middle panel of Figure 50-12, light rays coming from distant objects are focused in front
parallel light rays are not bent sufficiently by the relaxed of the retina, as shown in the bottom panel of Figure 50-12.
lens system to come to focus by the time they reach the This condition is usually due to too long an eyeball but also
retina. To overcome this abnormality, the ciliary muscle can result from too much refractive power in the lens sys-
must contract to increase the strength of the lens. By us- tem of the eye.
ing the mechanism of accommodation, a farsighted person No mechanism exists whereby the eye can decrease the
is capable of focusing distant objects on the retina. If the strength of its lens to less than that which exists when the
person has used only a small amount of strength in the cili- ciliary muscle is completely relaxed. A myopic person has
ary muscle to accommodate for the distant objects, he or no mechanism to focus distant objects sharply on the reti-
she still has much accommodative power left, and objects na. However, as an object moves nearer to the person’s eye,

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 CHAPTER 50 The Eye: I. Optics of Vision

it finally gets close enough that its image can be focused.
Then, when the object comes still closer to the eye, the per-
son can use the mechanism of accommodation to keep the
image focused clearly. A myopic person has a definite limit-
ing “far point” for clear vision.
Correction of Myopia and Hyperopia Through Use of

UNIT X
Lenses. If the refractive surfaces of the eye have too much
refractive power, as in myopia, this excessive refractive
power can be neutralized by placing a concave spherical
lens in front of the eye, which will diverge rays. Such cor-
rection is shown in the upper diagram of Figure 50-13.
Conversely, in a person who has hyperopia—that is,
someone who has too weak a lens system—the abnormal
vision can be corrected by adding refractive power using a
convex lens in front of the eye. This correction is demon-
strated in the lower diagram of Figure 50-13.
One usually determines the strength of the concave or Figure 50-13. Correction of myopia with a concave lens (top) and
convex lens needed for clear vision by “trial and error”— correction of hyperopia with a convex lens (bottom).
that is, by first trying a strong lens and then a stronger or
weaker lens until the one that gives the best visual acuity
Point source
is found.
of light
Astigmatism. Astigmatism is a refractive error of the
eye that causes the visual image in one plane to focus at
A B
a different distance from that of the plane at right angles.
Astigmatism usually results from too great a curvature of
the cornea in one plane of the eye. An example of an astig-
C
matic lens would be a lens surface like that of an egg lying D
sidewise to the incoming light. The degree of curvature in Focal line Plane AC
the plane through the long axis of the egg is not nearly as for plane BD Plane BD (less refractive
great as the degree of curvature in the plane through the (more refractive power)
short axis. power)
Focal line
Because the curvature of the astigmatic lens along one for plane AC
plane is less than the curvature along the other plane, light
rays striking the peripheral portions of the lens in one plane
are not bent nearly as much as the rays striking the periph- Figure 50-14. Astigmatism, demonstrating that light rays focus at
eral portions of the other plane. This effect is demonstrated one focal distance in one focal plane (plane AC) and at another focal
in Figure 50-14, which shows rays of light originating from distance in the plane at a right angle (plane BD).
a point source and passing through an oblong, astigmatic
lens. The light rays in the vertical plane, indicated by plane the astigmatic lens. Then, an additional cylindrical lens is
BD, are refracted greatly by the astigmatic lens because of used to correct the remaining error in the remaining plane.
the greater curvature in the vertical direction than in the To do this, both the axis and the strength of the required
horizontal direction. By contrast, the light rays in the hori- cylindrical lens must be determined.
zontal plane, indicated by plane AC, are not bent nearly as Several methods exist for determining the axis of the
much as the light rays in vertical plane BD. Therefore, light abnormal cylindrical component of the lens system of an
rays passing through an astigmatic lens do not all come to a eye. One of these methods is based on the use of paral-
common focal point because the light rays passing through lel black bars of the type shown in Figure 50-15. Some of
one plane focus far in front of those passing through the these parallel bars are vertical, some are horizontal, and
other plane. some are at various angles to the vertical and horizontal
The accommodative power of the eye can never com- axes. After placing various spherical lenses in front of the
pensate for astigmatism because, during accommodation, astigmatic eye, a strength of lens that causes sharp focus of
the curvature of the eye lens changes approximately equally one set of parallel bars but does not correct the fuzziness
in both planes; therefore, in astigmatism, each of the two of the set of bars at right angles to the sharp bars is usually
planes requires a different degree of accommodation. Thus, found. It can be shown from the physical principles of op-
without the aid of glasses, a person with astigmatism never tics discussed earlier in this chapter that the axis of the out
sees in sharp focus. of focus cylindrical component of the optical system is par-
Correction of Astigmatism With a Cylindrical Lens. One allel to the bars that are fuzzy. Once this axis is found, the
may consider an astigmatic eye as having a lens system examiner tries progressively stronger and weaker positive
made up of two cylindrical lenses of different strengths and or negative cylindrical lenses, the axes of which are placed
placed at right angles to each other. To correct for astigma- in line with the out of focus bars, until the patient sees all
tism, the usual procedure is to find a spherical lens by trial the crossed bars with equal clarity. When this goal has been
and error that corrects the focus in one of the two planes of accomplished, the examiner directs the optician to grind a

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UNIT X The Nervous System: B. The Special Senses

special lens combining both the spherical correction and When a cataract has obscured light transmission so
the cylindrical correction at the appropriate axis. greatly that it seriously impairs vision, the condition can be
Correction of Optical Abnormalities With Contact corrected by surgical removal of the lens. When the lens is
Lenses. Glass or plastic contact lenses that fit snugly against removed, the eye loses a large portion of its refractive pow-
the anterior surface of the cornea can be inserted. These lenses er, which must be replaced by placing a powerful convex
are held in place by a thin layer of tear fluid that fills the space lens in front of the eye; usually, however, an artificial plastic
between the contact lens and the anterior eye surface. lens is implanted in the eye in place of the removed lens.
A special feature of the contact lens is that it nullifies the re-
fraction that normally occurs at the anterior surface of the cor- VISUAL ACUITY
nea almost entirely. The reason for this nullification is that the
Theoretically, light from a distant point source, when
tears between the contact lens and the cornea have a refractive
index almost equal to that of the cornea, so the anterior surface
focused on the retina, should be infinitely small. However,
of the cornea no longer plays a significant role in the eye’s opti- because the lens system of the eye is never perfect, such
cal system. Instead, the outer surface of the contact lens plays a retinal spot ordinarily has a total diameter of about 11
the major role. Thus, the refraction of this surface of the con- micrometers, even with maximal resolution of the normal
tact lens substitutes for the cornea’s usual refraction. This factor eye optical system. The spot is brightest in its center and
is especially important in people whose eye refractive errors shades off gradually toward the edges, as shown by the
are caused by an abnormally shaped cornea, such as those who two-point images in Figure 50-16.
have an odd-shaped, bulging cornea, a condition called kera- The average diameter of the cones in the fovea of the ret-
toconus. Without the contact lens, the bulging cornea causes ina—the central part of the retina, where vision is most highly
such severe abnormality of vision that almost no glasses can developed—is about 1.5 micrometers, which is one-seventh
correct the vision satisfactorily; when a contact lens is used,
the diameter of the spot of light. Nevertheless, because the
however, the corneal refraction is neutralized, and normal re-
fraction by the outer surface of the contact lens is substituted.
spot of light has a bright center point and shaded edges, a
The contact lens has several other advantages as well, person can normally distinguish two separate points if their
including the following: (1) the lens turns with the eye and centers lie up to 2 micrometers apart on the retina, which is
gives a broader field of clear vision than glasses; and (2) the slightly greater than the width of a foveal cone. This discrimi-
contact lens has little effect on the size of the object the nation between points is also shown in Figure 50-16.
person sees through the lens, whereas lenses placed about 1 The normal visual acuity of the human eye for discrim-
centimeter in front of the eye do affect the size of the image inating between point sources of light is about 25 seconds
in addition to correcting the focus. of arc. That is, when light rays from two separate points
Cataracts—Opaque Areas in the Lens. “Cataracts” are strike the eye with an angle of at least 25 seconds between
an especially common eye abnormality that occurs mainly them, they can usually be recognized as two points instead
in older people. A cataract is a cloudy or opaque area (or of one. This means that a person with normal visual acu-
areas) in the lens. In the early stage of cataract formation,
ity looking at two bright pinpoint spots of light 10 meters
the proteins in some of the lens fibers become denatured.
Later, these same proteins coagulate to form opaque areas
away can barely distinguish the spots as separate entities
in place of the normal transparent protein fibers. when they are 1.5 to 2 millimeters apart.
The fovea is less than 0.5 millimeter (