Using
The Direct Ophthalmoscope To Evaluate The Anterior
Chamber Angle Depth
Shadow Technique Of Evaluating Angles
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Width
Of Shadow
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Angle
Grade
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0 To 1 mm
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4
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1.5 To 2 mm
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4- To 3+
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2.5 To 3 mm Or 25%
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3
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3.5 To 4 mm Or >30%
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3- To 2+
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4.5 To 5 mm Or >40%
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2- To 1+
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> 5 mm Or >50%
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1 To 0
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Example
Of Technique:
No
Shadow, Open Grade 4 Angle
Using the
ophthalmoscope as a light source which is held tangential
to the iris one looks for any shadow that appears on the
nasal side. If the nasal corneal and iris junction has no
shadow you have a wide open angle. However, as this
shadow increases in width relative to the overall cornea
size, the angle becomes diagnostically
narrower.
Grading The Angle Opening
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Grade 4 To 3+
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Grade 3
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Grade 3- To 2+
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Grade 2- To 1+
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Grade 1 To 0
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Normal Open Angle
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Narrowed Angle
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The shadow
technique combined with the Van Herick technique will
give you results that are vary close to that of
gonioscopy. Vargas and Drance studied 135 eyes comparing
the shadow technique, Van Herick technique, against
gonioscopy and found that the shadow technique identified
26 of 29 "shallow eyes or approximately 90% the three
closure patients that were missed all had plateau iris.
The Van Herick technique identified 24 of the 29 shallow
chambers or approximately 83%. It has been appropriately
suggested that if both techniques were used, the
sensitivity would probably approach one hundred percent.
Narrow or shallow angles were classified as grades 1 or
grades 2.
Using
The Direct Ophthalmascope
1.)
Pupils & Opacities: when you shine the
ophthalmoscope into a patient's eye you should get a
red-orange fundus glow back from the retina assuming
there is nothing blocking its path. This is a good time
to evaluate the patient's pupils by comparing their
equality and shape (25% of the population have unequal
pupils to some degree and is not pathological in nature).
You should have either a +1 or +2 D lens in the
ophthalmoscope and be viewing the pupils at a distance of
40 to 66 cms form the patient. You should be looking for
any thing that interferes with the light returning from
the retina such as floaters, cataracts, corneal
distortions, scars, pigment on the lens, etc. You should
also note what motion the opacity has either with or
against, using the pupil plane as your reference point,
which will help you identify the location of the
disturbance. If the opacity moves in the same direction
you move the ophthalmoscope the opacity is located behind
the iris and most likely behind the embryonic nucleus. If
the opacity moves in the opposite direction the opacity
is located in front of the iris.
2.)
Anterior Segment: Add plus to the ophthalmoscope
and slowly work closer to the patient and the cornea,
keeping the eye in clear focus, and grossly examine the
cornea, lids, sclera, lashes and iris. At this point a
+13 0r 13D lens will now be in your ophthalmoscope. The
ophthalmoscope and your face will only be about 2 to 3
inches away from the patient or cheek to cheek so to
speak. This is the correct distance you should be for the
rest of the examination with the direct
ophthalmoscope.
3.)
Vitreous: Slowly reduce the plus power in the
ophthalmoscope and work your way back through the
vitreous examining it for slight changes. Such as
floaters, posterior vitreous detachments and general
degenerative changes of the vitreous body. Vitreous
floaters are best seen with a + 6 or 7 D lens in place.
With the retroillumination clearly in focus as the
patient to look very quickly to their left and right the
back to a fixation point. The floaters will be seen to
swirl across as dark cobwebs or filaments within the
retinal glow. It is better for you to ask the patient if
their floaters bother them than for the patient to ask if
you noticed them.
4.)
Disc: Controling your accommodation allows for a
close estimation of the patient's refractive error.
Estimation of the refractive error is made when the optic
disc just comes into focus. Examine the disc noting its
shape, color, margins clarity (blurred or distinct) any
scleral crescents of pigment crescents, what type nerve
head, the cup to disc (C/D) ratio, the depth of the
physiological cup, venous pulsation (+) or (-) or
elicited. The red free filter is helpful when judging the
C/D ratio and at times viewing the foveal reflex.
Spontaneous venous pulsation (SVP) is absent in
approximately 20% of normal individuals, therefore, you
must try to elicit venous pulsation if not
seen.
5.)
Vessels: Artery to vein ratio (A/V) ratio,
arterior light reflex (ALR), branching of vessels to all
four quadrants, crossings phenomenons, etc.
Arteriolar
Sclerosis and Associated Crossing Phenomenons
The eye is
one organ in the body where thrombosis of a vein results
from intimal arteriosclerosis. It occurs because the
central retinal vein and artery and their branches are
surrounded by a common adventitial sheath at their
arteriovenous crossings as well as within the optic
nerve. At these crossings the atheromatous process
readily invades the vein, causing a similar atheromatous
plaque on which a thrombosis may form. When you stop and
think about it, this is how and why patients may develop
a central retinal vein occlusion or a branch vein
occlusion. Central retinal artery and branch occlusions
,usually, result from the above plus emboli (plaques)
that have broken off the internal carotid artery,
ophthalmic artery, aorta or from a heart valve. Those
which successfully migrate into the arterioles of the
retina may be seen at an arteriole bifurcation and are
called "Hollenhorst plaques".
Two types
of sclerosis affects the arterioles of the retinas
(fundi) and are seen with the ophthalmoscope:
1.) Intimal atherosclerosis, a plaque - like
disease of the intima.
2.) Arteriolar sclerosis affecting the arterioles. This
is associated with, and believed to be a
consequence of hypertension.
Hypertensive
changes seen with the ophthalmoscope:
1.) First, narrowing of the arterioles (attenuation)
2.) Second, compression of the veins at artery vein
crossings and focal spasms of the arterioles, sometimes
referred to as sausaging.
3.) Third, hemorrhages which are usually of the flame
shape nature within the nerve fiber layer.
4.) Forth, exudates and "macular star"
5.) Fifth, Edema of the optic disc "papilledema", cotton
wool spots exudates and "macular star " Seen the chart
at the end of these notes.
6.)
Macula: you should record if the macula is clear
or are there drusens, pigmentary migration,
depigmentation (RPE drop out), elevated (edema), age
related macular degeneration (ARMD) and is there a foveal
light reflex (FLR) present. You should not ask the
patient to look into your light when viewing the macula
on a non-dilated patient. The patient will accommodate
and this together with the bright light from your
ophthalmoscope will make the pupil even smaller reducing
your ability to view the whole macula area. You must
develop the skill of moving temporally with your
ophthalmoscope into the macula area not only viewing the
fovea but the whole macula area plus the
fovea.
7.)
Fundus: Observe as much of the posterior pole as
possible and check the integrity of the back ground. To
accomplish this have the patient look in different
directions, since, the total area seen is only 6.5 to 10
degrees at any one time. This will depend to some extent
on the patient's pupil size.
8.)
Filters: The red free filter in the ophthalmoscope
is a very diagnostic tool. For one it is used to
differentiate between retina nevi or choroidal nevi. The
retinal blood supply and its retinal pigment epithelium
(RPE) act like a red filter. Therefore, a nevus that is
behind the retina and located in the choroid will not be
seen when viewed with the red free filter since red and
green cancel each other out. On the other hand a nevus
located on or in the retina will still be seen with the
red free filter in place. The red free filter also makes
small macro-aneurysms and small hemorrhages standout more
clearly. The red free filter can also be helpful in
estimating the C/D ratio. Nerve fibers are lost in
glaucoma and optic atrophy and using the red free filter
can help detect these subtle changes. If the scope has a
cobalt blue filter this too works to detect nerve fiber
drop out. Some feel the aforementioned condition is best
view with the cobalt blue since the blue light wave
length is focused more directly in the nerve fiber layer.
Other than the nerve fiber layer the cobalt blue filter
has little use when examining the retina.
The optic
nerve head is usually not round but oval in nature. The
horizontal component is approximately 1.5mms (1500
microns) or 5.5 degrees across and the vertical component
is 7.5 degrees. The fovea is located approximately 2DD
temporal and 1.5 degrees below the horizontal. The small
spot of light (apertural) in the direct ophthalmoscope is
intended to be approximately one disc-diameter in size.
Place the spot on the disc and observe how much of the
disc is filled up. If the disc fully fills the spot of
light and matches its size this would indicate a normal
disc size. Optic nerve heads will vary in size. A recent
study, Heijl A., Molder H. Act Ophthalmologica 71
(1993) 122-129, there is a tendency to label large discs
with large cup as being glaucomatous even if they are not
and small discs as normal even when glaucoma is
present.
Magnification
Of The Direct Ophthalmoscope
The direct
ophthalmoscope gives a magnification of approximately 15
x and a field of view of 6.5 to 10 degrees, therefore, if
you want to see more than just the very posterior pole
you will have to have the patient look in 6 to 8
different directions. This 15 x magnification makes the
1.5 mm disc appear much larger than it really is. The
formula M= 60D/4 holds well for up to + or - 10D's of
refractive error. You can really appreciate this small
field of view when you compare what you seen with the
direct and the indirect view of the penlight
technique.
Monocular
Indirect Ophthalmoscope
The
monocular indirect ophthalmoscope (MIO) gives a
magnification of 5 x and a field of view of approximately
30 degrees, but it is important that you have the patient
look in 6 to 8 different directions to see as much of the
fundus as possible. The optical system of the MIO has an
erecting lens which allows you to see things as they
actually appear anatomically. It also gives you a greater
working distance from the patient of 5 to 6 inches. The
mio has a yellow filter that allows one to see deeper
details of the retina at about the level of the choroid
which is nice. The cost of the MIO is about equal to that
of a good binocular indirect ophthalmoscope and you of
course do not get a stereoscopic view of the
retina.
Things
not to do:
There are
certain things that you should be careful of or not do at
all when performing ophthalmoscopy on a patient. Do not
put your hands on the patient's shoulder use the back of
the chair to steady yourself. Do not put your hands on
the top of the patient's head. Number "ONE" women
and many men do not like for you to mess up their hair
and "SECOND" there are men who are wearing hair
pieces that go flying off their head very easily "be
careful out there." Last, you cannot do much about your
patient's breath on personal hygiene, but you can yours
so make sure to pay some attention to the
both.
Penlight
Ophthalmoscopy
This is a
very old technique that originally utilized a pen light
and a high plus lens. The pen light can still be used,
however, your direct ophthalmoscope gives a brighter
light that is more uniform. The patient must be dilated
to get as much binocularity as possible and large field
of view. The ophthalmoscope is held just below your eyes
and its light directed into the patient's eye. The
patient's eye is viewed from over the top of the
ophthalmoscope while a 20D lens is placed approximately
3-4 cm from the patient's eye. The condensing lens is
held just like a 90 or 78D lens between the thumb and
forefinger with the other fingers resting on the
patient's brow or forehead. The light leaving the
condensing lens must come to focus within the pupil
allowing the fullest field of view of the retina,
approximately 30 degress. The image is inverted and
perverted and located between the ophthalmoscope and the
condensing lens. The degree of stereopsis depends on how
fully the pupil is dilated and ones ability to converge
and accommodate on the image. There are a number of views
when stereopsis will be lost and the image is seen in a
monocular fashion. It still gives a larger field of view
than a MIO though less magnification. One should not be
mislead in believing this will take the place of a
binocular indirect ophthalmoscope (BIO) for you just do
not have the stereopsis. This is an excellent method to
examine small infants. They become frightened by the
ominous looking presence of the BIO on the doctor's head
not to mention the bright light. Should the bulb burn out
in a BIO one has an alternative means to get a good view
of the peripheral fundi.
Grades Of Vascular Retinopathies
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A.) Hypertension
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B.) Arteriosclerosis
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Degree
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A/V Ratio
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Hemorrhages
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Exudates
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Papilledema
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Light Reflex
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A/V Crossings
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Normal
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2/3-3/4
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None
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None
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None
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Fine Yellow Line
1/3-1/4
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None
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Grade 1
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A/V=1/2
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None
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None
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None
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Slight Increase
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Mild Compression
Of Venules
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Grade 2
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A/V=1/3
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None
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None
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None
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More Marked
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Compression or
Elevation Of Venules
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Grade 3
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A/V=1/4
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Present
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Macular Star
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None
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Copper Wire
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Right Angle Deviations,
Nicking Or Tapering
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Grade 4
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Fine Cords
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Present
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Cotten Wool &
Macular Star
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Present
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Silver Wire
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All The Above Plus
Marked Distal Congestion
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Hypertension
And Arteriosclerosis May Occur Together In Varying
Degress. This Table Is Only Intended To Serve As A Guide
To Better Help Organize The Ocular Signs.
