Visual Field Analyzer

Why test your peripheral vision?

Visual field analyzers are often used in detection and diagnosis of Glaucoma, AMD, Scotomas and brain abnormalities. These analyzers test the full horizontal and vertical field of peripheral vision, identifying potential diminished or blind spots (scotomas) in the patients’ vision. Identifying specific scotomas in ones vision can be indicative of a certain type of brain trauma or disease, such as a stroke or tumour. The patient is directed to identify certain light stimuli provided by the analyzer in their peripheral vision, if the patient is unable to detect the stimuli, then this could indicate trauma and/or scotomas.

These visual field analyzers can offer up to 90º of measurement across the visual field and boast features such as monocular and binocular testing, fast and simple operation, colour and kinetic perimetry to name just a few.

How visual field testing helps identify eye issues

Many eye and brain disorders can cause peripheral vision loss and other visual field abnormalities. Visual field tests are performed by eye care professionals to detect blind spots (scotomas) and other visual field defects, which can be an early sign of these problems.

The size and shape of a scotoma offer important clues about the presence and severity of diseases of the eye, optic nerve and visual structures in the brain. For example, optic nerve damage caused by glaucoma creates a very specific visual field defect. Other conditions associated with blind spots and other visual field defects include diseases of the retinaoptic neuropathy, brain tumors and stroke.

During a routine eye exam, your optometrist or ophthalmologist may recommend visual field testing to assess the full horizontal and vertical range and sensitivity of your vision. These “baseline” visual field test results can then be used to assess potential changes in your visual field in the future.

Types of visual field tests

Confrontation visual field testing typically is used as a screening visual field test. One eye is covered, while the other eye fixates on a target object, such as the doctor’s open eye, while the doctor stands or sits directly in front of you. You then are asked to describe what you see on the far edges or periphery of your field of view.

As an example, your eye doctor may hold up different numbers of fingers within your peripheral field of view and ask how many can be seen while you continue to fixate on the doctor’s eye. If an eye disease is suspected, you may need to undergo more comprehensive, formal types of visual field testing to evaluate the quality of your central and peripheral vision. A variety of sensitive tests for measuring visual field loss exist, including:

  • Automated Perimetry. Various forms of automated perimetry tests measure your responses to the presence of objects in different areas of your field of view. While your head is held still, usually with a forehead and chin rest inside a large bowl-like instrument, you stare at a source of light straight ahead and tiny lights of different intensities are flashed from random points in your visual field. Each time you see one of these lights, you immediately press a button or use some other means to indicate your response. If you can’t see the lights in certain parts of your field of view, then you may have a blind spot indicating vision loss. This is a common form of visual field testing.

  • Frequency Doubling Perimetry. Frequency doubling is based on an optical illusion produced with vertical bars of contrasting colors (usually black and white) appearing on a screen. These bars appear to double in number when they alternately flicker at higher frequencies, a phenomenon thought to be due to the unique response of specific light-sensitive cells (photoreceptors) in the retina. Inability to see vertical bars at certain frequencies could indicate optic nerve or other types of eye damage with accompanying loss of vision in certain areas of the visual field.
  • Electroretinography. This test measures electrical activity generated by the photoreceptor cells in the retina when the eye is stimulated by a special strobe light or a reversing checkerboard pattern of light. The measurement is captured by an electrode placed on the front surface of the eye (cornea), and a graphic record called an electroretinogram (ERG) is produced. Electroretinography is useful in diagnosing several hereditary and acquired disorders of the retina, including retinitis pigmentosa, a detached retina or functional changes in the retina caused by arteriosclerosis (hardening of the arteries) or diabetes.


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