Humphrey visual field analyser


Humphrey field analyser[], is a tool for measuring the human visual field, it is used by optometrists, orthoptists and ophthalmologists, particularly for detecting monocular visual field.
The results of the Analyser identify the type of vision defect. Therefore, it provides information regarding the location of any disease processes or lesion throughout the visual pathway. This guides and contributes to the diagnosis of the condition affecting the patient's vision. These results are stored and used for monitoring the progression of vision loss and the patient's condition.

Medical uses

The Analyser can be used for screening, monitoring and assisting in the diagnosis of certain conditions. There are numerous testing protocols to select, based on the purpose. The first number denotes the extent of the field measured on the temporal side, from the centre of fixation, in degrees. The '-2' represents the pattern of the points tested. They include:
The above tests can be performed in either SITA-Standard or SITA-Fast. SITA-Fast is a quicker method of testing. It produces similar results compared to SITA-Standard, however repeatability is questionable and it is slightly less sensitive
There are additional tests for more specific purposes such as the following:
The Analyser test takes approximately 5–8 minutes, excluding patient set up. There are multiple steps which need to be done before commencement of the test to ensure reliable results are attained.
The test type and eye are firstly selected and the patient's details are entered, including their refractive error. The Analyser will provide a lens strength and type, if required for the test. In these instances, wire-rimmed trial lenses are generally used, with the cylindrical lens placed closest to the patient so the axis is easily read. The clinician can alter the fixation targets as per necessary.
Before putting the patient onto the machine, the requirements of the test itself are clearly explained. The patient is instructed to maintain fixation on the central target and is given a buzzer to only press when they see a light stimulus. It is not possible to see every light and some lights appear brighter/duller and slower/faster than others. The eye not being tested is patched and the room lights are dimmed prior to commencement of the test.
The patient is positioned appropriately and comfortably against the forehead rest and chin rest. Minor adjustments to the head position are made to centre the pupil on the display screen to allow eye monitoring throughout the test. The lens holder should be as close to the patient's eye as possible to avoid artefacts.
It is important for the patient to blink normally, relax and maintain concentration throughout the test. This will increase the reliability of results. File:Fixation targets.jpg|thumb|Figure 3 - Fixation targets
left: central, middle: small diamond, right: large diamond

How it works

The Analyser projects a series of white light stimuli of varying intensities, throughout a uniformly illuminated bowl. The patient uses a handheld button that they press to indicate when they see a light. This assesses the retina's ability to detect a stimulus at specific points within the visual field. This is called retinal sensitivity and is recorded in 'decibels'.
The Analyser currently utilises the Swedish Interactive Thresholding Algorithm ; a formula which allows the fastest and most accurate visual field assessment to date. Results are then compared against an age-matched database which highlights unusual and suspicious vision loss, potentially caused by pathology.

Fixation targets

There are different targets a patient can fixate on during the test. They are chosen on the basis of the patient's conditions.

Reliability indices

Issues of reliability are critical in result interpretation. These include, but not limited to, the patient losing concentration, closing their eyes or pressing the buzzer too frequently. Monitoring fixation is made visible via the display screen and gaze tracker, located at the bottom of the printout. The degree of reliability is determined by the reliability indices located on the printout. These are assessed first and allow the examiner to determine if the end results are reliable. These indices include:
After reliability is determined, the remaining data is assessed.

Numerical Display

The numerical display represents raw values of patient's retinal sensitivity at specific retinal points in dB. Higher numbers equate to higher retinal sensitivities. Sensitivity is greatest in the central field and decreases towards the periphery. Normal values are approximately 30 dB while recorded values of <0 dB equate to no sensitivity measured.

Grey Scale

The grey scale is a graphical representation of the numerical display, allowing for easy interpretation of the field loss. Lower sensitivities are indicated by darker areas and higher sensitivities are represented with a lighter tone. This scale is used to demonstrate vision changes to the patient but is not used for diagnostic purposes.

Total Deviation

The numerical total demonstrates the difference between measured values and population age-norm values at specific retinal points.
The statistical display demonstrates the percentage of the normal population who measure below the patient's value at a specific retinal point. The probability display provides this percentage a key for interpreting the statistical display. For example, the darkest square in the key represents that <0.5% of the population would also attain this result, indicating that the vision loss is extensive. The Total Deviation plots highlight diffuse vision loss.

Pattern Deviation

The pattern deviation provides a numerical total and statistical display as the Total Deviation plot. However, it accounts for general reductions of vision caused by media opacities, uncorrected refractive error, reductions in sensitivity due to age and pupil miosis. This highlights focal loss only. Therefore, this is the main plot referred to when making a diagnosis. The Pattern Deviation plot is generally lighter than the Total Deviation because of the factors accounted for.

Global Indices

These provide a statistical summary of the field with one number. Although not used for initial diagnosis, they are essential for monitoring glaucoma progression. They include:
The Glaucoma Hemifield Test provides assessment of the visual field where glaucomatous damage is often seen. It compares five corresponding and mirrored areas in the superior and inferior visual fields. The result of either 'Outside Normal Limits', 'Borderline' or 'Within Normal Limits' is only considered when the patient has, or is a suspect for, glaucoma. This is only available in 30-2 and 24-2 Analyser protocol.

Visual Field Index (VFI)

The VFI reflects retinal ganglion cell loss and function, as a percentage, with central points weighted more.
It is expressed as a percentage of visual function; with 100% being a perfect age-adjusted visual field and 0% represents a perimetrically blind field. The pattern deviation probability plot is used to identify abnormal points and age corrected sensitivity at each point is calculated using total deviation numerical map. VFI is a reliable index on which glaucomatous visual field severity staging can be based.
The shaded pattern of vision loss provided on the Pattern Deviation plot allows for diagnosis of the type of vision loss present. This contributes to other clinical findings in the diagnosis of certain conditions. The types of vision loss and associated conditions are not described in the extent of this article, however Figure 5 provides typical examples of visual field loss seen. Refer to #See also for more information.

Advantages and Disadvantages

Advantages