Perimetry (2. LF UK)

Introduction
Perimetry is a method for getting information about status of visual field and its possible abnormalities. It is a subjective method of examination, which always needs cooperation of the patient, and possibility of errors must be thought of.

Visual field is the area that one eye is able to see without moving the angle of vision

Normal visual field of human eye is about 60° upwards, 70° downwards 65° towards the nose and 95° outwards. We are able to distinguish between central vision and peripheral vision. As the name says, central vision gives us information from the center of the visual field of the eye. This area is about one fifth of the whole visual field but over 80% of eyesight information comes from this area. Area of peripheral vision is around central vision and it does not give us as sharp image as the central vision. The status of visual field gives us useful information, not only about function of retina, but the condition of optic nerve and intracranial section of visual path. It is also important to outline the existance of several types of perimetry: Tangent Perimetry, Goldmann Perimetry, Automated Perimetry(is based on Goldmann perimetry) and Microperimetry. Despite the existance of the other 3 our paper will focus on automated perimetry only; as it is the most wide spread type of perimetry in modern hospitals.

Importance to Clinical Medicine
Perimetry is mainly used in Ophthalmology which is a branch of medicine that discusses the diseases of the eyeball such as Blindness, cataract and glaucoma. In addition, as perimetry is focused on detecting the blind spot of the eye it can also discuss the problem of scotoma that can be a sign of a desease in the eye.Consequently, the most important use of Perimetry is to prevent damage of the optic nerve, central nervous system, visual structures in the brain and also the diseases of the eye which can cause peripheral vision loss and other visual field abnormalities. The most commonly discussed disease by the Perimetry is glaucoma that can cause damage to the optic nerve. The Perimetry test is also used to diagnose many diseases other than those mentioned before. The examples of such more complicated deseases are: macular degeneration, optic glicoma, brain tumor, stroke, central nervous system disorder and the pituitary gland disorder. The results of the Perimetry test can tell in which areas the patient have a problem in his visual field and indicate the areas of the brain or optic nerve that are damaged or about to be damaged or cause a desease.

Literature Review
Perimetry has become one of the more evolved concepts of medicine, which physicians use to further develop their understanding of some diseases, especially with cases of glaucoma. This disease is the elevated internal pressure in the eye which subsequently degrades the field of vision. Perimetry is a test that measures field of vision. Through this means, we can further our understanding of the glaucoma and evaluate an individual’s condition.

Perimetry is a visual field test that measures the subject’s central and peripheral vision. To do this procedure, one eye has to be completely covered as only one eye can be tested at a time. The subject has to look to a perimeter, a device that measures the capabilities of an individual’s field of vision. This device has a defined white background, which optimizes results and sends them to the program in a computer. A doctor and a patient work coherently, the patient is displayed flashes on this background. The computer creates a printout of all the positions of the flashes on the background and distinguishes the field of vision depending on how well the patient reacted to the stimuli. The disease, glaucoma, as before mentioned, can be predicted if the subject shows to have more than one blind spot as well as degraded areas of their vision.

Perimetry is a particularly well developed field in that it is a reliable means to test an individual’s field of vision. However, this procedure is subjective; it is only able to be as efficient and reliable in its results as the subject is able or willing to participate. Only with the subject’s full co-operation can the test be successful and reliable. The results however, can never be definitive as each subject, does not and/or cannot behave and carry out this procedure with the accuracy and precision of the technology present. The only disadvantage is that no matter the conditions, subject or technology, the results from the test will not be as accurate as they can be, but at the same time, is the most accurate method to use at this time.

Perimetry can be described as stagnant, regarding its testing procedure. There are no changes, minute if any, to the test. If a subject, that experiences vision loss, partakes in this test several times, he or she will develop a learning curve that will help them subconsciously perform better. For example, a 1996 study examined twenty-five individuals that were just newly detected with glaucomatous eyes. The results of the study determined that “visual field results improved with repeated testing” and these results “were more pronounced peripherally than centrally” (Heijl). Results to this test cannot be strictly followed depending on the amount of exposure of the test to the subject as well as the subject’s capability to perform this test.

Automated Perimeter MEDMONT M-700.
The perimeter is used usually by the ophthalmologists. It is one of the best tool for assessing visual fields.
 * F - ixation point : fixation target at which the patient must fix their vision.
 * T - he response button to use when the patient see the light goes off.
 * T - he eyepatch you will use to cover one eye.
 * Chin-Brow Rest - purposed to make patient feel comfortable and fully concentrate on the test. It also provides fixation of forehead and chin making it easier for the patient to focus on fixation point.
 * Perimetry.gifple light dots - normally they are switched off, when the test starts one will be active at a time, than another. The patient must press the response button when he sees the light.

The operating software MEDMONT STUDIO
This software is an advanced system analysis with many options such as:
 * Global Statistics - Allows interpretation of the perimetry results. After the patient finishes the test his results will be compared to the average result of his age group. This tool compares all the points tested and allows us to interpret which areas have defects compared to an average healthy person. This option makes it much more easy for the doctor to identify and problems of abnormalities in the patient's visual field.
 * Regression and Histogram analysis - Shows the patterns over time in the form of a diagram or histogram that will display changes over time. Full patient's history is different as it does not provide any analysis but raw data.
 * Full patient history - allows doctor to track the changes in the visual field of a particular patient making it possible to identify long term patterns. It might as well assist in diagnosis.

Methodology
Practical Use of the Perimeter

Procedure: After Test You will see such abbreviations: False -ve and False +ve.
 * 1) Turn on the perimeter table,perimeter, and the computer.
 * 2) Using the program Medmont, register one of the group members as a patient (File/New/Patient) and then save the data you entered.
 * 3) Run an examination on your patient (File/New/M700N Exam). You will see initial test control window. This window is the representation of the Perimeter. The grey points are the points that will not be tested. The numbers inside the black dots represent the exposure level in decibels and based on the Age Normal Hill of Vision Distribution.
 * 4) Select the type o the exam: Glaucoma test. Then choose the eye you want to test and set it in the program settings. After it, click Edit Setting in the Test Menu.  From the Stimulus Parameters group select Standard.
 * 5) Tick Adaptive Response checkbox, which means that as the test progresses the response time will adapt based on how quickly the patient responds to exposures.
 * 6) From the Strategy box select Fast threshold.
 * 7) Cover one eye of the patient. Patient should focus his eye on the fixation target
 * 8) Start demonstration mode. After patient is familiar with setting press the start button. IMPORTANT: Test will start immediately.
 * 9) Patient should follow the light and click for every light he or she follows.
 * 10) Surroundings shall not disturb the patient no one shall talk enter or exit the room.
 * 11) Dots will change colour:in the course of the test blue – not tested; red -  tested, not seen; green – tested, seen; white – completed state.
 * 12) After the test, the result status will be displayed on the program.
 * 13) Disinfect the eye patch.

False -ve:
Around every 10th exposure the perimeter will expose one of the completed points of 9dB or dimmer to the patient again (but increasing it by 9dB). This is the reliability test: If the patient will notice this exposure it means that he he really sees this point and has no blindspot their. However, if the exposure remains unnoticed by the patient it means that he had completed the point by guessing rather than by seeing it. Higher false negatives - less reliability. Value of about 33% would indicate low reliability of the patient and the test.

False +ve:
Considered as even more important indicator of reliability than False -ve, False +ve tests whether patient really sees the light or he just responds to a rhythm of lights (lights appear at the same periods of time. Just as the previous test, False +ve test appears after around every tenths light. The mechanism is a bit different. Instead of testing already completed points, this reliability test is based on using the time slot of the light but not exposing any light at all. Therefore, if the patient simply responds to a rhythm he would press the button while there might not be any light at all. High value of False +ve indicates low reliability of the patient. 20% rate would indicate low patient's reliability as well as low reliability of the test.

Fluctuation Measure
Fluctuation measurement adds a further level of confidence by re-testing a number of suspect points and recording the variability of these results as a fluctuation measure. As the test progresses, four spatially dispersed and completed points with the highest defect levels (but not brighter than 3 dB) are chosen for fluctuation testing and are re-tested four times. To ensure four points are chosen the default threshold defect level is progressively reduced as the test proceeds. When the test concludes, the completed threshold values for these points are examined and their standard deviation (SD) computed.
 * 3 or more points with SD > 2.50 - Indicates high severity
 * 2 or more points with SD > 2.75 - Indicates medium severity
 * 1 or more points with SD > 3.05 - Indicates low severity

Abnormal Points
3 Conditions must be satisfied for a point to be considered abnormal: The Button Retest Abnormals will retest those abnormal points. Abnormal points might occur because of loss of attention of the patient during the test or simply not reacting to a light despite seeing it.
 * 1) It deviates by more than 6 dB from the mean of its neighbours
 * 2) The variation within the neighbourhood is reasonable for this test.
 * 3) There are an adequate number of neighbour points (i.e. the point is not isolated).

Fixation Loss
A Fixation Loss control is set automatically. A fixation loss higher than 20 % indicates low patient and low test reliability.

Processing of Data
Data processing is based on the information saved in the Medmont Studio. The information comes from the test in several different formats. If the patient had been tesated previously you woudl also be able to see all the results.
 * 1) Open the file.
 * 2) The toolbar will appear in the upper menu with 3 options (First is for patient's information; Second for test results; Third icon is for regression analysis of the patient's tests.
 * 3) Click second icon for test results.
 * 4) Open the patient’s file on the left panel. The View Mode controls how the selected exams are displayed. Select the View mode from the View menu. Select Combination View. It displays 4 different clinical views of the same exam allowing deeper and more accurate analysis.
 * 5) Display the results as a printing preview, save into folder Praktikum Perimetrie (in Dokumenty folder, shortcut on the desktop) as .jpg or .tiff file format. Print out the result and attach them to the report or upload them to the server.

Evaluation of The Defects

 * 1) HoV (Hill of Vision). Depending on the eccentricity (distance from the center expressed in degrees) the threshold value changes. Values of the patient's HoV are expressed as the linear slope dB/10° and level in dB corresponding to 3° eccentricity. This means that at 3° eccentricity the patient’s mean threshold was 25.5 dB, and it fell away at 3.5 dB for every 10° of eccentricity. Thus at 20° the HoV level would be 19.55 dB. The calculation might be like this: We need to know dB for 20°, we have value for 3°. The value of dB will be lower at 20° than at 3° as we move further from the centre. The difference between 20° and 3° is 17°. 17/10 = 1.7; we also know slope HoV (3.5 dB/10°). We multiply 3.5 by 1.7: 3.5*1.7 = 5.95dB. Therefore, the difference will be 5.95dB. We know that at 20° it is lower therefore we subtract: 25.5dB - 5.95dB = 19.55dB. That is an example of how you use HoV.
 * 2) Overall defect (OD) is the mean difference between the age normal HoV and the mean deviation or patient based HoV. This number is negative if the patient’s HoV is less than the age normal HoV. At the age of 1-45 Low Severity is above -2.6; Medium Severity -3.72; High Severity -4.92. At the age of 46-60 Low Severity is above -2.8; Medium Severity -4.05; High Severity -6.10. At the age greater than 60 Low Severity would be -3.2; Medium Severity -5.95, High Severity --8.91.
 * 3) Pattern defect (PD) is based on spatial correlation, and is a measure of the clustering and depth of defects. It is a scaled mean value of the product of a point’s HoV deviation and that of its neighbours. It qualifies the extent to which deviations are spatially correlated or clustered. For example if deviations from the patient’s HoV are distributed more or less randomly throughout the field, then the PD will be small. As deviations tend to cluster, the index will increase, particularly where both the absolute deviations and clustering are high. Pattern Defect of Low Severity is more or equal to 2.8; Medium Severity is more or equal to 5.7; High Severity is more or equal to 8.6.

Conclusion
The modern type of perimetry, “White-on-white” perimetry is used in the vast majority of research projects and hospitals; yet many tests and histological studies proved this type of perimetry to be simply not sensitive enough. Furthermore, it can be stated that it is a subjective test rather than an objective as the person can guess when the light is on. Studies showed that only after 25-50% loss of ganglion cells (although field of vision might not be affected that much), perimetry could detect only mild deficit.

Testing Subset of Ganglions Instead of the Whole Nerve
Most of the newly developing tests focus on testing different optic pathways – different parts of optic nerve transmitting information about: 1) motion; 2) colour and form: 3) short-wavelengths information. Testing the subset of ganglions (1-3) proved to be a more reliable than white-on-white perimetry for detection of specific diseases (mainly glaucoma).

Improvement in Reliability by Removing Subjectivity
Another option may remove subjectivity from perimetry. This technology is a theory now: we could connect directly to the optic nerve and the corresponding part of the brain to check if the patient really sees the light or they just guess.

First solution would undoubtedly allow us to detect glaucoma at much early stages and slow down/avoid ganglion loss. Second solution could transform subjective into objective and add reliability to the test.

References:
2015. Web. 12 Dec. 2016. (Literature Review) "Low-, Medium-, and High-risk Ocular Hypertensive Eyes." Archives of Ophthalmology (Chicago, Ill. : 1960). U.S. National Library of Medicine, Jan. 1995. Web. 12 Dec. 2016. (Literature Review) Experience in Patients With Glaucoma." The JAMA Network. JAMA Ophthalmology, 01 Jan. 1996. Web. 12 Dec. 2016. (Literature Review) Procedures; Article in Clinical and Experimental Optometry 2005; Allison M McKendrick; MScOptom PhD; School of Psychology, University of Western Australia; P. 73; 74; 75. (2 links are given for the same information) file:///C:/Users/User/Downloads/Recent_developments_in_perimetry_Test_stimuli_and_.pdf
 * Sheppard, John, MD. "Visual Field Test: Learn How the Procedure Is Performed." MedicineNet. Ed. William C. Shiel. N.p., 6 Mar.
 * Johnson, CA, Brandt, JD, Khong, AM, and Adams, AJ.
 * PhD, Anders Heijl MD. "The Effect of Perimetric
 * Recent Developments in Perimetry: Test Stimuli and

http://onlinelibrary.wiley.com/doi/10.1111/j.1444-0938.2005.tb06671.x/epdf (Conclusion) Chris A. Johnson, PhD, DSc; November 2015; Volume 13; http://glaucomatoday.com/2015/12/the-next-generation-in-perimetry (Conclusion) http://www.glaucoma.org/treatment/why-do-i-need-a-visual-field-test.php (Importance to clinical medicine)
 * Glaucoma Today; Title: The Next Generation in Perimetry; By
 * HealthLine Website; izual Field Exam;Wrtten by: Janelle Martel; Medically Review by Seven Kim; 6th January 2016 http://www.healthline.com/health/visual-field#AutomatedPerimetryTest4 (Importance to clinical medicine)
 * AllAboutVision Website; Visual Field Testing; Written by Marilyn Haddrill; Reviewed by Charles Slonim, MD; http://www.allaboutvision.com/eye-exam/visual-field.htm (Importance to clinical medicine)
 * Glaucoma Research Foundation Website; Why do I need a visual test? Written by Anna C. Momont, MD and Richard P. Mills, MD, MPH; Last Reviewed: Spetember 2014i