Zeiss Humphrey Visual Field Analyzer User Manual
Field analyzer user manual Download Zeiss humphrey visual field analyzer user manual. For most versions of the Linksys WRT310N, the default password is admin. Go and get a on-line quotation from the 2pass Insurance Providers explain please I have no idea what this means. 380 projects. The ZEISS Humphrey Field Analyzer HFA 750 represents the culmination of more than 25 years of research, development and clinical experience. As the premier automated visual field perimeter, the ZEISS Humphrey Field Analyzer is the current standard of care for diagnosing and managing glaucoma. The Touchstone of Glaucoma Diagnosis & Treatment. Carl Zeiss Visual Field Analyzer Humphrey 750i Field Analyzer Hfa Ii-I Model Information: Features: Threshold Visual Fields in as Little as 2 Minutes. SITA sensitivity, reproduci. Carl Zeiss Humphrey 720 Perimeter Field Analyzer II come with a video eye monitor and compact ergonomic design to increase patient comfort. Carl Zeiss Humphrey 720 examine the patient’s visual field with utilizes a computerized. Carl Zeiss Humphrey 720 include STATPAC 2 Analysis Software which compares test results to age-matched normative data and wheelchair accessible.
8 AVAILABLE
KEY FEATURES :
- ZEISS 750i GUIDE MANUAL .
- POWER TABLE.
- GPA ENABLED.
- SITA-SWAP ENABLED.
- KEYBOARD.
- PRITEX PRINTER WITH NEW PRINTER PAPER.
- ZEISS DUST COVER.
- NEW BULB.
- PATIENT CLICK.
- POWER CORD AND PRINTER CORD.
- ADVANCED ANALYSIS:
Zeiss Humphrey GPA Glaucoma Progression Analysis software identifies clinically significant progression automatically. Pattern Deviation Plots identify localized field loss typical of glaucoma, minimizing ocular media effects such as cataracts.
GPA – Advancing the Science of progression analysis
The Humphrey Field Analyzer Guided Progression Analysis™ (GPA™) software differentiates statistically significant progression of visual field loss from random variability. The analysis is based upon detailed empirical knowledge of the variability found at various stages of glaucomatous visual field loss through information acquired in extensive multi-center clinical trials worldwide.
Baseline Examinations
Establish initial visual field status
Visual Field Index Value
A summary measurement of the patient’s visual field status, expressed as a percent of a normal age-adjusted visual field
VFI Rate of Progression Analysis
Trend analysis of the patient’s overall visual field history1
VFI Plot
Regression analysis of VFI values and 3 to 5 year projection
VFI Bar
A graphical depiction of the patient’s remaining useful vision at the current VFI value along with a 3 to 5 year projection of the VFI regression line if the current trend continues
Current Visual Field Summary
Complete report of current visual field including VFI, MD, PSD, the Progression Analysis Plot and the GPA alert
GPA Alert
A message that indicates whether statistically significant deterioration was noted in consecutive tests.
FEATURES:
- Threshold Visual Fields in as Little as 2 Minutes
SITA sensitivity, reproducibility & accuracy has been shown in clinical testing when using the Zeiss 750i Perimeter
- DIAGNOSTIC PRECISION:
STATPAC 2 - Single & Multiple Field Analysis, as well as STATPAC for Blue & Yellow are standard features on the Zeiss 750i Perimeter. STATPAC, the language of perimetry, compares results to proprietary age normative and glaucoma databases
- IMPROVED RELIABILITY:
The Zeiss 750i Perimeter also offers patented fixation monitoring including, Krakau Blind Spot Monitoring, Video Eye Monitor, Gaze Tracking, Head Tracking, Lens tracking and Remote Video Eye Monitor capability
Social Security Disability testing, Monocular, Binocular, Kinetic Testing and Custom Testing are standard features on the Zeiss Humphrey 750i, providing the widest range of testing protocols on any perimeter
- EARLY GLAUCOMA DETSCTION:
The Zeiss 750i, 750, 745i, and 745 Perimeters all offer SITA-SWAP software, which reduces blue-yellow threshold test time to just 4-6 minutes, providing a clinically practical tool for early detection of glaucoma. The SITA-SWAP software is standard on the Zeiss 750i Perimeter, and the Zeiss 745i Perimeter, and available as an option on the Zeiss 750 Perimeter, and the Zeiss 745 Perimeter
- OPERATOR FRIENDLY & PATIENT FRIENDLY:
The Zeiss 750i Perimeter offers a touch screen, featuring on-screen menus to simplify and expedite instrument operations. The Zeiss 750i Perimeter is also wheelchair accessible and an ergonomic design allows maximum comfort for all patient body types
The Zeiss 750i, 745i, 740i, and the 720i Perimeters include networking software which automates Visual Field Analysis by connecting directly to your office information system.
Touch-screen and menu-driven interface simplifies operation. The Zeiss 750i Perimeter offers agronomic design for maximum comfort, access and versatility.
- COMPLETE ARCHIVING SYSTEM:
The Humphrey Field Analyzer II 'i' Series including the Zeiss 750i, 745i, 740i, and the 720i, all contain a hard drive, and Magneto-optical drive.
Contact us for additional information.
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Validated by more than 25 years of research, design and clinical experience, the Humphrey Field Analyzer (HFA) is the accepted standard of care in glaucoma diagnosis and management. With over 65,000 installed units worldwide, the HFA is the premier automated visual field analyzer. Humphrey field analyser (HFA), 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(s) throughout the visual pathway.
The Humphrey Field Analyzer (HFA, Carl Zeiss Meditec, Dublin, CA, USA) is commonly used to monitor Humphrey Field Analyzer II-i Series, User Manual. For more than 30 years, the.
Humphrey field analyser (HFA), is a tool for measuring the human visual field, it is used by optometrists, orthoptists and ophthalmologists, particularly for detecting monocular visual field.[1]
The results of the Analyser identify the type of vision defect. Therefore, it provides information regarding the location of any disease processes or lesion(s) 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.[2]
- 2Method of assessment
- 3Interpreting results
- 3.2Plots
- 4Advantages and Disadvantages
Medical uses[edit]
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.[3] They include:
- 10-2: Measures 10 degrees temporally and nasally and tests 68 points. Used for macula, retinal and neuro-ophthalmic conditions and advanced glaucoma[4]
- 24-2: Measures 24 degrees temporally and 30 degrees nasally and tests 54 points. Used for neuro-ophthalmic conditions and general screening[5] as well as early detection of glaucoma[6][7]
- 30-2: Measures 30 degrees temporally and nasally and tests 76 points. Used for general screening, early glaucoma and neurological conditions[6]
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[8][9]
There are additional tests for more specific purposes such as the following:
- Esterman – Used to test the functionality of a patient's vision to ensure they are safe to drive, as requested by VicRoads, Australia[10][11]
- SITA SWAP: Short Wavelength Automated Perimetry (SWAP) is used for detection of early glaucomatous loss[5]
Method of assessment[edit]
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 (either spherical and/or cylindrical), 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 (see Fixation Targets for advice).[12]
Find out driving essentials such as the location and explanation of controls, safety tips, specifications and capacities, and sometimes scheduled maintenance. With step-by-step instructions, clear pictures, fluid capacities and specifications, you will have the information you need to get the most from your vehicle. This book is a supplement to the main owner's manual for your vehicle covering diesel engine. 2011 ford f 250 user manual. Your owner's manual is designed by experts to keep you informed. You will need both for complete information.Owner's Manuals explain the operation and care of your vehicle.
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.[12]
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 (see Disadvantages for possible artefacts).
It is important for the patient to blink normally, relax and maintain concentration throughout the test. This will increase the reliability of results.[12]
How it works[edit]
The Analyser projects a series of white light stimuli of varying intensities (brightness), 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' (dB).[1]
The Analyser currently utilises the Swedish Interactive Thresholding Algorithm (SITA); 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.[8]
Fixation targets[edit]
There are different targets a patient can fixate on during the test. They are chosen on the basis of the patient's conditions.[12]
- Central target: Yellow light in the bowl's centre
- Small diamond: For patients who cannot see the central target such as those with macular degeneration. The patient looks into the centre of the four lights
- Large diamond: For patients who cannot see the above two[12]
Interpreting results[edit]
Reliability indices[edit]
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 (Fig. 4). These are assessed first and allow the examiner to determine if the end results are reliable. These indices include:
- Fixation Losses: Recorded when a patient responds to a stimulus that is projected on to area of their blind spot. Fixation losses exceeding 20%, are denoted with an 'XX' next to the score, and deems results unreliable[12]
- False Positives: Recorded when a patient responds when there is no stimulus present. This patient is often referred to as 'buzzer happy'. False positives exceeding 15% are denoted with an 'XX' and results are considered unreliable. This may indicate that the patient is anxious and concerned about missing targets[12]
- False Negatives:Recorded when a patient does not respond to brighter stimuli where a duller stimulus has already been seen. High false negative scores indicate that the patient is fatigued, inattentive, a malingerer or has genuine significant visual field loss.[12] Literature presents various percentages regarding reliability. However, majority of the literature defines that false negatives exceeding approximately 30% deem results unreliable.[13][14][15]
Plots[edit]
1: Reliability Indices
2: Numerical Display
3: Grey Scale
4: Total Deviation
5: Probability Display
6: Pattern Deviation
7: Global Indices
8: Glaucoma Hemifield Test
9: Visual Field Index
After reliability is determined, the remaining data is assessed.
Numerical Display[edit]
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.[16]
Grey Scale[edit]
Zeiss Humphrey Visual Field 3 Manual
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.[3] This scale is used to demonstrate vision changes to the patient but is not used for diagnostic purposes.
pattern Deviation[edit]
The numerical total demonstrates the difference between measured values and population age-norm values at specific retinal points.[3]
- Negative values indicate lower than normal sensitivity
- Positive indicates higher
- 0 equals no change[3]
The statistical display (located below the numerical total) 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.[3] 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 (i.e. the total departure from the age-norm).[17]
total Deviation[edit]
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 (e.g. cataract), uncorrected refractive error, reductions in sensitivity due to age and pupil miosis. This highlights focal loss only (i.e. vision loss suspected from only pathological processes).[16] 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[edit]
A: Central scotoma
B: Centrocaecal scotoma
C: Nasal Step
D: Superior Arcuate
E: Nasal Wedge defect
F: Superior Nasal quadrantanopia
G: Superior Altitudinal
H: Nasal hemianopia
I: Enlarged Blind Spot with Paracentral scotoma located 15 degrees superiorly
These provide a statistical summary of the field with one number. Although not used for initial diagnosis, they are essential for monitoring glaucoma progression.[3] They include:
- Mean Deviation (MD): Derived from the Total Deviation and represents the overall mean departure from the age-corrected norm.[18] A negative value indicates field loss, while a positive value indicates that the field is above average. A P value is provided if the global indices are abnormal. It provides a statistical representation of the population. For example, P <2% means that less than 2% of the population have vision loss worse than measured[19]
- Pattern Standard Deviation (PSD): Derived from the Pattern Deviation and thus highlights focal loss only. A high PSD, indicating irregular vision, is therefore a more useful indicator of glaucomatous progression, than the MD[3]
Glaucoma Hemifield Test (GHT)[edit]
The Glaucoma Hemifield Test (GHT) 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.[3][20] The result of either 'Outside Normal Limits' (significant difference in superior and inferior fields), 'Borderline' (suspicious differences) or 'Within Normal Limits' (no differences) is only considered when the patient has, or is a suspect for, glaucoma.[20] This is only available in 30-2 and 24-2 Analyser protocol.[3]
Visual Field Index (VFI)[edit]
The VFI reflects retinal ganglion cell loss and function, as a percentage, with central points weighted more.[21]
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 (or total deviation probability plot when MD is worse than -20 dB) 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.[22]
Zeiss Humphrey Field Analyzer User Manual
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[edit]
Advantages[edit]
- Provides a comprehensive visual field assessment and ensures reliable results[12]
- Compares patient's data to age-matched populations[12]
- Distinguishes focal from diffuse vision loss[12]
- Figure 6 - Artefacts (right eye)Can be used for patients who are wheelchair users, hearing impaired, have postural and fixation problems and/or very low visual acuity[12]
A: Aphakia
B: Rim artefact
C: Chin slip
D: Lens position
E: Corneal opacity
F: Keratoconus
G: Ptosis
H: Pupil Miosis - 1mm
I: Pupil Miosis - 3mm - Provides a baseline measurement
- Simple for the examiner to perform and interpret
Disadvantages[edit]
- Requires a higher level of patient understanding and concentration compared to other visual field tests[9]
- Time-consuming
- Learning effect: new patients improve as more tests are performed due to understanding of the test conditions. Consider the third test as the baseline result[23]
- Potential for artefacts (i.e. uncharacteristic vision loss) (fig. 6). Below is a list of possible artefacts and a representation of how they may appear. These can however, be managed with correct patient setup.
- Uncorrected refractive error and aphakia cause significant decrease in visual field sensitivity[3]
- Rim of trial frame can simulate glaucomatous loss[24]
- Media opacities and keratoconus cause decreased sensitivity[3]
- Ptosis cause superior visual field loss[3]
- Miosis cause decreased peripheral sensitivity[3]
See also[edit]
References[edit]
- ^ abLanders, John; Sharma, Alok; Goldberg, Ivan; Graham, Stuart L (February 2010). 'A comparison of visual field sensitivities between the Medmont automated perimeter and the Humphrey field analyzer'. Clinical & Experimental Ophthalmology. doi:10.1111/j.1442-9071.2010.02246.x. PMID20447123.
- ^Kedar, Sachin; Ghate, Deepta; Corbett, JamesJ (2011). 'Visual fields in neuro-ophthalmology'. Indian Journal of Ophthalmology. 59 (2): 103–109. doi:10.4103/0301-4738.77013. PMC3116538. PMID21350279.
- ^ abcdefghijklmKanski, J. J.; Bowling, B. (2011). Clinical Ophthalmology. Edinburgh: Elsevier Saunders.
- ^Asaoka, Ryo; Vavvas, Demetrios (20 June 2014). 'Mapping Glaucoma Patients' 30-2 and 10-2 Visual Fields Reveals Clusters of Test Points Damaged in the 10-2 Grid That Are Not Sampled in the Sparse 30-2 Grid'. PLoS ONE. 9 (6): e98525. doi:10.1371/journal.pone.0098525. PMC4064971. PMID24950300.
- ^ abKhoury, Johnny, M.; Donahue, Sean, P.; Lavin, Patric, J.; Tsai, James (1999). 'Comparison of 24-2 and 30-2 Perimetry in Glaucomatous and Nonglaucomatous Optic Neuropathies'. Journal of Neuro-Ophthalmology. 19 (2): 100–108. doi:10.1097/00041327-199906000-00004.
- ^ abNouri-Mahdavi, Kouros (December 2014). 'Selecting visual field tests and assessing visual field deterioration in glaucoma'. Canadian Journal of Ophthalmology. 49 (6): 497–505. doi:10.1016/j.jcjo.2014.10.002.
- ^Huang, Charles Q.; Carolan, James; Redline, Daniel; Taravati, Parisa; Woodward, Kimberly R.; Johnson, Chris A.; Wall, Michael; Keltner, John L. (1 March 2008). 'Humphrey Matrix Perimetry in Optic Nerve and Chiasmal Disorders: Comparison with Humphrey SITA Standard 24-2'. Investigative Ophthalmology & Visual Science. 49 (3): 917–23. doi:10.1167/iovs.07-0241. PMID18326712.
- ^ abBengtsson, Boel; Olsson, Jonny; Heijl, Anders; Rootzén, Holger (27 May 2009). 'A new generation of algorithms for computerized threshold perimetry, SITA'. Acta Ophthalmologica Scandinavica. 75 (4): 368–375. doi:10.1111/j.1600-0420.1997.tb00392.x.
- ^ abSzatmáry, Gabriella (1 September 2002). 'Can Swedish Interactive Thresholding Algorithm Fast Perimetry Be Used as an Alternative to Goldmann Perimetry in Neuro-ophthalmic Practice?'. Archives of Ophthalmology. 120 (9): 1162. doi:10.1001/archopht.120.9.1162.
- ^'Vic Driving Vision Standards'. Optometry Australia. Optometry Australia. Archived from the original on 2016-04-18.
- ^'Visual impairment'. VicRoads. State Government of Victoria. 2015. Archived from the original on 2019-02-28.
- ^ abcdefghijklArtes, Paul H (2012). Humphrey Field Analyzer II-i series User Manual. Carl Zeiss Meditec.
- ^Bengtsson, B; Heijl, A (2000). 'False-negative responses in glaucoma perimetry: indicators of patient performance or test reliability?'. Investigative Ophthalmology and Visual Science. 41 (8): 2201–2204.
- ^McKendrick, Allison M.; Denniss, Jonathan; Turpin, Andrew (August 2014). 'Response times across the visual field: Empirical observations and application to threshold determination'. Vision Research. 101: 1–10. doi:10.1016/j.visres.2014.04.013. PMID24802595.
- ^Johnson, Chris A; Keltner, John L; Cello, Kimberly E; Edwards, Mary; Kass, Michael A; Gordon, Mae O; Budenz, Donald L; Gaasterland, Douglas E; Werner, Elliot (March 2002). 'Baseline visual field characteristics in the ocular hypertension treatment study'. Ophthalmology. 109 (3): 432–437. doi:10.1016/S0161-6420(01)00948-4.
- ^ abWyatt, Harry J.; Dul, Mitchell W.; Swanson, William H. (March 2007). 'Variability of visual field measurements is correlated with the gradient of visual sensitivity'. Vision Research. 47 (7): 925–936. doi:10.1016/j.visres.2006.12.012. PMC2094527. PMID17320924.
- ^Cubbidge, R (2012). 'Essentials of visual field assessment'. The Optician. 243 (6356): 14–16. ProQuest1027770159.
- ^Chen, Yi-Hao; Wu, Jian-Nan; Chen, Jiann-Torng; Lu, Da-Wen (2008). 'Comparison of the Humphrey Field Analyser and Humphrey Matrix Perimeter for the Evaluation of Glaucoma Patients'. Ophthalmologica. 222 (6): 400–407. doi:10.1159/000154203.
- ^Stamper, Robert L; Lieberman, Marc F; Drake, Michael V (2009). Becker-Shaffer's diagnosis and therapy of the glaucomas (8th ed.). [Edinburgh]: Mosby/Elsevier. ISBN978-0-323-02394-8.
- ^ abIshiyama, Y.; Murata, H.; Mayama, C.; Asaoka, R. (11 November 2014). 'An Objective Evaluation of Gaze Tracking in Humphrey Perimetry and the Relation With the Reproducibility of Visual Fields: A Pilot Study in Glaucoma'. Investigative Ophthalmology & Visual Science. 55 (12): 8149–8152. doi:10.1167/iovs.14-15541. PMID25389198.
- ^Horton, M. (2015). '10 tips for improving visual fields: perimetry may seem like second nature, but these recommendations can help you obtain better results by refining your understanding of the technology'. Review of Optometry. 152 (4): 62.
- ^Kuzhuppilly N, Patil S, Dev S, Deo A. Reliability of Visual Field Index in Staging Glaucomatous Visual Field Damage. Journal of Clinical & Diagnostic Research. 2018 Jun 1;12(6): NC05-NC08
- ^Saigal, Rahul. 'Learning Effects and Artefacts in Automated Perimetry'(PDF). Association Of Optometry Ireland.
- ^Donahue, Sean. P. (1998). 'Lens Holder Artifact Simulating Glaucomatous Defect in Automated Perimetry'. JAMA Ophthalmology. 116 (12): 1681–1683. doi:10.1001/archopht.116.12.1681. PMID9869806.