BACKGROUND: Multifocal pupillographic objective perimetry was compared using 24 and 44 regions per visual field. DESIGN: Experimental design in a university setting. PARTICIPANTS: Twenty-seven normal control and 36 age-matched glaucoma patients. METHODS: The four test variants differed in the mean interval between stimuli: 4, 1 or 0.25 s; and the number of visual field regions tested within the central 60 degrees: 24 or 44. All subjects had their diagnostic status confirmed by optical coherence tomography, two forms of perimetry and slit-lamp biomicroscopy. Both eyes were measured concurrently in 2.73 ± 0.45 min/eye (mean ± standard deviation), and tests were repeated about 2 weeks apart. MAIN OUTCOME MEASURES: The main outcome measures were: (i) mean change in light sensitivity due glaucoma; and (ii) areas under Receiver Operator Characteristic plots for detecting glaucoma. RESULTS: For all four variants, consensual responses, female gender and age produced small but significant sensitivity differences, and sensitivity declined with age by ≤-0.27 dB/decade (all P < 0.0003). The best diagnostic accuracy (area under curve 93.2 ± 3.89%) was produced by the one-presentation/s 44-region protocol. Across the four protocols, the effect of repeat testing was small (all methods ≤0.15 dB). CONCLUSIONS: Presentation rate had little effect, but increasing the tested density from 24 to 44 regions/field improved diagnostic power. Given that multifocal pupillographic objective perimetry also provides information on response delay and afferent versus efferent defects at every visual field region, it may be a useful adjunct to perimetry.
BACKGROUND: Multifocal pupillographic objective perimetry was compared using 24 and 44 regions per visual field. DESIGN: Experimental design in a university setting. PARTICIPANTS: Twenty-seven normal control and 36 age-matched glaucomapatients. METHODS: The four test variants differed in the mean interval between stimuli: 4, 1 or 0.25 s; and the number of visual field regions tested within the central 60 degrees: 24 or 44. All subjects had their diagnostic status confirmed by optical coherence tomography, two forms of perimetry and slit-lamp biomicroscopy. Both eyes were measured concurrently in 2.73 ± 0.45 min/eye (mean ± standard deviation), and tests were repeated about 2 weeks apart. MAIN OUTCOME MEASURES: The main outcome measures were: (i) mean change in light sensitivity due glaucoma; and (ii) areas under Receiver Operator Characteristic plots for detecting glaucoma. RESULTS: For all four variants, consensual responses, female gender and age produced small but significant sensitivity differences, and sensitivity declined with age by ≤-0.27 dB/decade (all P < 0.0003). The best diagnostic accuracy (area under curve 93.2 ± 3.89%) was produced by the one-presentation/s 44-region protocol. Across the four protocols, the effect of repeat testing was small (all methods ≤0.15 dB). CONCLUSIONS: Presentation rate had little effect, but increasing the tested density from 24 to 44 regions/field improved diagnostic power. Given that multifocal pupillographic objective perimetry also provides information on response delay and afferent versus efferent defects at every visual field region, it may be a useful adjunct to perimetry.
Authors: Marnix Naber; Carlien Roelofzen; Alessio Fracasso; Douwe P Bergsma; Mies van Genderen; Giorgio L Porro; Serge O Dumoulin Journal: Front Neurol Date: 2018-07-10 Impact factor: 4.003
Authors: Corinne F Carle; Andrew C James; Faran Sabeti; Maria Kolic; Rohan W Essex; Chris Shean; Rhiannon Jeans; Aiasha Saikal; Alice Licinio; Ted Maddess Journal: Transl Vis Sci Technol Date: 2022-02-01 Impact factor: 3.283