Twenty participants with open-angle glaucoma (OAG; mean age, 63.1 years; range, 48–80 years) and 15 healthy control participants (mean age, 64.1 years; range, 40–81 years) were recruited for this study. Healthy control participants were examined as part the accompanying study,³⁰ with the same inclusion and exclusion criteria applied here. Healthy participants were recruited and tested at Moorfields Eye Hospital (MEH; London, UK, n = 12) or the University of Ulster, Coleraine (UUC, n = 3). All healthy participants had a visual acuity of 20/30 (6/9) or better in the test eye, normal IOP (≥11 and ≤21 mm Hg), and optical coherence tomograph (OCT) peripapillary retinal nerve fiber layer (RNFL) within normal limits (Spectralis; Heidelberg Engineering GmbH, Heidelberg, Germany). Glaucoma patients were recruited and tested at MEH. Of the patients recruited, 19 had been diagnosed previously with primary OAG, and one with pigment dispersion glaucoma. All glaucoma patients had a corrected visual acuity of 20/30 (6/9) or better in the test eye. Spherical refractive error was within ± 6.00 diopter sphere (DS) in any meridian with astigmatism less than 3.00 diopter cylinder (DC). There were no significant media opacities or concurrent ocular pathology in any subject, as determined by slit-lamp assessment of the anterior eye and dilated biomicroscopic assessment of the posterior segment. Spectralis OCT peripapillary RNFL thickness was outside normal limits in at least one sector in all patients. Visual fields were examined using the 24-2 SITA standard test on the Humphrey visual field analyzer (Carl Zeiss Meditec, Dublin, CA, USA). Mean MD was −3.33 dB (range, −0.12 to −12.2) and mean PSD was 4.80 dB (range, 1.59–14.2 dB). 

Ethical approval for this work was given by the London-Central National Research Ethics Service committee and the University of Ulster Biomedical Sciences Research Ethics Committee. The research protocol adhered to the tenets of the Declaration of Helsinki. 

Stimuli were presented on a γ-corrected 21-inch Phillips FIMI MGD-403 achromatic CRT monitor (pixel resolution of 976 × 1028, frame rate 121 Hz, MEH site; Ampronix, Irvine, CA, USA) or a γ-corrected 21-inch Sony GSM F500-PST CRT monitor (pixel resolution of 640 × 480, frame rate 120 Hz, UUC site; Sony Corp., Tokyo, Japan) using a ViSaGe MKII stimulus generator (Cambridge Research Systems, Rochester, UK) and the CRS toolbox (version 1.27) for MATLAB (version R2011a; The MathWorks, Inc., Natick, MA, USA). A background luminance of 10 cd/m² was used for all tests. Before the start of each experiment the CRT display was permitted a 1-hour warm-up time. 

Data collection in this study was split into two phases. In the first phase, an area-threshold that was intended to be smaller than Ricco's area by a defined amount (0.20 log deg²) in each subject was generated for test locations at 8.8° eccentricity along the 45°, 135°, 225°, and 315° meridians of the visual field. To achieve this, circular stimuli of fixed duration (191.9 ms) and luminance (ΔI = 5.3 cd/m², log ΔI/I = −0.3) but varying in area, were presented. Stimulus area was modulated in line with subject responses to estimate threshold area. It was assumed that the area of this threshold stimulus was slightly smaller than Ricco's area in both groups since the luminance used was greater than the approximate threshold expected for a stimulus equal to Ricco's area (ΔI 3.3 cd/m², log ΔI/I −0.5; Mulholland et al. IOVS 2013;54:ARVO E-Abstract 3924).^14,16,31 As the average spatial summation function for glaucoma patients was simply translated across the size-axis, when compared to healthy age-similar control subjects,¹⁶ an area-modulation paradigm with a stimulus of constant luminance was deemed to be an appropriate and efficient method to gain an estimate of Ricco's area for the purposes of this study. A stimulus smaller than Ricco's area was desired to ensure that complete spatial summation was exhibited for all stimulus presentation durations in this study (phase 2). 

In the second phase of the experiment, achromatic temporal summation functions were measured at the same test locations using a near-GIII stimulus (0.48° diameter) and the Ricco's area-scaled stimuli from phase one. For healthy observers, contrast thresholds collected for a near-GIII stimulus in the accompanying study³⁰ were used. To construct each summation function, contrast thresholds were measured for seven stimuli of different duration (1–24 frames, 1.8–191.9 ms) within separate test runs. The order of the stimuli tested (i.e., duration and area combinations) was chosen at random. Regular rest periods were provided at intervals throughout each data collection session and when requested by the subject. 

Area (phase one) and contrast (phase two) thresholds were estimated using a randomly interleaved 1/1 staircase with a Yes/No response paradigm. Each staircase terminated after six reversals, with threshold being calculated as the mean of the final four reversal values. In phase one, stimulus area was varied by 10% up to 3 reversals. Once 3 reversals were exceeded, area was varied by 5%. In phase 2, stimulus contrast varied by 0.05 log units (0.5 dB), following each response. The false-positive rate was monitored through the presentation of stimuli with 0% contrast. If the false-positive rate was greater than 20% in any run, those data were discarded and the test run was repeated. Before undertaking each phase of the experiment, a trial run was provided to each participant. Only when it was clear that the subject understood the test fully were study measurements performed. 

For the purposes of statistical analysis, mean threshold area values (Ricco's area estimates) were calculated for the superior and inferior hemifield in each subject.¹⁶ A Mann-Whitney U test then was used to examine for statistically significant differences in area thresholds between glaucoma patients and healthy observers in each hemifield. Individual area thresholds for glaucoma patients were also grouped according to total deviation (TD) values (from SAP) to investigate the association between spatial summation and local visual field depression. As each test location used in this study did not lie exactly on any test point on the Humphrey 24-2 (SAP) test grid, TD values were estimated as a mean of TD values for the four locations surrounding 8.8° (Fig. 1). Before this calculation individual TD values were first converted to linear units (TD_Lin, Equation 1), with the mean TD_Lin value then converted back to dB units (Equation 2).     

Ricco's area estimates then were grouped into one of five strata (TD ≥ 0, −1 ≤ TD < 0, −2 ≤ TD < −1, −3 ≤ TD < −2 and TD < −3). A Kruskal-Wallis test (and post hoc Mann-Whitney U tests as appropriate) was applied to test for a statistically significant difference in threshold area with changes in localized visual field depression. 

Contrast thresholds and stimulus durations were expressed using identical metrics to those used in the accompanying study³⁰ (i.e., contrast energy values calculated as the product of stimulus increment luminance, duration in s and area in deg², and stimulus durations as Bridgeman equivalents in s incorporating known phosphor persistence values for the P45 phosphor incorporated in the Phillips FIMI display³²). Should the contrast required at threshold for a given location exceed the maximum for the display monitor being used (i.e., ceiling effect), data from that location were excluded from further analysis. The critical duration was estimated for each suitable test location using iterative two-phase regression analysis. Briefly, this analysis attempts to fit two lines to the data set. The slope of the first line is constrained to zero in line with Bloch's law (constant energy at threshold), with the slope of the second line, in addition to the point at which the two constituent lines intersect (breakpoint), free to vary. The intersection point, in each case, was taken to be the critical duration estimate. If the bilinear fit failed, due to variability within the data set, or produced critical duration estimates less than the duration of the shortest stimulus (1 frame, 1.8 ms), those data were excluded from further analysis. If a critical duration value greater than the longest stimulus duration (24 frames, 191.9 ms) were estimated, a value of 191.9 ms (2.28 log ms) was allocated for later analysis. The total number of successful critical duration estimates is reported in the results. 

Mean critical duration values were calculated for the superior and inferior hemifield of each subject. Where data were excluded from a given location, the critical duration from the one remaining test location in the hemifield was taken to be the critical duration for that hemifield. A Mann-Whitney U test was used to test for a statistically significant difference (P < 0.05) in critical duration values between glaucoma patients and healthy observers. The association between the critical duration and localized visual field depression in glaucoma patients was investigated in a manner identical to that described above with spatial summation data (i.e., critical duration values were grouped according to mean local TD values and a Kruskal-Wallis test was undertaken). 

In agreement with previous studies,^16,17 we found estimates of Ricco's area (median, interquartile range [IQR]) to be larger in glaucoma subjects (superior, 0.19 deg²; IQR, 0.09–0.85; inferior, 0.10 deg²; IQR, 0.08–0.20) than in healthy observers (superior, 0.06 deg²; IQR, 0.04–0.08; inferior, 0.05 deg²; IQR, 0.04–0.10). This difference was statistically significant (Mann-Whitney U test; superior, P < 0.001; inferior, P = 0.01). When estimates of Ricco's area at each test location were divided into strata according to pointwise TD values in glaucoma subjects, a trend of increasing area threshold values was observed with increasing visual field depression (Fig. 2). This change was statistically significant (Kruskal-Wallis, P < 0.001). Post hoc analysis with Bonferroni correction revealed a statistically significant difference (P < 0.001) between the TD ≥ 0 group (median, 0.08 deg²; IQR, 0.04–0.09) and the TD < −3 group (median, 0.83 deg²; IQR, 0.29–3.98). Those test locations with TD values ≥ −3 also displayed size thresholds significantly smaller than those locations with TD < −3. There was no statistically significant difference between Ricco's area estimates in healthy observers (median, 0.06 deg²; IQR, 0.04–0.09) and those from locations in glaucoma patients with TD ≥ 0 (P = 0.33). 

Energy thresholds were significantly higher in the glaucoma group than in the age-similar healthy control group with the near-GIII stimulus (P < 0.001 for stimulus durations < 191.9 ms and P = 0.01 for 191.9 ms duration) and Ricco's area-scaled stimuli (P < 0.001 for all stimulus durations). Boxplots of threshold estimates for each stimulus duration, along with temporal summation functions estimated with two-phase regression analysis of across-subject median values, are shown in Figure 3. In these plots, it can be seen that the critical duration is longer in the glaucoma group, with the near-GIII and Ricco's area scaled stimuli. When thresholds were expressed in terms of luminance, the contrast at threshold (log ΔI/I) for a target scaled to Ricco's area and duration 24 frames (191.9 ms), was similar in the healthy (median, −0.24; IQR, −0.31 to −0.14) and glaucoma groups (median, −0.24; IQR, −0.34 to −0.19), as would be expected from the results of Redmond et al.¹⁶ For the shortest duration stimulus (1 frame, 1.8 ms) luminance contrast thresholds were comparatively higher (i.e., reduced sensitivity) in the glaucoma group (median, 0.96; IQR, 0.74–1.13) relative to healthy controls (median, 0.70; IQR, 0.61–0.84) for the scaled stimulus. 

A total of 140 local temporal summation measurements (60 in healthy observers, 80 in glaucoma subjects) was made using the near-GIII and Ricco's area scaled stimuli. In healthy observers, 58 temporal summation data sets measured with the near-GIII stimulus, and 57 with the Ricco's area scaled stimuli, were successfully fitted. In glaucoma subjects, 57 and 70 temporal summation functions were determined for data collected with near-GIII and Ricco's area scaled stimuli, respectively. The median critical duration was significantly longer in the glaucoma group for the near-GIII (superior [P = 0.01], 77.6 ms; IQR, 32.4–158.5; inferior [P < 0.001], 104.7 ms; IQR, 77.6–162.2) and Ricco's area scaled stimuli (superior [P = 0.001], 93.3 ms; IQR, 56.2–123.0; inferior [P = 0.007], 89.1 ms; IQR, 66.1–158.5) compared to that in healthy subjects (GIII superior, 35.4 ms; IQR, 21.4–48.9; inferior, 34.6 ms; IQR, 19.5–47.9; Ricco's area scaled superior 33.1 ms; IQR, 23.4–49.0; inferior, 53.7 ms; IQR, 30.2–72.4). 

Individual critical duration values grouped according to local TD values can be seen in Figure 4. A statistically significant difference was observed between the critical durations in the healthy control group and those estimated at locations in glaucoma patients with TD values greater than or equal to 0 dB for the near-GIII stimulus (P = 0.02). No statistically significant difference was observed when critical duration values for the Ricco's area scaled stimulus were compared in the healthy and glaucoma TD ≥ 0 dB groups (P = 0.13). All other strata with a mean TD less than or equal to −1 dB displayed critical duration values that were statistically significantly longer than those in healthy observers, when a near-GIII stimulus was used (all P ≤ 0.05). A statistically significant increase in the critical duration also was observed in glaucoma patients at locations with TD values −1 ≤ TD < 0 (P = 0.002), −3 ≤ TD < −2 (P = 0.02), and < −3 (P < 0.001) for Ricco's area scaled stimuli relative to estimates in healthy controls. Despite the median critical duration for the −2 ≤ TD < −1 group being higher than the healthy control group the difference between these strata did not reach statistical significance for the scaled stimulus (P = 0.21). Among glaucoma patients, an increase in the critical duration is evident between locations with TD values ≥ 0 dB (GIII, 70.8 ms; IQR, 30.9–190.5; Ricco's area scaled, 55.0 ms; IQR, 34.7–100.0) and < −3 dB (GIII, 151.4 ms; IQR, 75.9–186.2; Ricco's area scaled, 128.8 ms; IQR, 74.1–182.0). This difference, although present for both stimuli used, failed to reach statistical significance over the range of TD values in this study (Kruskal-Wallis, near-GIII, P = 0.49; scaled stimulus, P = 0.09). 

To our knowledge, this is the first study demonstrating an increase in the critical duration in glaucoma. Statistically significant increases were found when measured with a near-GIII stimulus (0.48° diameter) and a stimulus scaled according to local spatial summation, under the same background and other stimulus conditions as used in SAP. In accordance with previous studies,^16,17 we confirm Ricco's area, estimated through an area-modulation test for a stimulus of constant luminance and duration 191.9 ms (24 frames), is larger in patients with early glaucoma. 

The results of this study appear to contradict those reported in earlier work investigating temporal summation using similar achromatic stimuli.^21–23 However, variations in experimental methodology, test equipment and, perhaps most importantly, analysis techniques used to estimate the critical duration, confound comparison. For example, Dannheim and Drance²¹ used a stimulus (0.75° diameter) much larger than most stimuli used in our experiment. In the same study, “control” data were collected from glaucoma subjects, in regions of the visual field where no defect was apparent with either kinetic or static profile perimetry. Other studies have used analysis methods that potentially can overestimate the critical duration.⁸ For example, Funkhouser and Fankhauser²² and Ogawa et al.²³ estimated the critical duration by fitting a bilinear function that assumed complete and then no summation. As a result, it is possible that small changes in the critical duration may have been overlooked in these studies.⁸ In the current study, it was only assumed that there is a duration below which complete summation took place; the slope and intercept of the second line, together with the breakpoint, in the bilinear fit were free to vary. 

The effect of glaucoma on temporal summation also may be seen if one considers the threshold contrast energy values for stimuli of varying duration. When Bloch's law is satisfied, and summation complete, energy at threshold remains constant. Thus, should the critical duration increase, the range of stimulus durations for which energy remains constant at threshold would also be expected to extend. This is seen in Figure 3 where complete summation is evident for a larger range of stimulus durations in glaucoma patients compared to healthy control subjects. This result supports the findings of Homlin and Krakau²⁵ and Hnik et al.²⁷ It also is interesting to note that when temporal summation is complete, contrast energy at threshold does not appear to alter greatly with changes in stimulus area for either the healthy (log ΔE = ∼−1.50) or glaucoma (log ΔE = ∼−1.00) groups (Fig. 3). 

The results of this study pose important questions about the nature of visual processing in glaucoma: Why does summation increase, and what is the physiological source of this change? To answer such questions tentatively, one must first consider summation in the healthy visual system and the various factors that can influence the critical duration and extent of Ricco's area. For example, Ricco's area and critical duration can vary with background illumination^11,13 and visual field locus (Ref. 14 and Mulholland P, et al. IOVS 2013;54:ARVO E-Abstract 3924). It may be argued that such changes occur to maintain a constant signal-to-noise ratio, and thus constant sensitivity or detectability (d'), in a range of visual environments.¹¹ In glaucoma, such changes also might occur to maintain d' at a constant level, to compensate for RGC loss, at the expense of spatial and temporal resolution. This hypothesis has been put forward previously by Krakau²⁶ and Redmond et al.¹⁶ as a possible explanation for increasing summation in glaucoma. Krakau²⁶ proposed that an increase in temporal summation might be explained by a reduction in the number of RGCs or available “channels.” Redmond et al.¹⁶ suggested Ricco's area might enlarge to boost the signal being delivered to higher visual centers with the result that d' remains constant. 

The physiological basis of the critical duration remains a matter of significant debate in published literature. It is likely that photoreceptors,^33–35 RGCs^36,37 and higher visual areas^15,38 each have a role, either independently or together with other structures,³⁹ in determining the critical duration. In the case of glaucoma, it generally is accepted that RGCs are the primary cells affected in the disease.^40,41 Ricco's area has been found to be larger in individuals with glaucomatous damage, possibly occurring through either an active reorganization of retinal or other neurons of the visual pathway leading to a wider convergence of RGCs on cortical cells,⁴² or detection becoming mediated by already present cortical receptive fields/filters of greater spatial extent to maintain input from a constant number of RGCs in the absence of any neural reorganization.^16,31,43 Given the intrinsic link between spatial and temporal summation,^11,28,29 and considering spatial summation changes in glaucoma,^16,17 it is entirely possible that temporal summation also will be affected. Interestingly, we also observed a statistically significant increase in the critical duration in glaucoma patients relative to healthy controls when examined using stimuli scaled to reflect localized spatial summation. Here, we might expect the functional consequences of changes in RGC density to be, at least in part, compensated for through scaling stimulus area.¹⁶ Considering this, it is possible that RGC function is disturbed before, or in tandem with, structural damage in optic neuropathy,⁴⁴ leading to changes in temporal summation over and above those explained by a change in spatial summation. It has been shown in animal models that before apoptotic cell death, RGCs undergo shrinkage^45,46 with a reduction in dendritic arborisations,⁴⁷ resulting in reduced synaptic integrity.⁴⁸ Functional anomalies have been attributed to such changes.^48,49 On this basis, it is reasonable to hypothesize that premorbid dysfunction in RGCs,⁴⁴ in addition to cell death, may partially explain our findings. 

Although generally thought of as a disease altering RGC function and density, glaucoma is increasingly considered a neurodegenerative disorder influencing the entire visual pathway, including the structure^50–55 and function⁵⁶ of higher visual centers. With this in mind, and considering that the visual cortex has a central role in governing temporal summation,^15,33,38 it is possible that changes in the visual cortex as a consequence of glaucoma also might lead to the changes in temporal summation observed in this study. Wilson¹⁵ found temporal summation to be disrupted in subjects with defects affecting only the visual pathway posterior to the lateral geniculate nucleus (LGN). It also has been suggested that changes in the extent of Ricco's area in glaucoma may be related to the spatial tuning of second stage cortical filters.³¹ Redmond et al.¹⁶ hypothesized that an enlargement of Ricco's area is the result of detection becoming mediated by alternative cortical channels, in an attempt to preserve a constant signal-to-noise ratio in the absence of structural reorganization. Specifically, they hypothesized that the largest area over which spatial summation remains linear equates to a cortical filter receiving input from 31 RGCs. As RGCs are lost in glaucoma, the area over which 31 RGCs are dispersed is larger. A cortical filter with a spatial extent equivalent to this larger area would have displayed probability summation when the RGC density was normal, but now demonstrates linear summation. Thus, Ricco's area appears to enlarge (i.e., a constant number of RGCs underlie the “perceptive” field^31,43). In a similar manner, a cortical “detector” or filter with a long time constant may facilitate the detection of perimetric stimuli in glaucoma, and, thus, also lead to an increase in the critical duration relative to healthy observers with no active remodeling of the visual pathway. It also could be argued that second-stage cortical filters, with a specific time constant and spatial tuning, determine the size of Ricco's area and/or the critical duration in healthy subjects and glaucoma patients. In turn, such filters may function to maintain constant detectability across the visual field in a range of visual environments or in disease. Equally, it is possible that an active reorganization of the visual cortex takes place in glaucoma resulting in filters with spatiotemporal properties different to those present in the healthy visual cortex. Such neural plasticity has been observed in in vitro⁵⁷ and in vivo^58,59 animal studies. 

In this study, we observed a statistically significant increase in the critical duration in glaucoma patients relative to healthy controls when examined using a stimulus scaled to the localized Ricco's area. However, it must be noted that a stimulus scaled to approximate Ricco's area for a 24-frame reference presentation duration (191.9 ms) was used to construct temporal summation functions. Ricco's area is known to increase with a reduction in stimulus duration²⁹ and, as such, the scaled stimulus used is unlikely to accurately reflect the extent of Ricco's area for all stimulus presentation durations in this study. It also is currently unknown if the effect of stimulus duration on the size of Ricco's area is different in glaucoma subjects when compared to healthy controls. Should the rate of change in Ricco's area with stimulus duration be greater in glaucoma observers, the discrepancy between the true Ricco's area and the stimulus area used in this study for stimulus durations less than 191.9 ms may be greater in this group relative to healthy controls, with the result that an artifactual change in temporal summation is observed. Further work, outside of the scope of this study, is required to firmly establish the rate of change in Ricco's area with stimulus duration in healthy subjects and glaucoma patients. 

It is clear, from the findings presented here, that the use of a stimulus presentation time in the range of 100 to −200 ms is inappropriate if one wishes to detect early disease using SAP. In Figure 3, it can be seen that the temporal summation functions for subjects with glaucoma undergo a rightward (increase in the critical duration) and upward (increase in threshold contrast energy) shift in position compared to healthy observers. Considering this, any differences in threshold (vertical difference in the position of summation function for a single stimulus of fixed duration) between healthy observers and glaucoma patients, otherwise termed the disease signal (plotted as a function of stimulus duration in Fig. 5), may be increased if a presentation time shorter than 100 to 200 ms is used in combination with a GIII stimulus or stimuli scaled to the localized Ricco's area. In the case of a GIII stimulus, disease signal may be boosted by approximately 200% if a stimulus equal to the critical duration in healthy observers is used (Fig. 5, B), in place of the standard presentation duration of 200 ms (Fig. 5, A). An even greater boost (∼300%) in the disease signal may be gained if a stimulus is scaled to the localized Ricco's area and presented with a duration less than or equal to the critical duration in healthy observers for that stimulus type (Fig. 5, D). Interestingly, a comparable boost in the disease signal of SAP may be gained by reducing stimulus duration to be equal to the critical duration in healthy observers when using a GIII stimulus (Fig. 5, B), or scaling stimulus area to reflect localized spatial summation when using a presentation duration of approximately 200 ms (Fig. 5, C). These findings clearly demonstrated that achromatic SAP stimuli modulating in either two (luminance/area, luminance/duration) or three (luminance/area/duration) dimensions also would serve to increase the dynamic range of SAP, improve the ability to detect early RGCs loss, and ultimately permit clinicians to chart subtle underlying changes in the glaucomatous visual system, provided the increase in signal is not matched with a corresponding increase in variability. Further research is required to determine whether a stimulus modulating in one, two, or three dimensions affords the largest disease signal, and if a low degree of measurement variability can be maintained with such a stimulus (i.e., to achieve a higher signal-to-noise ratio). 

Spatial and temporal summation are greater in glaucoma than in healthy controls. Such changes may occur in an effort to maintain constant signal-to-noise ratio in regions of the visual field served by RGCs that have either been lost or whose function is compromised. The findings of this study also have implications for the optimum design of perimetric stimuli. It is likely that stimuli modulating in area, duration, or in three-dimensions (area-duration-luminance), offers the advantage of extending the dynamic range of current instruments, in addition to improving the sensitivity of SAP. 

Presented in part at the European Academy of Optometry and Optics annual meeting, Warsaw, Poland, May 2014, and 21st International Imaging and Visual Field Symposium, New York, New York, United States, September 2014. 

Supported by a PhD studentship from the Department for Employment and Learning, Northern Ireland (PJM), and in part by the National Institute for Health Research (NIHR) Biomedical Research Centre based at Moorfields Eye Hospital NHS Foundation Trust and UCL Institute of Ophthalmology (PJM, DFG-H). DFG-H's chair at UCL is supported by funding from the International Glaucoma Association. Conference presentation of this work was supported by the Moorfields Association in the form of a travel grant (PJM). The views expressed are those of the authors and not necessarily those of the NHS, the NIHR, or the Department of Health. 

Disclosure: P.J. Mulholland, Heidelberg Engineering (R); T. Redmond, Heidelberg Engineering (F); D.F. Garway-Heath, Carl Zeiss Meditec (F, R), Heidelberg Engineering (F, R), P; M.B. Zlatkova, None; R.S. Anderson, Heidelberg Engineering (F, R)