Methods

We followed 23 patients (2 men and 21 women) who underwent surgery for idiopathic FTMHs between January 1, 2008 and September 30, 2008. The patient age ranged from 45 to 71 years (mean, 61 years). Patients with bilateral MHs or any diseases involving macula at the fellow eyes were excluded from this study. Microincision vitrectomy (23- or 25-gauge) and internal limiting membrane peeling with indocyanine green (0.05%) staining was performed. No attempt was made to aspirate over and around the MH. Cataract surgery was combined in 21 eyes. Vitrectomy alone was performed in 2 pseudophakic eyes. At the end of the vitrectomy, air was replaced by a mixture of air and C ₃ F ₈ (8%). After surgery, patients were asked to hold their heads in a face-down position for 1 week. All patients underwent best-corrected visual acuity (BCVA) measurements, both SD-OCT imaging of the macula and macular microperimetry by Spectral OCT/SLO (OTI, Toronto, Canada), and FAF imaging using the Heidelberg retina angiograph 2 (HRA2, Heidelberg, Germany) at an average of 10 months after MH surgery. The scan acquisition protocols for SD-OCT imaging include 5-line raster scans and a macular cube 200 × 200 Combo. The macular cube 200 × 200 Combo consists of a horizontal 200 A-scans measured to 200 vertical lines across an area of 6 × 6 mm. Thirty-μm slices were examined in both horizontal and vertical directions. The amount of IS/OS defects on SD-OCT was graded as none, focal, small, or diffuse (or invisible) by 3 retinal surgeons who operated in a masked manner. In the microperimetry test, a Goldmann III size stimulus was used, and 25 stimulus locations covering the central 9 degrees were examined by microperimetry. The duration of the stimulus was 200 ms (flashing test stimuli measuring 5 × 5 pixels were presented for 200 ms by a helium-neon laser). The retinal sensitivity at the center of the fovea (microperimetry, center) and the mean retinal sensitivities at 24 locations covering the central 9 degrees of both study and fellow eyes were determined. The mean retinal sensitivities within the central 9 degrees (microperimetry, mean), the retinal sensitivity of the foveal center (microperimetry, center), and the difference in the retinal sensitivity of the foveal center or the mean of the study and the fellow eyes (microperimetry, centerdiff and microperimetry, meandiff, respectively) were measured with microperimetry.

As the amount of fluorescent light (at approximately 500 nm) emitted by the RPE is extremely low, an confocal scanning laser ophthalmoscope. (HRA2; Heidelberg, Germany) was used with both exciter illumination and barrier filters in place. The degrees of FAF were subjectively graded (grade 1-4) independently by the same retina surgeons. These values were compared with those obtained using the semiautomatic method by an expert (J.K.K.), using Matlab (MathWorks) for Wiener filtering, thresholding, and analyzing images ( http://www.mathworks.com/products/matlab ). Briefly, step 1 was cropping the region of interest (ROI) in each FAF image, because we are interested in the variation of brightness around the macula. This excludes the effect of a transparency in the tissue, vessel, etc. Step 2 was enhancement of the signal-to-noise ratio in tissue by Wiener filter. The Wiener filter is applied to ROI images. Step 3 was expert-aided segmentation of the images. Because the brightness of FAF in a healthy eye is likely to decrease monotonically toward the center of the macula (foveola), a local bright segment will be problematic. Thus, the threshold value was adjusted until the resulting boundary and the expert-subjective boundary were almost similar. Then, the resulting binary image for a local bright segment was trimmed to form a single image. Step 4 was calculation of the representative value of local bright segments. The value was defined by the area multiplied by the mean, where area is the size of a local bright segment and mean is the average value of brightness of local bright segment (ie, value = (A1 × B1) + (A2 × B2) + …).

The SPSS V14.0 software program (SPSS Inc., Chicago, Illinois, USA) was used for all statistical analyses, and P value < .05 was considered as statistically significant. The possible correlations between variables were investigated using the Spearman rank correlation test.

Results

All 23 patients showed complete closure of MH, defined clinically by an ophthalmoscopic and SD-OCT examination. The mean Snellen VA of the 23 study eyes improved from 20/200 preoperatively to 20/50 postoperatively. The mean VA in logMAR significantly improved from 1.02 to 0.44 ( P < .001). The average value of microperimetry (mean) of the study and fellow eyes was 8.89 (standard deviation, 2.16) and 10.95 (standard deviation, 2.18), respectively. The average value of microperimetry (center) of the study and fellow eyes was 6.96 (standard deviation, 4.23) and 8.68 (standard deviation, 3.29), respectively. Microperimetry (mean) was well correlated with microperimetry (center) in both study and fellow eyes (r ² = 0.716, P < .001; r ² = 0.704, P = .001, respectively). Poor preoperative VA was correlated with lower postoperative microperimetry (mean) and microperimetry (center) of the study eyes (r ² = −0.521, P = .027; r ² = −0.514, P = .029, respectively). The poorer the preoperative VA, the lower the postoperative microperimetry threshold. Poor postoperative VA was also correlated with large microperimetry (meandiff) (r ² = 0.486, P = .035). The poorer the postoperative VA, the larger the difference with respect to the nondiseased eyes ( Figure 1 ).

Correlations between visual acuity (VA) and parameters of microperimetry. Preoperative visual acuity (VA) (logMAR [logarithm of minimal angle of resolution]) versus (Top) microperimetry (mean) and (Middle) microperimetry (center) in repaired macular holes. Poor preoperative VA is related with lower postoperative microperimetry (mean) and microperimetry (center) of the study eyes. (Bottom) Postoperative VA (logMAR) versus microperimetry (meandiff) in repaired macular holes. Poor postoperative VA is also correlated with high microperimetry (meandiff) values.

Following successful closure of MH after surgery, the FAF of all eyes decreased markedly. There were 10 eyes that were graded 1, 6 eyes graded 2, 3 eyes graded 3, and 4 eyes graded 4. The subjectively graded amount of FAF was well correlated with the semiautomatic method ( Supplemental Figure 1 , available at AJO.com ) using an image analyzer (r = 0.889, P < .001) ( Figure 2 ). There was a positive correlation between microperimetry (centerdiff) and the degree of FAF in the study eyes (r = 0.469, P = .037) ( Figure 3 ). In other words, the FAF of the study eyes tended to be high when there were large differences between the retinal sensitivities of the foveal centers of the study eyes and normal fellow eyes. However, preoperative and postoperative VA (logMAR) and time after surgery were not correlated with FAF. The extent of the IS/OS defect on SD-OCT was graded as none, focal, small, or diffuse (or invisible) ( Figure 4 ). Six eyes were graded as none, 7 eyes were graded as focal, 8 eyes were graded as small, and 2 eyes were graded as diffuse defect. The mean central macular thickness in eyes with repaired MHs as determined by SD-OCT machine was 240.3 μm (standard deviation, 31.6). A decrease in FAF after successful MH surgery was not correlated with either the degree of IS/OS defects or central macular thickness on SD-OCT. The postoperative degree of IS/OS defects was not correlated with the preoperative and postoperative VA (logMAR) or measured microperimetry parameters. Study eyes with focal IS/OS defects had good visual outcomes (logMAR), as did eyes with intact IS/OS seen on SD-OCT (0.379 ± 0.212 vs 0.333 ± 0.137, P = .663) ( Figure 5 ).

Fundus autofluorescence (FAF) grading in repaired macular holes. Representative examples of FAF grading (subjective). The subjectively graded amount of FAF is well correlated with results obtained through use of the semiautomatic method by an expert (r = 0.889, P < .001).

Fundus autofluorescence (FAF) versus microperimetry (centerdiff) in patients with repaired macular holes. There is a positive correlation between microperimetry (centerdiff) and the degree of FAF in the study eyes (r = 0.469, P = .037).

The degrees of inner and outer segment (IS/OS) defects on spectral-domain optical coherence tomography in repaired macular holes. Representative examples of none, focal, small, or diffuse defect on IS/OS are shown.

Spectral-domain optical coherence tomography (SD-OCT) and fundus autofluorescence (FAF) of patients with repaired macular holes (MH). (Top, left) Patient 1, a 49-year-old woman, showed no detectable photoreceptor inner and outer segment (IS/OS) defect on SD-OCT 8 months after MH surgery. Her Snellen visual acuity (VA) was 0.4, microperimetry (centerdiff) was 3.3, and FAF grade was 2. (Top, middle) Patient 2, a 54-year-old woman, showed focal IS/OS defect on SD-OCT 5 months after MH surgery. Her VA was 0.8, microperimetry (centerdiff) was 1.0, and FAF grade was 1. Despite intact IS/OS morphology seen in Patient 1, her postoperative VA was worse than that of Patient 2. However, FAF grade and microperimetry (centerdiff) are well correlated and reflect VA in both patients. (Top, right) Patient 3, a 69-year-old woman, showed focal IS/OS defect on SD-OCT 7 months after MH surgery. Her VA was 0.5, microperimetry (centerdiff) was 4.0, and FAF grade was 4. (Bottom, left) Patient 4, a 45-year-old man, had cystic space in the outer retinal layer on SD-OCT 5 months after MH surgery. Foveola IS/OS was not clearly seen. His VA was 0.6, microperimetry (centerdiff) was 0.0, and FAF grade was 1. (Bottom, middle) Patient 5, a 54-year-old woman, showed no detectable IS/OS defect on SD-OCT 8 months after MH surgery. Her VA was 0.5, microperimetry (centerdiff) was 2.0, and FAF grade was 2. (Bottom, right) Patient 6, a 67-year-old woman, showed focal IS/OS defect on SD-OCT 5 months after MH surgery. Her VA was 0.32, microperimetry (centerdiff) was 10, and FAF grade was 3. FAF grade and microperimetry (centerdiff) is correlated in Patients 3, 4, 5, and 6.

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