Methods

Images from 4 clinical study sites (Bonn, London, Münster, Oxford) of the MacTel Study were collected via the Moorfields Eye Hospital Reading Centre (MEHRC) database. Cases were included if the diagnosis was confirmed by the MEHRC and if a 30-degree FAF image recorded with a confocal scanning laser ophthalmoscope (Spectralis HRA; Heidelberg Engineering, Heidelberg, Germany) of sufficient quality was available. The MacTel study was approved by the local medical ethics committees and adhered to the tenets of the Declaration of Helsinki. Informed consent was given by each subject before the start of the study.

For a detailed characterization of common FAF patterns, the full panel of multimodal imaging included in the MacTel study (color fundus photography, 30-degree FAF, FFA, blue reflectance imaging, and OCT) was analyzed in 100 consecutive eyes for which 30-degree macular pigment optical density (MPOD; recorded with dual-wavelength FAF technique) measurements were also available. Blue reflectance, FAF, and early- and late-phase FFA images were acquired using a scanning laser ophthalmoscope (Spectralis HRA or HRA2; Heidelberg Engineering, Heidelberg, Germany), and MPOD images were recorded as described previously using a modified 2-wavelenght HRA classic (Heidelberg Engineering) ³ : MPOD was calculated from 2 averaged FAF images (each consisting of up to 16 single images) derived from excitation using 488-nm and 514-nm light, respectively, in conjunction with a barrier filter that blocks wavelengths shorter than 560 nm. Because of the maximum absorbance of macular pigment at 460 nm, the AF signal recorded using 488-nm excitation light is strongly dependent on macular pigment density, whereas the AF signal of the 514-nm AF image is not. Subtraction of the 2 averaged images results in an image representing MPOD distribution, which was saved with an intensity resolution of 8 bits/pixel, and a 512 × 512-pixel resolution. Spectral domain OCT macular volume scans (15 degrees horizontally × 10 degrees vertically, ~30 µm distance between individual B-scans, recorded in the high-resolution mode with 768 A-scans per B-scan) and single-line scans through the foveal center (30 degrees in high-speed mode with 768 A-scans per B-scan) were acquired using Spectralis OCT (Heidelberg Engineering). The automatic real-time mode was used to improve the signal-to-noise ratio, averaging 9 frames for volume scans and up to 100 consecutive frames for single-scan recordings.

Next, simplified categories of alterations on FAF images were defined to analyze the frequency of specific features in a large cohort of more than 400 patients. The following alterations were not mutually exclusive and could coexist in the same eye:

• 1.
  

  Presence of FAF changes, and whether or not these were limited to the “MacTel area”

  
  
• 2.
  

  Asymmetry of FAF changes with more pronounced alterations in the temporal MacTel area (ie, temporal to a vertical line through the foveal center)

  
  
• 3.
  

  The pattern of FAF changes: increased compared to normal ± decreased signal (mixed AF)

  
  
• 4.
  

  Visibility of vascular abnormalities (blunted venules and/or ectatic capillaries)

Changes were considered to be more pronounced temporally than nasally, if either there was (1) any abnormal FAF signal temporal and a normal signal nasally, (2) an increased signal nasal to the fovea and a mixed signal temporally, (3) the size of the area with FAF changes was larger temporal than nasal to the fovea, or (4) there were vascular changes only or mainly affecting temporal vessels. Images were deemed gradable if at least the first 3 categories could be assessed. Grading was performed by L.P. and ambiguous cases were discussed with P.C.I.

Youden index was used as performance measure for evaluating the ability of AF images to avoid misclassification. Youden index evaluates the ability of a classifier to avoid misclassifications but putting equal weights on a classifier’s performance on both the positive and negative cases. The Youden index as a performance index that provides the maximum differentiability of classifier when equal weight is given to sensitivity and specificity, thus minimizing the total misclassification rates. For this purpose, 100 FAF images from 100 consecutive MacTel patients from one center (London) were mixed with FAF images of 50 normal controls and of 50 patients with different macular diseases that may mimic MacTel, which were obtained as part of standard care in medical retina clinics between January 1, 2016, and January 31, 2019. The latter included cases with central serous retinopathy (n=11), age-related macular degeneration (n=9), vitelliform lesion (n=7), epiretinal membrane (n=5), pathologic myopia (n=5), pigment epithelial detachment of various aetiology (n=4), retinal vein occlusion (n=3), diabetic maculopathy (n=1), macular hole (n=1), PRPH2 -related macular dystrophy (n=1), vitreomacular traction (n=1), perifoveal exudative vascular anomalous complex (n=1), and acute macular neuroretinopathy (n=1). Two masked retinal specialists (P.C.I., M.G.) independently, separately assessed FAF images in random sequence without additional information from multimodal imaging and to classify them as either having MacTel or not. Only one eye from each patient was assessed without information on the phenotype of the fellow eye.

Results

Fundus Autofluorescence Features and Multimodal Imaging

Features on FAF images and the associated findings on multimodal imaging were investigated in 100 eyes with available full retinal imaging data set, including fundus photography, macular pigment assessment using MPOD maps, OCT, and blue reflectance imaging. Table 1 provides a summary of the FAF changes as described below.

Changes on FAF images were usually limited to the MacTel area. In mild disease without obvious loss of the photoreceptor layer, a relatively increased AF signal may be limited to a wedge-shaped area temporal to the foveal center ( Figure 1 , A) or may involve the entire MacTel area ( Figure 1 , B). The abnormal AF signal was usually not higher than outside the MacTel area and was associated with reduced macular pigment on MPOD maps and/or hyporeflective cavities on OCT images ( Figure 1 , A and B). Macular pigment loss was usually associated with increased reflectivity on confocal blue reflectance images. Increased FAF associated with hyporeflective cavities is usually limited to the fovea ( Figure 1 , B).

Increased fundus autofluorescence (FAF) in patients with macular telangiectasia type 2 and associated findings on multimodal imaging. Dashed lines show the horizontal extent of macular pigment loss. A. Wedge-shaped temporal increase in FAF associated with the loss of macular pigment. B. Foveal increase in FAF (arrow heads) associated with a cystoid space visible on OCT (arrow heads). C. Well-demarcated increase in FAF associated with photoreceptor atrophy (dotted line). D. Small area of increased FAF centered on the fovea that may be linked to a funduscopically visible “yellow spot.” E. Full-thickness macular hole with persistent internal limiting membrane drape causing a round increase in FAF signal (shown by short lines). MPOD: macular pigment optical density maps. BR: blue reflectance images.

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