The purpose of this review is to provide a comprehensive and updated overview of the clinical features, imaging modalities, differential diagnosis, diagnostic criteria, and treatment options for Vogt-Koyanagi-Harada (VKH) syndrome, a rare progressive inflammatory condition characterized by bilateral granulomatous panuveitis and systemic manifestations. While the clinical features and disease course of VKH syndrome are well-characterized in the literature, its diagnosis is challenging due to a broad differential that include infectious and noninfectious causes of uveitis and rare inflammatory conditions, as well as a lack of a single diagnostic finding on exam, laboratory testing, or imaging. The evolution of the diagnostic criteria for VKH syndrome reflects the growing understanding of the disease by the ophthalmic community and advancement of imaging technology. Findings on enhanced depth imaging (EDI) optical coherence tomography (OCT) and indocyanine green angiography (ICGA) help detect subtle inflammation of the choroid and were incorporated into new diagnostic criteria developed in the last few years. There is limited research on the treatment for acute VKH, but results of studies to date support the early initiation of immunomodulatory therapy (IMT) due to a high recurrence rate and progression to chronic disease in patients treated with monotherapy with high-dose systemic corticosteroids. This review will provide an in-depth summary of recent literature on advanced imaging modality and IMT to guide clinicians in their management of patients with VKH syndrome.
Background: Soft drusen and basal linear deposit (BLinD) are two forms of the same extracellular lipid rich material that together make up an Oil Spill on Bruch’s membrane (BrM). Drusen are focal and can be recognized clinically. In contrast BLinD is thin and diffusely distributed, and invisible clinically, even on highest resolution OCT, but has been detected on en face hyperspectral autofluorescence (AF) imaging ex vivo. We sought to optimize histologic hyperspectral AF imaging and image analysis for recognition of drusen and sub-RPE deposits (including BLinD and basal laminar deposit), for potential clinical application.
Methods: Twenty locations specifically with drusen and 12 additional locations specifically from fovea, perifovea and mid-periphery from RPE/BrM flatmounts from 4 AMD donors underwent hyperspectral AF imaging with 4 excitation wavelengths (λex 436, 450, 480 and 505 nm), and the resulting image cubes were simultaneously decomposed with our published non-negative matrix factorization (NMF). Rank 4 recovery of 4 emission spectra was chosen for each excitation wavelength.
Results: A composite emission spectrum, sensitive and specific for drusen and presumed sub-RPE deposits (the SDr spectrum) was recovered with peak at 510–520 nm in all tissues with drusen, with greatest amplitudes at excitations λex 436, 450 and 480 nm. The RPE spectra of combined sources Lipofuscin (LF)/Melanolipofuscin (MLF) were of comparable amplitude and consistently recapitulated the spectra S1, S2 and S3 previously reported from all tissues: tissues with drusen, foveal and extra-foveal locations.
Conclusions: A clinical hyperspectral AF camera, with properly chosen excitation wavelengths in the blue range and a hyperspectral AF detector, should be capable of detecting and quantifying drusen and sub-RPE deposits, the earliest known lesions of AMD, before any other currently available imaging modality.
