Abstract
The aim of this paper is to investigate the clinical utility of the application of deep learning denoise algorithms on standard wide-field Optical Coherence Tomography Angiography (OCT-A) images. This was a retrospective case-series assessing forty-nine 10 × 10 mm OCT-A1 macula scans of 49 consecutive patients attending a medical retina clinic over a 6-month period. Thirty-seven patients had pathology; 13 had none. Retinal vascular layers were categorised into superficial or deep capillary plexus. For each category, the retinal experts compared the original standard image with the same image that had intelligent denoise applied. When analysing the Superficial Capillary Plexus (SCP), the denoised image was selected as “best for clinical assessment” in 98% of comparisons. No difference was established in the remaining 2%. On evaluating the Deep Capillary Plexus (DCP), the denoised image was preferred in 35% of comparisons. No difference was found in 65%. There was no evidence of new artefactual features nor loss of anatomical detail in denoised compared to the standard images. The wide-field denoise feature of the Canon Xephilio OCT-A1 produced scans that were clinically preferable over their original OCT-A images, especially for SCP assessment, without evidence for causing a new artefactual error.
Highlights
We looked at the effect of denoise on the Superficial Capillary Plexus (SCP) as well as the Deep Capillary Plexus (DCP) and its effect on different forms of vasculature
The intelligent denoise feature of the Canon Xephilio OCT-A1 appears to allow for a rapid facility to improve image quality with no evidence of meaningful loss of clinical detail nor new artefactual errors
The positive impact of the denoise software on the SCP did not apply to the same extent to the DCP; in most DCP image comparisons (65%), there was no improvement noted between the DCP denoised images and DCP original images
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. The first clinical studies using this technology were published in 2014 [1], and since the technology has improved to allow even greater insight into retinal vascular anatomy [2]. OCT-A technology uses laser light reflectance of the surface of moving red blood cells to accurately depict blood vessels through different segmented areas of the eye. It visualizes the retina in a depth-resolved fashion, allowing the separate study of the retinal superficial and deep vascular plexuses [3]
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