Abstract
Measurement of corneal nerve tortuosity is associated with dry eye disease, diabetic retinopathy, and a range of other conditions. However, clinicians measure tortuosity on very different grading scales that are inherently subjective. Using in vivo confocal microscopy, 253 images of corneal nerves were captured and manually labelled by two researchers with tortuosity measurements ranging on a scale from 0.1 to 1.0. Tortuosity was estimated computationally by extracting a binarised nerve structure utilising a previously published method. A novel U-Net segmented adjacent angle detection (USAAD) method was developed by training a U-Net with a series of back feeding processed images and nerve structure vectorizations. Angles between all vectors and segments were measured and used for training and predicting tortuosity measured by human labelling. Despite the disagreement among clinicians on tortuosity labelling measures, the optimised grading measurement was significantly correlated with our USAAD angle measurements. We identified the nerve interval lengths that optimised the correlation of tortuosity estimates with human grading. We also show the merit of our proposed method with respect to other baseline methods that provide a single estimate of tortuosity. The real benefit of USAAD in future will be to provide comprehensive structural information about variations in nerve orientation for potential use as a clinical measure of the presence of disease and its progression.
Highlights
Corneal nerve tortuosity is a morphological property which indicates the degree of curvature in nerves found in the sub-basal nerve plexus of the cornea
A major challenge for vision science is to estimate corneal nerve tortuosity from single images obtained by using in vivo confocal microscopy (IVCM) [1]
We established a baseline accuracy for subjective corneal nerve tortuosity gradings
Summary
Corneal nerve tortuosity is a morphological property which indicates the degree of curvature in nerves found in the sub-basal nerve plexus of the cornea. Appear approximately straight, while high tortuosity nerves have many twists and are significantly curved (Figure 1B). These anomalies are not evaluated in the scope of this paper, they provide an enduring challenge to developing image analysis tools for clinical assessment of the cornea. A major challenge for vision science is to estimate corneal nerve tortuosity from single images obtained by using in vivo confocal microscopy (IVCM) [1]. Eyes are composed of two fused pieces, both the posterior and anterior components [2]. The anterior component consists of the cornea, iris and lens.
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