Keskeiset käsitteet
A Residual U-Net model effectively reduces noise and enhances the diagnostic quality of both Anterior Segment and Posterior Segment Optical Coherence Tomography images.
Tiivistelmä
The study presents an enhanced denoising model based on a Residual U-Net architecture to improve the quality of Optical Coherence Tomography (OCT) images. The model was applied to both Anterior Segment OCT (ASOCT) and Posterior Segment OCT (PSOCT) images, aiming to reduce noise and improve overall image clarity while preserving essential anatomical features.
The key highlights of the study are:
- The Residual U-Net architecture, enhanced by incorporating a pre-trained EfficientNet network for feature extraction, was employed for the denoising task.
- A hybrid loss function was used, integrating Mean Squared Error (MSE) with additional perceptual quality components from the pre-trained network, to optimize both the fidelity of image reconstruction and the perceptual integrity of the denoised outputs.
- For PSOCT images, the Peak Signal to Noise Ratio (PSNR) improved to 34.343 ± 1.113, and the Structural Similarity Index Measure (SSIM) reached 0.885 ± 0.030, indicating significant enhancements in image quality.
- For ASOCT images, the PSNR was 23.525 ± 0.872 dB and the SSIM was 0.407 ± 0.044, also demonstrating notable improvements in noise reduction and preservation of anatomical details.
- The dual functionality of the model in effectively denoising both ASOCT and PSOCT images confirms its versatility and potential in clinical settings, contributing to more precise evaluations and potentially reducing the need for repeated imaging sessions.
Tilastot
The PSNR for PSOCT images improved to 34.343 ± 1.113 dB.
The SSIM for PSOCT images reached 0.885 ± 0.030.
The PSNR for ASOCT images was 23.525 ± 0.872 dB.
The SSIM for ASOCT images was 0.407 ± 0.044.
Lainaukset
"The implementation of the Residual U-Net model has proven effective in reducing noise and enhancing the diagnostic quality of OCT images across both ASOCT and PSOCT modalities."
"This dual functionality confirms the model's versatility and potential in clinical settings, contributing to more precise evaluations and potentially reducing the need for repeated imaging sessions."