2 research outputs found
A Deep Learning Approach to Denoise Optical Coherence Tomography Images of the Optic Nerve Head
Purpose: To develop a deep learning approach to de-noise optical coherence
tomography (OCT) B-scans of the optic nerve head (ONH).
Methods: Volume scans consisting of 97 horizontal B-scans were acquired
through the center of the ONH using a commercial OCT device (Spectralis) for
both eyes of 20 subjects. For each eye, single-frame (without signal
averaging), and multi-frame (75x signal averaging) volume scans were obtained.
A custom deep learning network was then designed and trained with 2,328 "clean
B-scans" (multi-frame B-scans), and their corresponding "noisy B-scans" (clean
B-scans + gaussian noise) to de-noise the single-frame B-scans. The performance
of the de-noising algorithm was assessed qualitatively, and quantitatively on
1,552 B-scans using the signal to noise ratio (SNR), contrast to noise ratio
(CNR), and mean structural similarity index metrics (MSSIM).
Results: The proposed algorithm successfully denoised unseen single-frame OCT
B-scans. The denoised B-scans were qualitatively similar to their corresponding
multi-frame B-scans, with enhanced visibility of the ONH tissues. The mean SNR
increased from dB (single-frame) to dB
(denoised). For all the ONH tissues, the mean CNR increased from (single-frame) to (denoised). The MSSIM increased from
(single frame) to (denoised) when compared with
the corresponding multi-frame B-scans.
Conclusions: Our deep learning algorithm can denoise a single-frame OCT
B-scan of the ONH in under 20 ms, thus offering a framework to obtain superior
quality OCT B-scans with reduced scanning times and minimal patient discomfort
Classification of MRI data using deep learning and Gaussian process-based model selection
International audience<p>The classification of MRI images according to the anatomicalfield of view is a necessary task to solve when faced with the increasing quantity of medical images. In parallel, advances in deeplearning makes it a suitable tool for computer vision problems. Using a common architecture (such as AlexNet) provides quite goodresults, but not sufficient for clinical use. Improving the model isnot an easy task, due to the large number of hyper-parameters governing both the architecture and the training of the network, and tothe limited understanding of their relevance. Since an exhaustivesearch is not tractable, we propose to optimize the network first byrandom search, and then by an adaptive search based on GaussianProcesses and Probability of Improvement. Applying this methodon a large and varied MRI dataset, we show a substantial improvement between the baseline network and the final one (up to 20% forthe most difficult classes).</p