Abstract
Deep learning based methods are routinely used to segment various structures of interest in varied medical imaging modalities. Acquiring annotations for a large number of images requires a skilled analyst, and the process is both time consuming and challenging. Our approach to reduce effort is to reduce the number of images needing detailed annotation. For intravascular optical coherence tomography (IVOCT) image pullbacks, we tested 10% to 100% of training images derived from two schemes: equally-spaced image subsampling and deep-learning- based image clustering. The first strategy involves selecting images at equally spaced intervals from the volume, accounting for the high spatial correlation between neighboring images. In clustering, we used an autoencoder to create a deep feature space representation, performed k-medoids clustering, and then used the cluster medians for training. For coronary calcifications, a baseline U-net model was trained on all images from volumes of interest (VOIs) and compared with fewer images from the sub-sampling strategies. For a given sampling ratio, the clustering based method performed better or similar as compared to the equally spaced sampling approach (e.g., with 10% of images, mean F1 score for calcific class increased from 0.52 to 0.63, with equal spacing and with clustering, respectively). Additionally, for a fixed number of training images, sampling images from more VOIs performed better than otherwise. In conclusion, we recommend the clustering based approach to annotate a small fraction of images, creating a baseline model, which potentially can be improved further by annotating images selected using methods described in active learning research.
Highlights
For deep learning applications in medical imaging, there is a need to conserve the numbers of images required and the numbers of images requiring detailed annotation
The auto-encoder used in the deep-feature extraction step was checked for reconstruction accuracy for each volumes of interest (VOIs)
We used a simple approach of selecting images spaced out in the VOI since it is known that slices form a contiguous volume within an OCT pullback, and slices close to each other are highly spatially correlated
Summary
For deep learning applications in medical imaging, there is a need to conserve the numbers of images required and the numbers of images requiring detailed annotation. Deep neural networks have been used in all areas of image processing/analysis, including image segmentation, enhancement, restoration, classification, and reconstruction. The associate editor coordinating the review of this manuscript and approving it for publication was John See. results could be applicable to other problems as well. Unlike applications using natural images where hundreds of thousands or even millions of images can be used, most often many fewer images are available in medical imaging, suggesting a need to learn as much as possible from available images. Here we examine segmentation of coronary calcifications in intravascular optical coherence tomography (IVOCT) images. IVOCT is an imaging modality that allows for assessment of coronary
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call