Abstract
PurposeProbe-based confocal laser endomicroscopy (pCLE) enables performing an optical biopsy via a probe. pCLE probes consist of multiple optical fibres arranged in a bundle, which taken together generate signals in an irregularly sampled pattern. Current pCLE reconstruction is based on interpolating irregular signals onto an over-sampled Cartesian grid, using a naive linear interpolation. It was shown that convolutional neural networks (CNNs) could improve pCLE image quality. Yet classical CNNs may be suboptimal in regard to irregular data.MethodsWe compare pCLE reconstruction and super-resolution (SR) methods taking irregularly sampled or reconstructed pCLE images as input. We also propose to embed a Nadaraya–Watson (NW) kernel regression into the CNN framework as a novel trainable CNN layer. We design deep learning architectures allowing for reconstructing high-quality pCLE images directly from the irregularly sampled input data. We created synthetic sparse pCLE images to evaluate our methodology.ResultsThe results were validated through an image quality assessment based on a combination of the following metrics: peak signal-to-noise ratio and the structural similarity index. Our analysis indicates that both dense and sparse CNNs outperform the reconstruction method currently used in the clinic.ConclusionThe main contributions of our study are a comparison of sparse and dense approach in pCLE image reconstruction. We also implement trainable generalised NW kernel regression as a novel sparse approach. We also generated synthetic data for training pCLE SR.
Highlights
Probe-based confocal laser endomicroscopy is a recent optical fibre bundle-based medical imaging modalityElectronic supplementary material The online version of this article contains supplementary material, which is available to authorized users.with utility in a range of clinical indications and organ systems, including gastrointestinal, urological and respiratory tracts [5].The pCLE probe relies on a coherent fibre bundle comprising many (>10k) cores that are irregularly distributed across the field of view (FoV)
To incorporate NW kernel regression into the convolutional neural networks (CNNs) framework, we propose a novel trainable CNN layer referred to as an “NW layer”, which models the relation of the data points by use of custom trainable kernels to perform local interpolation
To test NW kernel regression benefits from generalisation via learning multiple kernels, we trained the NWnetSR as EBSR network for the task of pCLE SR reconstruction with sparse input images and masks
Summary
We compare pCLE reconstruction and super-resolution (SR) methods taking irregularly sampled or reconstructed pCLE images as input. We propose to embed a Nadaraya–Watson (NW) kernel regression into the CNN framework as a novel trainable CNN layer. We design deep learning architectures allowing for reconstructing high-quality pCLE images directly from the irregularly sampled input data. We created synthetic sparse pCLE images to evaluate our methodology
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