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International Journal of Computer Assisted Radiology and Surgery
Published in: International Journal of Computer Assisted Radiology and Surgery 7/2020

Open Access 01-07-2020 | Original Article

Learning from irregularly sampled data for endomicroscopy super-resolution: a comparative study of sparse and dense approaches

Authors: Agnieszka Barbara Szczotka, Dzhoshkun Ismail Shakir, Daniele Ravì, Matthew J. Clarkson, Stephen P. Pereira, Tom Vercauteren

Published in: International Journal of Computer Assisted Radiology and Surgery | Issue 7/2020

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Abstract

Purpose

Probe-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.

Methods

We 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.

Results

The 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.

Conclusion

The 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.
Appendix
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Literature
1.
André B, Vercauteren T, Buchner AM, Wallace MB, Ayache N (2011) A smart atlas for endomicroscopy using automated video retrieval. Med Image Anal 15(4):460–476CrossRefPubMed
2.
3.
Eldesokey A, Felsberg M, Khan FS (2018) Propagating confidences through CNNs for sparse data regression. arXiv preprint arXiv:​1805.​11913
4.
5.
Fugazza A, Gaiani F, Carra MC, Brunetti F, Lévy M, Sobhani I, Azoulay D, Catena F, de’Angelis GL, de’Angelis N (2016) Confocal laser endomicroscopy in gastrointestinal and pancreatobiliary diseases: a systematic review and meta-analysis. BioMed Res Int 2016:1–31CrossRef
6.
Hua J, Gong X (2018) A normalized convolutional neural network for guided sparse depth upsampling. In: International joint conferences on artificial intelligence, pp 2283–2290
7.
Izadi S, Moriarty KP, Hamarneh G (2018) Can deep learning relax endomicroscopy hardware miniaturization requirements? In: International conference on medical image computing and computer-assisted intervention, pp 57–64. Springer
8.
Jaderberg M, Dalibard V, Osindero S, Czarnecki WM, Donahue J, Razavi A, Vinyals O, Green T, Dunning I, Simonyan K, Fernando C, Kavukcuoglu K (2017) Population based training of neural networks. arXiv preprint arXiv:​1711.​09846
9.
Janowczyk A, Madabhushi A (2016) Deep learning for digital pathology image analysis: a comprehensive tutorial with selected use cases. J Pathol Inform 7(1):29CrossRefPubMedPubMedCentral
10.
Kather JN, Weis CA, Bianconi F, Melchers SM, Schad LR, Gaiser T, Marx A, Zöllner FG (2016) Multi-class texture analysis in colorectal cancer histology. Sci Rep 6:27988CrossRefPubMedPubMedCentral
11.
Köhler R, Schuler C, Schölkopf B, Harmeling S (2014) Mask-specific inpainting with deep neural networks. In: German conference on pattern recognition, pp 523–534. Springer
12.
Le Goualher G, Perchant A, Genet M, Cavé C, Viellerobe B, Berier F, Abrat B, Ayache N (2004) Towards optical biopsies with an integrated fibered confocal fluorescence microscope. Med Image Comput Comput Assist Interv MICCAI 2004:761–768
13.
14.
Lim B, Son S, Kim H, Nah S, Lee KM (2017) Enhanced deep residual networks for single image super-resolution. In: The IEEE conference on computer vision and pattern recognition (CVPR) workshops
15.
16.
Nadaraya EA (1964) On estimating regression. Theory Probab Appl 9(1):141–142CrossRef
17.
Ravì D, Szczotka AB, Pereira SP, Vercauteren T (2019) Adversarial training with cycle consistency for unsupervised super-resolution in endomicroscopy. Med Image Anal 53:123–131CrossRefPubMedPubMedCentral
18.
Ravì D, Szczotka AB, Shakir DI, Pereira SP, Vercauteren T (2018) Effective deep learning training for single-image super-resolution in endomicroscopy exploiting video-registration-based reconstruction. Int J Comput Assist Radiol Surg 13:917–924CrossRefPubMedPubMedCentral
19.
Sundstrom A (2016) Replication Data for: histological image processing features induce a quantitative characterization of chronic tumor hypoxia. PloS one 11(4):e0153623CrossRefPubMedPubMedCentral
20.
Uhrig J, Schneider N, Schneider L, Franke U, Brox T, Geiger A (2017) Sparsity invariant cnns. In: IEEE International conference on 3D vision
21.
Vercauteren T (2008) Image registration and mosaicing for dynamic in vivo fibered confocal microscopy. Ph.D. dissertation, Equipe-Projet Asclepios, INRIA Sophia Antipolis
22.
Vercauteren T, Perchant A, Malandain G, Pennec X, Ayache N (2006) Robust mosaicing with correction of motion distortions and tissue deformations for in vivo fibered microscopy. Med Image Anal 10(5):673–692CrossRefPubMed
23.
Wang Z, Bovik AC, Sheikh HR, Simoncelli EP (2004) Image quality assessment: from error visibility to structural similarity. IEEE Trans Image Process 13(4):600–612CrossRefPubMed
24.
Zhao H, Gallo O, Frosio I, Kautz J (2017) Loss functions for image restoration with neural networks. IEEE Trans Comput Imag 3(1):47–57CrossRef
Metadata
Title
Learning from irregularly sampled data for endomicroscopy super-resolution: a comparative study of sparse and dense approaches
Authors
Agnieszka Barbara Szczotka
Dzhoshkun Ismail Shakir
Daniele Ravì
Matthew J. Clarkson
Stephen P. Pereira
Tom Vercauteren
Publication date
01-07-2020
Publisher
Springer International Publishing
Published in
International Journal of Computer Assisted Radiology and Surgery / Issue 7/2020
Print ISSN: 1861-6410
Electronic ISSN: 1861-6429
DOI
https://doi.org/10.1007/s11548-020-02170-7

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