Resumen
(1) Background: Clinicians demand new tools for early diagnosis and improved detection
of colon lesions that are vital for patient prognosis. Optical coherence tomography (OCT) allows microscopical
inspection of tissue and might serve as an optical biopsy method that could lead to in-situ
diagnosis and treatment decisions; (2) Methods: A database of murine (rat) healthy, hyperplastic and
neoplastic colonic samples with more than 94,000 images was acquired. A methodology that includes
a data augmentation processing strategy and a deep learning model for automatic classification
(benign vs. malignant) of OCT images is presented and validated over this dataset. Comparative
evaluation is performed both over individual B-scan images and C-scan volumes; (3) Results: A
model was trained and evaluated with the proposed methodology using six different data splits
to present statistically significant results. Considering this, 0.9695 (_0.0141) sensitivity and 0.8094
(_0.1524) specificity were obtained when diagnosis was performed over B-scan images. On the other
hand, 0.9821 (_0.0197) sensitivity and 0.7865 (_0.205) specificity were achieved when diagnosis
was made considering all the images in the whole C-scan volume; (4) Conclusions: The proposed
methodology based on deep learning showed great potential for the automatic characterization of
colon polyps and future development of the optical biopsy paradigm.
Idioma original | Inglés |
---|---|
Número de artículo | 3119 |
Páginas (desde-hasta) | 3119 |
Número de páginas | 1 |
Publicación | Applied Sciences |
Volumen | 11 |
N.º | 7 |
DOI | |
Estado | Publicada - 1 abr 2021 |
Palabras clave
- Colon cancer
- Colon polyps
- OCT
- Deep learning
- Optical biopsy
- Animal rat models
- CADx
Project and Funding Information
- Project ID
- info:eu-repo/grantAgreement/EC/H2020/732111/EU/Multimodal highly-sensitive PhotonICs endoscope for improved in-vivo COLOn Cancer diagnosis and clinical decision support/PICCOLO
- Funding Info
- This work was partially supported by PICCOLO project. This project has received funding_x000D_ from the European Union’s Horizon2020 Research and Innovation Programme under grant agreement No. 732111. _x000D_ This research has also received funding from the Basque Government’s Industry Department under the ELKARTEK_x000D_ program’s project ONKOTOOLS under agreement KK-2020/00069 and the industrial doctorate program UC- DI14 of the University of Cantabria.