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- Title
ICOSeg: Real-Time ICOS Protein Expression Segmentation from Immunohistochemistry Slides Using a Lightweight Conv-Transformer Network.
- Authors
Singh, Vivek Kumar; Sarker, Md. Mostafa Kamal; Makhlouf, Yasmine; Craig, Stephanie G.; Humphries, Matthew P.; Loughrey, Maurice B.; James, Jacqueline A.; Salto-Tellez, Manuel; O'Reilly, Paul; Maxwell, Perry
- Abstract
Simple Summary: Inducible T-cell COStimulator (ICOS) is a biomarker of interest in checkpoint inhibitor therapy, and as a means of assessing T-cell regulation as part of a complex process of adaptive immunity. The aim of our study is to segment the ICOS positive cells using a lightweight deep-learning segmentation network. We aim to assess the potential of a convolutional neural network and transformer together that permits the capture of relevant features from immunohistochemistry images. The proposed study achieved remarkable results compared to the existing biomedical segmentation methods on our in-house dataset and surpassed our previous analysis by only utilizing the Efficient-UNet network. In this article, we propose ICOSeg, a lightweight deep learning model that accurately segments the immune-checkpoint biomarker, Inducible T-cell COStimulator (ICOS) protein in colon cancer from immunohistochemistry (IHC) slide patches. The proposed model relies on the MobileViT network that includes two main components: convolutional neural network (CNN) layers for extracting spatial features; and a transformer block for capturing a global feature representation from IHC patch images. The ICOSeg uses an encoder and decoder sub-network. The encoder extracts the positive cell's salient features (i.e., shape, texture, intensity, and margin), and the decoder reconstructs important features into segmentation maps. To improve the model generalization capabilities, we adopted a channel attention mechanism that added to the bottleneck of the encoder layer. This approach highlighted the most relevant cell structures by discriminating between the targeted cell and background tissues. We performed extensive experiments on our in-house dataset. The experimental results confirm that the proposed model achieves more significant results against state-of-the-art methods, together with an 8× reduction in parameters.
- Subjects
PROTEIN metabolism; COLON tumors; DEEP learning; DIGITAL image processing; STAINS &; staining (Microscopy); IMMUNOHISTOCHEMISTRY; SLIDES (Photography); ARTIFICIAL intelligence; GENE expression; CELLULAR signal transduction; WORKFLOW; QUALITATIVE research; DESCRIPTIVE statistics; ARTIFICIAL neural networks; TUMOR markers; ALGORITHMS
- Publication
Cancers, 2022, Vol 14, Issue 16, p3910
- ISSN
2072-6694
- Publication type
Article
- DOI
10.3390/cancers14163910