Related papers: NCIS: Deep Color Gradient Maps Regression and Three-Class Pixel Classification for Enhanced Neuronal Cell Instance Segmentation in Nissl-Stained Histological Images

NCIS: Deep Color Gradient Maps Regression and Three-Class Pixel Classification for Enhanced Neuronal Cell Instance Segmentation in Nissl-Stained Histological Images

URL: http://arxiv.org/abs/2306.15784v1
Date: Tue, 27 Jun 2023 20:22:04 GMT
Title: NCIS: Deep Color Gradient Maps Regression and Three-Class Pixel Classification for Enhanced Neuronal Cell Instance Segmentation in Nissl-Stained Histological Images
Authors: Valentina Vadori, Antonella Peruffo, Jean-Marie Gra\"ic, Livio Finos, Livio Corain, Enrico Grisan
Abstract summary: This paper presents an end-to-end framework to automatically segment single neuronal cells in Nissl-stained histological images of the brain. A U-Net-like architecture with an EfficientNet as the encoder and two decoding branches is exploited to regress four gradient color maps and classify pixels into contours between touching cells, cell bodies, or background. The method was tested on images of the cerebral cortex and cerebellum, outperforming other recent deep-learning-based approaches for the instance segmentation of cells.
Score: 0.5273938705774914
License: http://creativecommons.org/licenses/by-nc-nd/4.0/
Abstract: Deep learning has proven to be more effective than other methods in medical image analysis, including the seemingly simple but challenging task of segmenting individual cells, an essential step for many biological studies. Comparative neuroanatomy studies are an example where the instance segmentation of neuronal cells is crucial for cytoarchitecture characterization. This paper presents an end-to-end framework to automatically segment single neuronal cells in Nissl-stained histological images of the brain, thus aiming to enable solid morphological and structural analyses for the investigation of changes in the brain cytoarchitecture. A U-Net-like architecture with an EfficientNet as the encoder and two decoding branches is exploited to regress four color gradient maps and classify pixels into contours between touching cells, cell bodies, or background. The decoding branches are connected through attention gates to share relevant features, and their outputs are combined to return the instance segmentation of the cells. The method was tested on images of the cerebral cortex and cerebellum, outperforming other recent deep-learning-based approaches for the instance segmentation of cells.

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