Practical guidelines for cell segmentation models under optical aberrations in microscopy.

Comput Struct Biotechnol J

Zhejiang Key Laboratory of Imaging and Interventional Medicine, Zhejiang Engineering Research Center of Interventional Medicine Engineering and Biotechnology, The Fifth Affiliated Hospital of Wenzhou Medical University, Lishui 323000, China.

Published: December 2024

AI Article Synopsis

  • Cell segmentation is crucial in biomedical research, and deep learning, specifically CNNs, has significantly improved this process; however, challenges remain with optical aberrations in microscopy.
  • This study assesses segmentation models under various simulated optical aberrations using datasets from fluorescence and bright field microscopy, testing methods like Mask R-CNN and Otsu threshold.
  • The research introduces the Point Spread Function Image Label Classification Model (PLCM) for identifying aberrations, offers best practices for using segmentation tools like Cellpose 2.0, and recommends model combinations that effectively handle aberrated cell images.

Article Abstract

Cell segmentation is essential in biomedical research for analyzing cellular morphology and behavior. Deep learning methods, particularly convolutional neural networks (CNNs), have revolutionized cell segmentation by extracting intricate features from images. However, the robustness of these methods under microscope optical aberrations remains a critical challenge. This study evaluates cell image segmentation models under optical aberrations from fluorescence and bright field microscopy. By simulating different types of aberrations, including astigmatism, coma, spherical aberration, trefoil, and mixed aberrations, we conduct a thorough evaluation of various cell instance segmentation models using the DynamicNuclearNet (DNN) and LIVECell datasets, representing fluorescence and bright field microscopy cell datasets, respectively. We train and test several segmentation models, including the Otsu threshold method and Mask R-CNN with different network heads (FPN, C3) and backbones (ResNet, VGG, Swin Transformer), under aberrated conditions. Additionally, we provide usage recommendations for the Cellpose 2.0 Toolbox on complex cell degradation images. The results indicate that the combination of FPN and SwinS demonstrates superior robustness in handling simple cell images affected by minor aberrations. In contrast, Cellpose 2.0 proves effective for complex cell images under similar conditions. Furthermore, we innovatively propose the Point Spread Function Image Label Classification Model (PLCM). This model can quickly and accurately identify aberration types and amplitudes from PSF images, assisting researchers without optical training. Through PLCM, researchers can better apply our proposed cell segmentation guidelines. This study aims to provide guidance for the effective utilization of cell segmentation models in the presence of minor optical aberrations and pave the way for future research directions.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11461983PMC
http://dx.doi.org/10.1016/j.csbj.2024.09.002DOI Listing

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