Unsupervised learning of pixel clustering in Mueller matrix images for mapping microstructural features in pathological tissues

Hematoxylin-eosin staining is the gold standard for anatomic pathology as the general stain for histological examination of human tissue. Birefringent property is a valuable and commonly used metric for characterizing the anisotropic structure of tissue. When assessing the birefringent property of tissue slices, unstained slice is often preferred to avoid the potential effects of staining dyes. However, obtaining high-quality adjacent tissue samples is often difficult due to possible distortion, rotation, and uneven thickness of the tissue slices during sample preparation. In this study, we measure the Mueller matrix images of the unstained, hematoxylin stained, eosin stained, and hematoxylin-eosin stained tissue slices using the transmission Mueller matrix microscope developed in our previous study. Then the Mueller matrix polar decomposition parameter of linear phase retardance is calculated to describe the linear birefringent property of tissue. It is shown that the linear birefringent property is enhanced by the combination of dye molecules and birefringent structures, which may be due to the parallel attachment of the dye molecules to the fibers. To evaluate in detail the contrast consistency of tissue linear birefringence imaging from differently stained slices, we perform a similarity analysis using the Bhattacharyya coefficient, which demonstrated that hematoxylin, eosin, and hematoxylin-eosin staining do not generate linear birefringent property on region of tissue samples without birefringent structures. Therefore, it can be acceptable to prepare hematoxylin-eosin stained slice to obtain both bright field image and linear phase retardance image simultaneously for digital pathologic diagnosis.

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Identification of microalgal particles using pixel feature analysis of Mueller matrix images

Cui,

Wan,

et al. 2024

Appl. Opt.

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Fine sorting of aquatic particles is of great significance for water environment monitoring. Natural water contains aquatic particles that exhibit a high degree of diversity and complexity, and the identification of aquatic particles remains a persistent challenge in the field. In this article, we propose a new technique for identifying the target species of microalgal particles by using the pixel feature analysis of Mueller matrix images. This technique is independent of any prior knowledge or data about the existing particles in the environment, which is advantageous when applied to real-world situations. The pixel-level polarimetric features are fully leveraged to construct polarization feature templates, which can be used to characterize and filter specific microalgal particles in complex environments. This method could enable the accurate detection of harmful algal blooms species in natural water, which can facilitate early warning of algal blooms. The preliminary results show that the recall rate reached 97.2%, and the average accuracy is 98.9%, which demonstrate the effectiveness of this approach for identifying the target species of aquatic particles in natural water.

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Unsupervised learning of pixel clustering in Mueller matrix images for mapping microstructural features in pathological tissues

Cited by 5 publications

References 42 publications

Non-Generative Artificial Intelligence (AI) in Medicine: Advancements and Applications in Supervised and Unsupervised Machine Learning

Non-Generative Artificial Intelligence (AI) in Medicine: Advancements and Applications in Supervised and Unsupervised Machine Learning

Effect of hematoxylin and eosin staining on tissue linear birefringence imaging: a case study

Identification of microalgal particles using pixel feature analysis of Mueller matrix images

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