主成分分析
计算机科学
稳健性(进化)
显微镜
人工智能
图像分辨率
计算机视觉
稳健主成分分析
迭代重建
模式识别(心理学)
光学
物理
化学
生物化学
基因
作者
Jiaming Qian,Weiyi Xia,Yuxia Huang,Jing Feng,Qian Chen,Chao Zuo
标识
DOI:10.1038/s41377-025-01979-8
摘要
Three-dimensional structured illumination microscopy (3DSIM) is an essential super-resolution imaging technique for visualizing volumetric subcellular structures at the nanoscale, capable of doubling both lateral and axial resolution beyond the diffraction limit. However, high-quality 3DSIM reconstruction is often hindered by uncertainties in experimental parameters, such as optical aberrations and fluorescence density heterogeneity. Here, we present PCA-3DSIM, a novel 3DSIM reconstruction framework that extends principal component analysis (PCA) from two-dimensional (2D) to three-dimensional (3D) super-resolution microscopy. To further compensate spatial nonuniformities of illumination parameters, PCA-3DSIM can be implemented in an adaptive tiled-block manner. By segmenting raw volumetric data into localized subsets, PCA-3DSIM enables accurate parameter estimation and effective interference rejection for high-fidelity, artifact-free 3D super-resolution reconstruction, with the inherent efficiency of PCA supporting the tiled reconstruction with limited computational burden. Experimental results demonstrate that PCA-3DSIM provides reliable reconstruction performance and improved robustness across diverse imaging scenarios, from custom-built platforms to commercial systems. These results establish PCA-3DSIM as a flexible and practical tool for super-resolved volumetric imaging of subcellular structures, with broad potential applications in biomedical research. This article developed PCA-3DSIM, a mathematically grounded enhancement to 3D structured illumination microscopy that improves robustness by integrating physical modeling with statistical analysis.
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