High-Resolution Lensless Microscopy Imaging Based on Fluorescence Intermittency.

IF 2.3

Journal of biophotonics Pub Date : 2025-04-21 DOI:10.1002/jbio.70036

Zhiping Zeng, Xinyi Chen, Biqing Xu, Jin Qiu, Yantang Huang, Canhua Xu

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Abstract

Lensless imaging microscopy has gained extensive application with the merits of system compactness and cost efficiency; however, its spatial resolution is usually compromised compared to conventional lens-based microscopes. To further enhance the spatial resolution, we built a lensless imaging system integrating a phase mask and a CMOS image sensor, and employed fluorescence fluctuation super-resolution microscopy (FF-SRM) algorithms to fully exploit the fluorescence intermittency (FI) characteristics of fluorescent molecules for high-resolution lensless image reconstruction. The study demonstrates that lensless image sequences processed by the Wiener deconvolution method can effectively retain the original fluorescence intermittency information, allowing for high-resolution reconstruction using FF-SRM algorithms. Furthermore, by combining expansion microscopy (ExM) and leveraging multi-algorithm synergy, we obtained additional improvements in spatial resolution and image quality for lensless imaging, facilitating clear visualization of biological subcellular organelles. This scheme offers a new pathway to achieve high spatial resolution imaging with practical advantages in simplicity and affordability.

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基于荧光间歇的高分辨率无透镜显微镜成像。

无透镜成像显微镜以其系统紧凑、性价比高的优点得到了广泛的应用；然而，与传统的基于透镜的显微镜相比，它的空间分辨率通常会受到损害。为了进一步提高空间分辨率，我们构建了一种集成相位掩模和CMOS图像传感器的无透镜成像系统，并采用荧光波动超分辨率显微镜（FF-SRM）算法，充分利用荧光分子的荧光间歇性（FI）特性进行高分辨率无透镜图像重建。研究表明，通过维纳反卷积方法处理的无透镜图像序列可以有效地保留原始荧光间歇信息，从而允许使用FF-SRM算法进行高分辨率重建。此外，通过结合扩展显微镜（ExM）和利用多算法协同，我们获得了无透镜成像的空间分辨率和图像质量的进一步提高，促进了生物亚细胞细胞器的清晰可视化。该方案具有简单、经济等优点，为实现高空间分辨率成像提供了新的途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of biophotonics

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