Abstract
Digital holographic microscopy enables the recording of sample holograms which contain 3D volumetric information. However, additional optical elements, such as partially or fully coherent light source and a pinhole, are required to induce diffraction and interference. Here, we present a deep neural network based on generative adversarial network (GAN) to perform image transformation from a defocused bright-field (BF) image acquired from a general white light source to a holographic image. Training image pairs of 11,050 for image conversion were gathered by using a hybrid BF and hologram imaging technique. The performance of the trained network was evaluated by comparing generated and ground truth holograms of microspheres and erythrocytes distributed in 3D. Holograms generated from BF images through the trained GAN showed enhanced image contrast with 3–5 times increased signal-to-noise ratio compared to ground truth holograms and provided 3D positional information and light scattering patterns of the samples. The developed GAN-based method is a promising mean for dynamic analysis of microscale objects with providing detailed 3D positional information and monitoring biological samples precisely even though conventional BF microscopic setting is utilized.
Highlights
Digital holographic microscopy enables the recording of sample holograms which contain 3D volumetric information
Digital holographic microscopy (DHM) has been used in various fields including accurate biological sample monitoring[6,7,8,9,10,11,12,13,14], environmental monitoring[15,16,17], and particle or cell dynamic analysis[18,19,20], because amplitude and phase information can be noninvasively obtained from the hologram without any labeling and mechanical scanning procedures
The generated holograms demonstrate that the 3D positional information and light scattering patterns of microparticles, which cannot be obtained from original BF images, can be precisely obtained
Summary
Digital holographic microscopy enables the recording of sample holograms which contain 3D volumetric information. The overall trends of in-focused images were the same with the raw hologram results Compared with the in-focus particle images reconstructed from the ground truth holograms, the in-focus images reconstructed from the generated holograms showed reduced background noise and increased SNR values [Fig. 3d and Supplementary Fig. S1].
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