[1] W FOO, A WIEDE, S BIERWIRTH, al. et. Automated multicolor mesoscopic imaging for the 3-dimensional reconstruction of fluorescent biomarker distribution in large tissue specimens. Biomedical Optics Express, 13, 3723-3742(2022).
[2] S GAO, M LI, N I NIZAM et al. End-to-end reconstruction for mesoscopic fluorescence molecular tomography via deep learning. communications, 562, 29-35(2021).
[3] F YANG, M S OZTURK, L ZHAO et al. High-resolution mesoscopic fluorescence molecular tomography based on compressive sensing. IEEE Transactions on Biomedical Engineering, 62, 248-255(2014).
[4] S BJÖRN, K H ENGLMEIER, V NTZIACHRISTOS et al. Reconstruction of fluorescence distribution hidden in biological tissue using mesoscopic epifluorescence tomography. Journal of Biomedical Optics, 16, 046005(2011).
[5] Y CHEN, D FAULKNER, F YANG. Parallel fast 3D reconstruction for tumor microvascular network in mesoscopic fluorescent molecular tomography, JTh2A. 17(2020).
[6] I COSTANTINI, E BARIA, M SORELLI et al. MAGIC: a label-free fluorescence method for 3D high-resolution reconstruction of myelinated fibers in large volumes.
[7] M SCARDIGLI, L PESCE, N BRADY et al. Comparison of different tissue clearing methods for three-dimensional reconstruction of human brain cellular anatomy using advanced imaging techniques. Frontiers in Neuroanatomy, 15, 752234(2021).
[8] J J FIELD, J A SQUIER, R A BARTELS. Fluorescent coherent diffractive imaging with accelerating light sheets. Optics Express, 27, 13015-13030(2019).
[9] V NTZIACHRISTOS, D RAZANSKY. Molecular imaging by means of multispectral optoacoustic tomography (MSOT). Chemical Reviews, 110, 2783-2794(2010).
[10] M REN, J CHEN, D CHEN et al. Aberration-free 3D imaging via DMD-based two-photon microscopy and sensorless adaptive optics. Optics Letters, 45, 2656-2659(2020).
[11] M LEVOY, R NG, A ADAMS et al. Light field microscopy, 924-934(2006).
[12] M BROXTON, L GROSENICK, S YANG et al. Wave optics theory and 3-D deconvolution for the light field microscope. Optics Express, 21, 25418-25439(2013).
[13] Z WANG, L ZHU, H ZHANG et al. Real-time volumetric reconstruction of biological dynamics with light-field microscopy and deep learning. Nature Methods, 18, 551-556(2021).
[14] T NÖBAUER, Y ZHANG, H KIM et al. Mesoscale volumetric light-field (MesoLF) imaging of neuroactivity across cortical areas at 18 Hz. Nature Methods, 20, 600-609(2023).
[15] Y XUE, I G DAVISON, D A BOAS et al. Single-shot 3D wide-field fluorescence imaging with a computational miniature mesoscope. Science Advances, 6, eabb7508(2020).
[16] H LI, C GUO, D KIM-HOLZAPFEL et al. Fast, volumetric live-cell imaging using high-resolution light-field microscopy. Biomedical Optics Express, 10, 29-49(2019).
[17] S WANG, B LI, F ZHANG. Molecular fluorophores for deep-tissue bioimaging. ACS Central Science, 6, 1302-1316(2020).
[18] M ROSSI, P FROSSARD. Graph-based light field super-resolution, 1-6(2017).
[19] H LI, Y YU, J PENG et al. Resolution improvement of light field imaging via a nematic liquid crystal microlens with added multi-walled carbon nanotubes. Sensors, 20, 5557(2020).
[20] M S IFTHEKHAR, M A HOSSAIN, C H HONG et al. Radiometric and geometric camera model for optical camera communications, 53-57(2015).
[21] R J CLEMENTS, M DAVIDSON, M A MODEL. Experimental test of the geometric model of image formation in bright-field microscopy. Journal of Microscopy, 283, 3-8(2021).
[22] J WU, Z LU, D JIANG et al. Iterative tomography with digital adaptive optics permits hour-long intravital observation of 3D subcellular dynamics at millisecond scale. Cell, 184, 3318-3332(2021).
[23] J WU, Y GUO, C DENG et al. An integrated imaging sensor for aberration-corrected 3D photography. Nature, 612, 62-71(2022).
