High-speed 4D fluorescence light field tomography of whole freely moving organisms

Kevin C Zhou, Clare Cook, Archan Chakraborty, Jennifer Bagwell, Joakim Jönsson, Kyung Chul Lee, Xi Yang, Shiqi Xu, Ramana Balla, Mark Harfouche, Donald T Fox, Michel Bagnat, Roarke Horstmeyer
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Abstract

Volumetric fluorescence imaging techniques, such as confocal, multiphoton, light sheet, and light field microscopy, have become indispensable tools across a wide range of cellular, developmental, and neurobiological applications. However, it is difficult to scale such techniques to the large 3D fields of view (FOV), volume rates, and synchronicity requirements for high-resolution 4D imaging of freely behaving organisms. Here, we present reflective Fourier light field computed tomography (ReFLeCT), a new high-speed volumetric fluorescence computational imaging technique. ReFLeCT synchronously captures entire tomograms of multiple unrestrained, unanesthetized model organisms over multi-millimeter 3D FOVs at 120 volumes per second. In particular, we applied ReFLeCT to reconstruct 4D videos of fluorescently labeled zebrafish and Drosophila larvae, enabling us to study their heartbeat, fin and tail motion, gaze, jaw motion, and muscle contractions with nearly isotropic 3D resolution while they are freely moving. As a novel approach for snapshot tomographic capture, ReFLeCT is a major advance towards bridging the gap between current volumetric fluorescence microscopy techniques and macroscopic behavioral imaging.
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对整个自由移动的生物体进行高速 4D 荧光光场断层扫描
共聚焦、多光子、光片和光场显微镜等体积荧光成像技术已成为细胞、发育和神经生物学等广泛应用中不可或缺的工具。然而,这些技术很难达到自由行为生物体高分辨率 4D 成像所需的大三维视场(FOV)、容积率和同步性要求。在此,我们介绍一种新型高速容积荧光计算成像技术--反射傅立叶光场计算机断层扫描(ReFLeCT)。ReFLeCT 以每秒 120 卷的速度同步捕捉多个无束缚、无麻醉的模型生物在多毫米三维视场上的整个断层图。特别是,我们应用 ReFLeCT 重建了荧光标记斑马鱼和果蝇幼虫的 4D 视频,使我们能够在它们自由活动时以近乎各向同性的三维分辨率研究它们的心跳、鳍和尾部运动、凝视、下颌运动和肌肉收缩。作为一种新颖的快照断层捕捉方法,ReFLeCT 是弥合当前体积荧光显微镜技术与宏观行为成像之间差距的一大进步。
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