We present a high-throughput computational imaging system capable of performing dense, volumetric fluorescence imaging of freely moving organisms at up to 120 volumes per second. Our method, termed 2pi Fourier light field tomography (2pi-FLIFT), consists of a planar array of 54 cameras and a parabolic mirror serving as the primary objective that allows for synchronized multi-view video capture over ~2pi steradians. 2pi-FLIFT features a novel 3D reconstruction algorithm that recovers both the 3D fluorescence distribution and attenuation map of dynamic samples. We demonstrate 2pi-FLIFT on important, freely moving model organisms, such as zebrafish and fruit fly larvae.
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