Deep imaging inside scattering media through virtual spatiotemporal wavefront shaping

The multiple scattering of light makes materials opaque and obstructs imaging. Wavefront shaping can reverse the scattering process, but imaging with physical wavefront shaping has limitations such as requiring physical guidestars, being restricted within a small isoplanatic volume, and relying on slow wavefront updates, with some approaches only working for planar targets outside the scattering media. Here, we introduce scattering matrix tomography (SMT): measure the hyperspectral scattering matrix of the sample, use it to digitally scan a synthesized confocal spatiotemporal focus and construct a volumetric image of the sample, and then use the tomograms as virtual guidestars in a nonconvex optimization to find the pulse shape, input wavefront, and output wavefront that can compensate for aberrations and scattering. SMT combines the strengths of wavefront shaping, spatiotemporal gating, and computational adaptive optics, eliminating physical guidestars and enabling digital double-path wavefront corrections tailored for every isoplanatic volume. We demonstrate sub-micron lateral resolution and one-micron axial resolution at one millimeter beneath ex vivo mouse brain tissue and over three transport mean free paths inside an opaque colloid, where existing imaging methods all fail due to the overwhelming multiple scattering. As a noninvasive and label-free method that works both inside and outside the scattering media, SMT may be applied broadly across medical imaging, biological science, device inspection, and colloidal physics.