Synthetic aperture phase imaging of second harmonic generation field with computational adaptive optics

Second-harmonic generation (SHG) microscopy provides label-free imaging of biological tissues with unique contrast mechanisms, but its resolution is limited by the diffraction limit. Here, we present the first experimental demonstration of super-resolution quantitative phase imaging of the SHG field based on synthetic aperture Fourier holographic microscopy. We discuss the mathematical model of synthetic-aperture imaging of SHG fields, as well as the computational adaptive optics technique for correcting sample-induced aberration. We demonstrate proof-of-concept experiments where SHG targets are embedded within a thick scattering medium to validate the performance of the proposed imaging technique. It is shown to be able to overcome the conventional Abbe diffraction limit even in the complex aberrations and strong multiple scattering. We also demonstrate SHG-based super-resolution deep-tissue phase imaging of ex-vivo zebrafish muscle tissue.