Optical microscopy is an indispensable tool in biomedical sciences,but its reach in deep tissues is limited due to aberrations and scattering.This problem can be overcome by wavefront-shaping techniques,albeit at limi...Optical microscopy is an indispensable tool in biomedical sciences,but its reach in deep tissues is limited due to aberrations and scattering.This problem can be overcome by wavefront-shaping techniques,albeit at limited fields of view(FOVs).Inspired by astronomical imaging,conjugate wavefront shaping can lead to an increased field of view in microscopy,but this correction is limited to a set depth and cannot be dynamically adapted.Here,we present a conjugate wavefront-shaping scheme based on focus scanning holographic aberration probing(F-SHARP).We combine it with a compact implementation that can be readily adapted to a variety of commercial and home-built two-photon microscopes.We demonstrate the power of the method by imaging with high resolution over extended FOV(>80μm)deeper than 400μm inside a mouse brain through a thinned skull.展开更多
基金funding by the German Science Foundation DFG(projects 326649520 and 327654276/SFB 1315)the Human Frontiers Science Programme+1 种基金a Starting Grant by the European Research Council(ERC-2016-StG-714560)the Alfried Krupp Prize for Young University Teachers,awarded by the Alfried Krupp von Bohlen und Halbach-Stiftung.
文摘Optical microscopy is an indispensable tool in biomedical sciences,but its reach in deep tissues is limited due to aberrations and scattering.This problem can be overcome by wavefront-shaping techniques,albeit at limited fields of view(FOVs).Inspired by astronomical imaging,conjugate wavefront shaping can lead to an increased field of view in microscopy,but this correction is limited to a set depth and cannot be dynamically adapted.Here,we present a conjugate wavefront-shaping scheme based on focus scanning holographic aberration probing(F-SHARP).We combine it with a compact implementation that can be readily adapted to a variety of commercial and home-built two-photon microscopes.We demonstrate the power of the method by imaging with high resolution over extended FOV(>80μm)deeper than 400μm inside a mouse brain through a thinned skull.