Complex-valued scatter compensation in nonlinear microscopy

TL;DR

This paper introduces C-DASH, a fast adaptive-optics algorithm for multi-photon microscopy that uses complex-valued light shaping to improve imaging through scattering media, outperforming phase-only methods.

Contribution

The work presents a novel complex-valued light shaping algorithm, C-DASH, for enhanced multi-photon imaging through scattering media, with faster convergence and higher image quality.

Findings

C-DASH converges faster than phase-only techniques.

It provides higher image quality enhancement.

It is robust to axial position and media variations.

Abstract

Nonlinear, i.e., multi-photon microscopy is a powerful technique for imaging deep into biological tissues. Its penetration depth can be increased further using adaptive optics. In this work, we present a fast, feedback-based adaptive-optics algorithm, termed C-DASH, for multi-photon imaging through multiply-scattering media. C-DASH utilises complex-valued light shaping (i.e., joint shaping of amplitude and phase), which offers several advantages over phase-only techniques: it converges faster, it delivers higher image quality enhancement, it shows a robust performance largely insensitive to the axial position of the correction plane, and it has a higher ability to cope with, on the one hand, scattering media that vary over time and, on the other hand, scattering media that are partially absorbing. Furthermore, our method is practically self-aligning. We also present a simple way to implement C-DASH using a single reflection off a phase-only spatial light modulator. We provide a thorough characterisation of our method, presenting results of numerical simulations as well as two-photon excited fluorescence imaging experiments.