Adaptive Optical Third-harmonic Generation Microscopy for in Vivo Imaging of Tissues

Overview

Journal bioRxiv

Date 2024 May 15

PMID 38746456

Authors

Cristina Rodriguez

Daisong Pan

Ryan G Natan

Manuel A Mohr

Max Miao

Xiaoke Chen

Trent R Northen

John P Vogel

Na Ji

Affiliations

Soon will be listed here.

Abstract

Third-harmonic generation microscopy is a powerful label-free nonlinear imaging technique, providing essential information about structural characteristics of cells and tissues without requiring external labelling agents. In this work, we integrated a recently developed compact adaptive optics module into a third-harmonic generation microscope, to measure and correct for optical aberrations in complex tissues. Taking advantage of the high sensitivity of the third-harmonic generation process to material interfaces and thin membranes, along with the 1,300-nm excitation wavelength used here, our adaptive optical third-harmonic generation microscope enabled high-resolution in vivo imaging within highly scattering biological model systems. Examples include imaging of myelinated axons and vascular structures within the mouse spinal cord and deep cortical layers of the mouse brain, along with imaging of key anatomical features in the roots of the model plant . In all instances, aberration correction led to significant enhancements in image quality.

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