High Sensitivity and Specificity Biomechanical Imaging by Stimulated Brillouin Scattering Microscopy

TL;DR

This paper introduces stimulated Brillouin scattering (SBS) microscopy, a noncontact, label-free technique that offers high specificity and significantly faster imaging for studying biomechanical properties in biological specimens.

Contribution

The authors developed SBS microscopy with enhanced speed and specificity, enabling detailed biomechanical imaging inside large biological samples, surpassing spontaneous Brillouin microscopy capabilities.

Findings

SBS microscopy achieves >10-fold faster pixel dwell times.

It provides high mechanical specificity for biomechanical contrast.

Successful application in live nematodes demonstrates its biological relevance.

Abstract

Noncontact label-free biomechanical imaging is a crucial tool for unraveling the mechanical properties of biological systems, which play critical roles in the fields of engineering, physics, biology and medicine; yet, it represents a significant challenge in microscopy. Spontaneous Brillouin microscopy meets this challenge, but often requires long acquisition times or lacks high specificity for detecting biomechanical constituents with highly overlapping Brillouin bands. We developed stimulated Brillouin scattering (SBS) microscopy that provides intrinsic noncontact biomechanical contrast and generates mechanical cross-sectional images inside large specimens, with high mechanical specificity and pixel dwell times that are >10-fold improved over those of spontaneous Brillouin microscopy. We used SBS microscopy in different biological applications, including the quantification of the high-frequency complex longitudinal modulus of the pharyngeal region of live wild-type Caenorhabditis elegans nematodes, imaging of the variations in the high-frequency viscoelastic response to osmotic stress in the head of living worms, and in vivo mechanical contrast mesoscopy of developing nematodes