A multi-modal microscope for integrated mapping of cellular forces and Brillouin scattering with high resolution

Andrew T Meek, Franziska Busse, Nils M Kronenberg, San Vinh Dinh, Kim V Berghaus, Jonathan H Booth, Giuliano Scarcelli, Malte C Gather*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract

Mechanical forces and stiffness play key roles in the health and development of cells and tissue, but despite the physical connection between these quantities, they cannot be monitored in parallel in most cases. Here, we introduce a fully integrated microscope that combines a method for high-resolution cell force imaging (elastic resonator interference stress microscopy, ERISM) with non-contact mapping of the elastic properties of cells (via Brillouin microscopy). In order to integrate both techniques, we had to account for the strong back reflection on the surface of the microcavity used for ERISM measurements as well as the local destruction of the cavity under illumination for Brillouin microscopy measurements. Therefore, we developed an elastic optical microcavity with minimal absorption that can perform ERISM measurements without sustaining laser damage during Brillouin microscopy. Furthermore, an unequal-arm Michelson interferometer was designed to suppress the back reflection of the laser on the ERISM microcavity surface using division by amplitude interference to reduce the reflected light and enhance the Brillouin signal. We show the utility of our integrated microscope by simultaneously mapping cellular forces and Brillouin shifts in cultures of fibroblast cells.
Original languageEnglish
Article number025012
Number of pages14
JournalJournal of Physics: Photonics
Volume6
Issue number2
Early online date23 Apr 2024
DOIs
Publication statusPublished - Apr 2024

Keywords

  • Mechanobiology
  • Integrated microscope
  • Brillouin microscopy
  • Cellular forces
  • Multi-modal

Fingerprint

Dive into the research topics of 'A multi-modal microscope for integrated mapping of cellular forces and Brillouin scattering with high resolution'. Together they form a unique fingerprint.

Cite this