Elastography of Multicellular Spheroids Using 3D Light Microscopy

Overview

Journal Biomed Opt Express

Specialty Radiology

Date 2019 May 31

PMID 31143496

Citations 9

Authors

Devina Jaiswal

Zoe Moscato

Yuji Tomizawa

Kevin P Claffey

Kazunori Hoshino

Affiliations

Soon will be listed here.

Abstract

We have demonstrated a new method of 3D elastography based on 3D light microscopy and micro-scale manipulation. We used custom-built micromanipulators to apply a mechanical force onto multicellular tumor spheroids (200-300 µm in size) and recorded the induced compression with a differential interference contrast (DIC)/confocal microscope to obtain a 4D (x, y, z, and indentation steps) image sequence. Deformation analysis made through 3D pattern tracking without using fluorescence revealed 3D structural and spatial heterogeneity in tumor spheroids. We observed a 20-30 µm-sized spot of locally-induced large deformation within a tumor spheroid. We also found solid fibroblast cores formed in a tumor-fibroblast co-culture spheroid to be stiffer than surrounding cancer cells, which would not have been discovered using only conventional fluorescence. Our new method of 3D elastography may be used to better understand structural composition in multicellular spheroids through analysis of mechanical heterogeneity.

Citing Articles

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Multiscale elasticity mapping of biological samples in 3D at optical resolution.

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Label-Free Morphological Phenotyping of In Vitro 3D Microtumors.

Moscato Z, Jaiswal D, Dixit K, Langanis C, Claffey K, Hoshino K Methods Mol Biol. 2022; 2394:31-46.

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