Electron microscopy imaging and mechanical characterization of T47D multicellular tumor spheroids-Older spheroids reduce interstitial space and become stiffer

Multicellular cancer spheroids are an in vitro tissue model that mimics the three-dimensional microenvironment. As spheroids grow, they develop the gradients of oxygen, nutrients, and catabolites, affecting crucial tumor characteristics such as proliferation and treatment responses. The measurement...

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Bibliographic Details
Published in:PloS one 2023-05, Vol.18 (5), p.e0286291-e0286291
Main Authors: Madhavan, Mathangi, Jaiswal, Devina, Karlberg, Sarah, Duggan, Alexis, Almarshad, Hassan A, Claffey, Kevin P, Hoshino, Kazunori
Format: Article
Language:English
Subjects:
Biology and Life Sciences
Breast cancer
Cancer therapies
Care and treatment
Catabolites
Cell culture
Cells
Diameters
Drug delivery systems
Drugs
Electron microscopy
Evaluation
Growth models
Humans
Hypoxia
Image resolution
Mechanical properties
Medical equipment and supplies industry
Medical imaging
Medical test kit industry
Medicine and Health Sciences
Metabolism
Methylene blue
Microenvironments
Microscopy
Microscopy, Electron
Modulus of elasticity
Multicellular tumor spheroids
Neoplasms
Nutrients
Oxygen
Patient outcomes
Physical Sciences
Physiology
Radiation
Research and Analysis Methods
Spheroids
Spheroids, Cellular
Stiffness
Transmission electron microscopy
Tumor Microenvironment
Tumors
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Summary:Multicellular cancer spheroids are an in vitro tissue model that mimics the three-dimensional microenvironment. As spheroids grow, they develop the gradients of oxygen, nutrients, and catabolites, affecting crucial tumor characteristics such as proliferation and treatment responses. The measurement of spheroid stiffness provides a quantitative measure to evaluate such structural changes over time. In this report, we measured the stiffness of size-matched day 5 and day 20 tumor spheroids using a custom-built microscale force sensor and conducted transmission electron microscopy (TEM) imaging to compare the internal structures. We found that older spheroids reduce interstitial spaces in the core region and became significantly stiffer. The measured elastic moduli were 260±100 and 680±150 Pa, for day 5 and day 20 spheroids, respectively. The day 20 spheroids showed an optically dark region in the center. Analyzing the high-resolution TEM images of spheroid middle sections across the diameter showed that the cells in the inner region of the day 20 spheroids are significantly larger and more closely packed than those in the outer regions. On the other hand, the day 5 spheroids did not show a significant difference between the inner and outer regions. The observed reduction of the interstitial space may be one factor that contributes to stiffer older spheroids.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0286291