Nanomechanical Analysis of Extracellular Matrix and Cells in Multicellular Spheroids

Introduction Over the last decade, atomic force microscopy (AFM) has played an important role in understanding nanomechanical properties of various cancer cell lines. This study is focused on Lewis lung carcinoma cell tumours as 3D multicellular spheroid (MS). Not much is know about the mechanical p...

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Bibliographic Details
Published in:Cellular and molecular bioengineering 2019-06, Vol.12 (3), p.203-214
Main Authors: Vyas, Varun, Solomon, Melani, D’Souza, Gerard G. M., Huey, Bryan D.
Format: Article
Language:English
Subjects:
Atomic force microscopy
Biological and Medical Physics
Biomaterials
Biomedical Engineering and Bioengineering
Biomedical Engineering/Biotechnology
Biophysics
Cancer
Cell Biology
Cell membranes
Collagen
Collagenase
Constitution
Engineering
Extracellular matrix
Indentation
Lung cancer
Lung carcinoma
Lymphocytes B
Measurement methods
Mechanical properties
Replication
Spheroids
Stiffness
Tumor cell lines
Tumors
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Summary:Introduction Over the last decade, atomic force microscopy (AFM) has played an important role in understanding nanomechanical properties of various cancer cell lines. This study is focused on Lewis lung carcinoma cell tumours as 3D multicellular spheroid (MS). Not much is know about the mechanical properties of the cells and the surrounding extracellular matrix (ECM) in rapidly growing tumours. Methods Depth-dependent indentation measurements were conducted with the AFM. Force-vs.-indentation curves were used to create stiffness profiles as a function of depth. Here studies were focused on the outer most layer, i.e., proliferation zone of the spheroid. Results Both surface and sub-surface stiffness profiles of MS were created. This study revealed three nanomechanical topographies, Type A-high modulus due to collagen fibers, Type B-high stiffness at cell membrane and ECM interface and Type C-increased modulus due to cell lying deep inside matrix at a depth of 1.35  μ m. Both Type and Type-B topographies result from collagen-based structures in ECM. Conclusion This study has first time revealed mechanical constitution of an MS. Depth-dependent indentation studies have the revealed role of various molecular and cellular components responsible for providing mechanical stability to MS. Nanomechanical heterogeneities revealed in this investigation can shed new light in developing correct dosage regime for collagenase treatment of tumours and designing better controlled artificial extracellular matrix systems for replicating tissue growth in-vitro .
ISSN:1865-5025
1865-5033
DOI:10.1007/s12195-019-00577-0