PEER-REVIEWED PUBLICATION

2025

Cell Spheroid Micromechanics under Large Deformations

Giannopoulos D, Schlittler M, et al.

Scientific Reports

TU Wien, University of Florence, Eurac Research

RESEARCH SUMMARY

This study establishes a new mechanical framework for quantifying large-strain compression behavior in 3D cell spheroids, advancing micromechanical characterization at physiologically relevant deformations. Human primary cardiac fibroblast spheroids were compressed up to 50% strain using parallel-plate microcompression and analyzed via a nonlinear hyperelastic contact model (extended Tatara). The study compared classical Hertzian, Ding, and Tatara models against the extended formulation, revealing that traditional Hertz-based models significantly overestimate apparent moduli under large deformations. The extended Tatara model, incorporating Mooney–Rivlin hyperelasticity and lateral expansion effects, achieved superior fits (R² ≈ 0.99) across 10–50% strain, providing more accurate apparent modulus and Poisson’s ratio estimates (≈0.43). These findings clarify nonlinear deformation mechanisms in soft biological aggregates, supporting precise biomechanical modeling of cardiac fibrosis progression and tissue remodeling.

Parallel-plate compression experiments were conducted using a CellScale MicroSquisher with tungsten cantilevers (0.203 mm diameter, 0.6 µN sensitivity) in PBS at 37 °C. Each spheroid was compressed to 50% apparent strain at displacement rates of 0.5–5 µm s⁻¹, with force–displacement data collected via SquisherJoy software and fitted to four contact models (Hertz, Ding, Tatara, extended Tatara) using MATLAB. The extended Tatara model best described hyperelastic and geometrically nonlinear responses, yielding apparent moduli of 2–4 kPa. Image segmentation quantified lateral expansion to derive Poisson’s ratio (~0.43), demonstrating the MicroSquisher’s precision for subcellular-scale, viscoelastic tissue mechanics.

AUTHORS

Dimosthenis Giannopoulos, Maja Schlittler, Marzia De Bortoli, Raffaele Coppini, Mina Petrovic, Elisabetta Cerbai, Gerhard J. Schütz, Philipp J. Thurner, Alessandra Rossini, Orestis G. Andriotis.

PUBLICATION DETAILS

JOURNAL

Scientific Reports

YEAR

2025

INSTITUTIONS

TU Wien, University of Florence, Eurac Research

COUNTRIES

Austria, Italy

INSTRUMENT USED

MicroSquisher

TESTING METHODS

Compression TestingHydrated and Temperature Controlled TestingMicro-Mechanical TestingUltra Low Force Testing

RESEARCH APPLICATIONS

Cardiac Tissue Engineering & MechanicsFibrosis & Tissue RemodelingMechanotransductionMicrotissue and Spheroid MechanicsOrganoid and Tissue Mimetic Systems

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