Indentation mechanics of healthy and fibrotic murine lung reveals homogeneous surface stiffness

Quiros K, Nelson T, et al.

Results in Engineering

University of California – Riverside

RESEARCH SUMMARY

This study investigates how pulmonary fibrosis alters the microscale mechanical properties of lung tissue by performing high-resolution spherical indentation across multiple lobes in healthy and bleomycin-injured mice. Contrary to expectations that fibrotic remodeling would produce regionally heterogeneous stiffening, the findings reveal that surface stiffness remains remarkably homogeneous across the lung, even under pathologic ECM deposition. Finite element simulations and small-amplitude oscillatory indentation help decouple geometric contributions from intrinsic material behavior, showing that curvature, thickness, and inflation state strongly influence apparent stiffness. These results suggest that surface indentation alone may not capture the full mechanical consequences of fibrotic remodeling and highlight the need for depth-dependent and structural analyses when interpreting lung mechanics.

Spherical indentation experiments were performed using a CellScale MicroTester G2 equipped with a calibrated cantilever probe and displacement-controlled actuation. Lung samples—mounted at controlled inflation pressures—were indented at precise loading rates while force–displacement curves were collected in real time. The MicroTester G2 provided sub-micron displacement resolution and low-force sensitivity required to measure soft pulmonary tissue. These data were used to compute apparent elastic modulus, evaluate regional variability, and parameterize finite element models assessing curvature and thickness effects.

AUTHORS

K.A.M. Quiros, T.M. Nelson, M. Eskandari.

PUBLICATION DETAILS

JOURNAL

Results in Engineering

YEAR

2025

INSTITUTIONS

University of California – Riverside

COUNTRIES

United States

INSTRUMENT USED

MicroTester

TESTING METHODS

Compression TestingHydrated and Temperature Controlled TestingIndentation TestingViscoelastic & Time-Dependent Testing

RESEARCH APPLICATIONS

Fibrosis & Tissue RemodelingLung and Pleural Tissue Biomechanics

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