Crossover frequency as a model-independent viscoelastic constant for soft tissue biomechanics
Ruhland L, Schattenfroh J, Guo J, Sack I, Willner K (2026)
Publication Type: Journal article
Publication year: 2026
Journal
DOI: 10.1016/j.actbio.2026.07.002
Abstract
Magnetic resonance elastography (MRE) and related elastography techniques are emerging as quantitative diagnostic tools for assessing tissue microstructure and pathology. To determine descriptive parameters of the tissues’ properties, a frequency-dependent viscoelastic material model is required, which is calibrated to the measured response in a parameter identification process. However, the selection of this model and the fitting strategy is challenging, since it may influence the identified viscoelastic parameters notably. Here, we address this limitation by proposing the crossover frequency (fc, defined as the frequency at which storage and loss moduli intersect G′(fc)=G′′(fc)) as a model-independent viscoelastic constant for soft tissues. Fresh porcine specimens of the corona radiata, the putamen, the thalamus, and the liver were investigated using tabletop MRE and the frequency-dependent viscoelasticity was characterized with a fractional Kelvin-Voigt model. By validating the crossover frequency against the viscoelastic parameters, we demonstrated that the crossover frequency accurately reflects the viscoelastic behavior, independent of the material model or the fitting strategy. Across all samples, fc distinguished brain regions and separated brain from liver tissue by median frequencies of 85 Hz (95 % CI: 69-269Hz) in the corona radiata, 423 Hz (95 % CI: 316-575Hz) in the putamen, 426 Hz (95 % CI: 302-601Hz) in the thalamus and 1174 Hz (95 % CI: 1074-1300Hz) in the liver (p <0.001). These results suggest that crossover frequencies capture distinct viscoelastic fingerprints without requiring viscoelastic model selection. The crossover frequency may therefore serve as a practical, model-independent biomaterial constant to improve comparability of viscoelastic measurements across elastography studies.
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APA:
Ruhland, L., Schattenfroh, J., Guo, J., Sack, I., & Willner, K. (2026). Crossover frequency as a model-independent viscoelastic constant for soft tissue biomechanics. Acta Biomaterialia. https://doi.org/10.1016/j.actbio.2026.07.002
MLA:
Ruhland, Laura, et al. "Crossover frequency as a model-independent viscoelastic constant for soft tissue biomechanics." Acta Biomaterialia (2026).
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