Non-minimum phase viscoelastic properties of soft biological tissues

TL;DR

This paper investigates the non-minimum phase viscoelastic properties of soft biological tissues using a fractional dynamics model with experimental validation on porcine samples, revealing tissue-specific phase delay behaviors.

Contribution

It introduces a fractional Hilbert transform-based model to accurately represent non-minimum phase properties in biological tissues, supported by experimental data.

Findings

Some tissues exhibit larger actual phase delay than estimated from compliance.

The fractional Hilbert transform model accurately fits experimental data.

Phase delay varies across tissue types.

Abstract

Understanding the visocoelastic properties of soft biological tissues is important for progress in the field of human healthcare. This study analyzes the viscoelastic properties of soft biological tissues using a fractional dynamics model. We conducted a dynamic viscoelastic test on several porcine samples, namely liver, breast, and skeletal muscle tissues, using a plate--plate rheometer. We found that some soft biological tissues have non-minimum phase properties; that is, the relationship between compliance and phase delay is not uniquely related to the non-integer derivative order in the fractional dynamics model. The experimental results show that the actual phase delay is larger than that estimated from compliance. We propose a fractional dynamics model with the fractional Hilbert transform to represent these non-minimum phase properties. The model and experimental results were highly correlated in terms of compliance and phase diagrams and complex mechanical impedance. We also show that the amount of additional phase delay, defined as the increase in actual phase delay compared to that estimated from compliance, differs with tissue type.