DEVELOPMENT OF AN ULTRASOUND PHANTOM WITH MODIFIED VISCOSITY TO SIMULATE HUMAN SOFT TISSUE

Authors

DOI:

https://doi.org/10.59485/d7f2e938

Keywords:

Ultrasonic Phantom, viscosity, PVA, 3D Printing, Medical Calibration

Abstract

The diagnostic accuracy and success of ultrasound-based intervention procedures depend heavily on the quality of device calibration and the expertise of medical personnel. The development of ultrasound phantoms that can realistically replicate the  acoustic  and  mechanical  properties  of human  soft  tissue  is  a  crucial  requirement  in  medical  education  and  the standardisation of electromedical technology. This study aims to develop and evaluate a method for producing soft tissue USG phantoms with modified viscosity and elasticity using polyvinyl alcohol (PVA) material, as well as integrating 3D printing technology to  achieve  anatomical  accuracy.  The phantoms  were  developed using  a mixture  of low  and  high viscosity PVA variants with the addition of ethylene glycol as a freeze-protectant. The fabrication process was carried out through a strictly controlled freeze-thaw cycle to manipulate the shear modulus and viscosity separately. Characterisation was performed through longitudinal sound velocity measurements (frequency 5–20 MHz), microstructure evaluation with a scanning electron microscope (SEM), and viscoelastic property testing using shear wave viscoelastography based on the Kelvin-Voigt model. The results show that the use of cryoprotectant produces a more homogeneous microstructure with a shear modulus of approximately 2.17 kPa and a viscosity of approximately 2.0 Pa · s, which is close to the physiological characteristics of human soft tissue. Acoustic parameters showed a sound velocity ranging from  1510–1571 m/s with an attenuation exponent of 1.23–1.38 dB/cm/MHz, meeting clinical range standards. The integration of natural fibres into the bio-elastomer matrix successfully created anisotropic properties resembling fibrous tissues such as muscle. The independent viscosity modification approach and the use of additive manufacturing provide a flexible platform for producing high- precision ultrasonic phantoms. This innovation  supports the development of standardised and safe clinical intervention training  tools,  as  well  as  reliable  calibration  instruments  for  the  development  of  future  imaging  techniques  such  as elastography.

 

Keywords: Ultrasonic Phantom, viscosity, PVA, 3D Printing, Medical Calibration.

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References

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Published

2026-06-29

How to Cite

DEVELOPMENT OF AN ULTRASOUND PHANTOM WITH MODIFIED VISCOSITY TO SIMULATE HUMAN SOFT TISSUE. (2026). MEDIKA TRADA, 7(1), 69-76. https://doi.org/10.59485/d7f2e938