Abstract
With the currently available materials and technologies it is difficult to mimic the mechanical properties of soft living tissues. Additionally, another significant problem is the lack of information about the mechanical properties of these tissues. Alternatively, the use of phantoms offers a promising solution to simulate biological bodies. For this reason, to advance in the state-of-the-art a wide range of organs (e.g., liver, heart, kidney as well as brain) and hydrogels (e.g., agarose, polyvinyl alcohol –PVA–, Phytagel –PHY– and methacrylate gelatine –GelMA–) were tested regarding their mechanical properties. For that, viscoelastic behavior, hardness, as well as a non-linear elastic mechanical response were measured. It was seen that there was a significant difference among the results for the different mentioned soft tissues. Some of them appear to be more elastic than viscous as well as being softer or harder. With all this information in mind, a correlation between the mechanical properties of the organs and the different materials was performed. The next conclusions were drawn: (1) to mimic the liver, the best material is 1% wt agarose; (2) to mimic the heart, the best material is 2% wt agarose; (3) to mimic the kidney, the best material is 4% wt GelMA; and (4) to mimic the brain, the best materials are 4% wt GelMA and 1% wt agarose. Neither PVA nor PHY was selected to mimic any of the studied tissues.
Highlights
The present paper aims to address several soft living tissues mimicking using different hydrogels
We aimed to mimic several soft living tissues with different materials taking into consideration several parameters: (1) viscoelastic properties using compression tests (E0 and E00 ); (2) Shore hardness; and (3) the “cut feeling” concept by carrying out the Warner–Bratzler shear test, which measured the forces profile along the cut
It was seen that the mimicking of soft living tissues is a difficult task, due to the high complexity of organs
Summary
Polymer networks that are swollen with water as the dispersion medium They are an excellent solution for different medical applications such as bone regeneration [1,2], tissue engineering [3,4] or, soft-tissue-mimicking [5]. Regarding the latter application, studying the mechanical characterization of real soft tissues is an important approach to understanding how they are deformed during different clinical scenarios such as surgeries. A possible solution could be to use surgical planning prototypes, known as phantoms, which are simulated biological bodies
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