Abstract
Recent soft tissue studies have reported issues that occur during experimentation, such as the tissue slipping and rupturing during tensile loads, the lack of standard testing procedure and equipment, the necessity for existing laboratory equipment adaptation, etc. To overcome such issues and fulfil the need for the determination of the biomechanical properties of the human gracilis and the superficial third of the quadriceps tendons, 3D printed clamps with metric thread profile-based geometry were developed. The clamps’ geometry consists of a truncated pyramid pattern, which prevents the tendons from slipping and rupturing. The use of the thread application in the design of the clamp could be used in standard clamping development procedures, unlike in previously custom-made clamps. Fused deposition modeling (FDM) was used as a 3D printing technique, together with polylactic acid (PLA), which was used as a material for clamp printing. The design was confirmed and the experiments were conducted by using porcine and human tendons. The findings justify the usage of 3D printing technology for parts manufacturing in the case of tissue testing and establish independence from the existing machine clamp system, since it was possible to print clamps for each prepared specimen and thus reduce the time for experiment setup.
Highlights
In the paper presented by Scholze et al [17], the authors used quasistatic tensile tests combined with digital image correlation and fatigue trials to characterize the applicability of the current clamping technique using 3D printed clamps
They reported that the 3D printed clamps showed no signs of clamping-related failure during the quasistatic tests and the fatigue tests and that the material slippage was low
Could the clamp geometry be based on the mechanical engineering field and possibly be used in consideration for the future standardization of procedure, since there are currently no standards used in tissue testing?
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. In the paper presented by Scholze et al [17], the authors used quasistatic tensile tests combined with digital image correlation and fatigue trials to characterize the applicability of the current clamping technique using 3D printed clamps They reported that the 3D printed clamps showed no signs of clamping-related failure during the quasistatic tests and the fatigue tests and that the material slippage was low. Sci. 2021, 11, 2563 highly adaptable to the varying specimen geometries and are ideal for high-standardization and high-throughput experiments in soft tissue biomechanics They used a clamp design with 4-sided pyramid structures in a cross-sectional view. Could the clamp geometry be based on the mechanical engineering field and possibly be used in consideration for the future standardization of procedure, since there are currently no standards used in tissue testing?
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