Force interaction, modeling and soft tissue deformation during reciprocating insertion of multi-part probe

TL;DR

This study investigates the mechanics of reciprocating probe insertion into soft tissue, combining modeling and experiments to understand force interactions and tissue deformation, inspired by ovipositing wasps.

Contribution

It introduces a reciprocal insertion model and experimental analysis to elucidate tissue interaction mechanisms during reciprocating insertion.

Findings

Reciprocal motion reduces peak force by approximately 19%.

Average tissue displacement decreases by about 20%.

Modeling and experiments provide insights into force mechanics during insertion.

Abstract

The bio-inspired engineering of ovipositing wasps, which employ a reciprocating motion for soft tissue insertion, offers potential advantages in reducing insertion force and minimizing tissue damage. However, the underlying mechanisms of tissue interaction and sparing are not fully understood. In this study, we aim to investigate a multi-part probe designed to mimic the reciprocating motion of ovipositors. A reciprocal insertion model was developed to study the interaction between the probe and soft tissue, and experimental testing was conducted using a force sensor and laser optical technique to gain insights into interacting forces and tissue deformation. The results reveal that during the cutting phase of reciprocal motion, the peak force and average displacement of the soft substrate were approximately 19% and 20% lower, respectively, compared to direct insertion at an overall probe velocity of 1 mm/s. This study presents a novel approach combining mechanical modeling and experimental analysis to explore the force mechanics of the reciprocating insertion method, providing a better understanding of the interaction between the probe and soft tissue.