Additive Manufacturing of a Miniature Functional Trocar for Eye Surgery.

Kirsten Lussenburg,Aimée Sakes,Paul Breedveld,Marta Scali

doi:10.3389/fmedt.2022.842958

Kirsten Lussenburg, Aimée Sakes + Show 2 more

Open Access

https://doi.org/10.3389/fmedt.2022.842958

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Abstract

Stereolithography is emerging as a promising additive manufacturing technology for a range of applications in the medical domain. However, for miniature, medical devices such as those used in ophthalmic surgery, a number of production challenges arise due to the small size of the components. In this work, we investigate the challenges of creating sub-millimeter features for a miniature, functional trocar using Stereolithography. The trocar cannula system is used in eye surgery to facilitate a passage for other instruments. A standard trocar consists of a hollow cannula and a flexible check valve. The research was performed in two stages: in the first stage we investigated the effect of different materials and print settings on the current design of the cannula and the valve separately, and in the second stage we used these findings to optimize the design and production process. After the first investigation, it became apparent that even though the dimensions of the trocar are within the feature size range of Stereolithography, all hollow features tended to fuse shut during printing. This effect appeared regardless of the materials or print settings, and can be attributed to refraction of the laser source. In order to circumvent this, we identified two potential strategies: (1) increasing the negative space surrounding features; and (2) decreasing the surface area per layer. By applying these strategies, we tested a new design for the cannula and valve and managed to 3D print a functional trocar, which was tested in an artificial eye. The design of the 3D printed trocar allows for further personalization depending on the specific requirements of both patient and surgeon. The proposed strategies can be applied to different applications to create miniature features using Stereolithography.

Highlights

Additive manufacturing (AM) or 3D printing offers great flexibility in creating and producing complex parts and mechanisms
The higher force can be attributed to the larger wall thickness, which results in a larger step-difference between the knife inserter and the trocar, as well as the “ribbed” outer wall that results from the helix design
We attempted to 3D print a functional trocar intended for use in eye surgery, consisting of a hollow, stiff cannula, and a flexible valve

Summary

Introduction

Additive manufacturing (AM) or 3D printing offers great flexibility in creating and producing complex parts and mechanisms. For ophthalmic surgical instruments, which are often in the sub-millimeter-scale range, it is important that AM technologies offer accuracy and repeatability, in addition to a small manufacturing size. Processing (DLP), have become popular in the medical domain Their popularity can be attributed to a high resolution, currently in the range of 25 μm [6,7,8], and the availability of biocompatible materials [6]. Because of these factors, SLA and DLP are widely accepted in the medical domain, for applications ranging from patient specific implants to anatomical models [6, 9]

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