The 3D printed ring-based finger splint - a cheap and lightweight alternative

The 3D printed ring-based finger splint - a cheap and lightweight alternative

Introduction and purpose The orthosis is used to assist the function of the injured limb or to stop or limit the movement during the healing process. The actual process of making the orthosis is quite time-consuming [1]. An addictive manufacturing process, known commonly as 3D printing can be adv...

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Bibliographic Details
Main Authors: Jakub Rezmer, Inga Wasilewska, Wojciech Homa, Joanna Wanat
Format: Article
Language:English
Published: Kazimierz Wielki University 2025-04-01
Series:Journal of Education, Health and Sport
Subjects:
3D printing
Finger splint
Orthosis
Customizable medical devices
Fusion Deposition Modeling
Online Access:https://apcz.umk.pl/JEHS/article/view/59425
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Summary:Introduction and purpose The orthosis is used to assist the function of the injured limb or to stop or limit the movement during the healing process. The actual process of making the orthosis is quite time-consuming [1]. An addictive manufacturing process, known commonly as 3D printing can be advantageous in creating cheap and highly customizable prosthetics. Using Fusion Deposition Modeling (FDM), where each layer of material is deposited right on the previous one is now fully available both in professional and consumer-grade printers. The main aim of this study was to create an easily customizable and cheap 3D printable finger splint with the use of Fusion Deposition Modeling technology. Material and methods BambuLab P1P 3D printer with CoreXY kinematics was used. The filament used was the 1.75mm PLA (polylactic acid). OnShape was used as CAD software. Results  Basing our project on the three rings, which dimensions can be easily measured with a set of calipers or basic measuring tape we were able to develop a fully customizable finger splint that weighed less than 10 grams and could be fully prepared within 1 hour, including taking measurements, modifying the 3D model and printing it. Due to the fact, that PLA starts to deform around 60-65 degrees Celsius, with the use of hot water we could thermoform the splint after the printing, providing an even more precise fit with the “injured” finger. Modifying every measurement and aspect of the splint is simple due to the use of parametric design rules. Conclusions We were able to create a cheap splint, easy to print, and highly customizable to fit as many different patients as possible. In our opinion, 3D printing is a promising technology. With the lowering cost of equipment and filament, one day it might be a viable option in the process of creating individualized orthosis on a mass scale.
ISSN:2391-8306

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