Using computed tomography and 3D printing to construct custom prosthetics attachments and devices

Background The prosthetic devices the military uses to restore function and mobility to our wounded warriors are highly advanced, and in many instances not publically available. There is considerable research aimed at this population of young patients who are extremely active and desire to take part...

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Bibliographic Details
Published in:3D printing in medicine 2017-08, Vol.3 (1), p.8-8, Article 8
Main Authors: Liacouras, Peter C., Sahajwalla, Divya, Beachler, Mark D., Sleeman, Todd, Ho, Vincent B., Lichtenberger, John P.
Format: Article
Language:English
Subjects:
3-D printers
Accessories
Biomaterials
Biomedical Engineering and Bioengineering
Computed tomography
Devices
Engineers
Imaging
Medicine
Medicine & Public Health
Military applications
Printing
Prostheses
Prosthetics
Radiology
Recovery of function
Surface geometry
Surgery
Three dimensional models
Three dimensional printing
Titanium alloys
Titanium base alloys
Tomography
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Summary:Background The prosthetic devices the military uses to restore function and mobility to our wounded warriors are highly advanced, and in many instances not publically available. There is considerable research aimed at this population of young patients who are extremely active and desire to take part in numerous complex activities. While prosthetists design and manufacture numerous devices with standard materials and limb assemblies, patients often require individualized prosthetic design and/or modifications to enable them to participate fully in complex activities. Methods Prosthetists and engineers perform research and implement digitally designs in collaboration to generate equipment for their patient’s rehabilitation needs. 3D printing allows for these devices to be manufactured from an array of materials ranging from plastic to titanium alloy. Many designs require form fitting to a prosthetic socket or a complex surface geometry. Specialty items can be scanned using computed tomography and digitally reconstructed to produce a virtual 3D model the engineer can use to design the necessary features of the desired prosthetic, device, or attachment. Completed devices are tested for fit and function. Results Numerous custom prostheses and attachments have been successfully translated from the research domain to clinical reality, in particular, those that feature the use of computed tomography (CT) reconstructions. The purpose of this project is to describe the research pathways to implementation for the following clinical designs: sets of bilateral hockey skates; custom weightlifting prosthetic hands; and a wine glass holder. Conclusion This article will demonstrate how to incorporate CT imaging and 3D printing in the design and manufacturing process of custom attachments and assistive technology devices. Even though some of these prosthesis attachments may be relatively simple in design to an engineer, they have an enormous impact on the lives of our wounded warriors.
ISSN:2365-6271
2365-6271
DOI:10.1186/s41205-017-0016-1