【 摘 要 】

BackgroundAn external fixator is an orthopaedic device used to stabilize long bone fractures after high energy trauma. These devices are external to the body and fixed to metal pins going into non-injured areas of bone. They serve a mechanical function to maintain length, prevent bending, and resist torque forces about the fracture area. The purpose of this manuscript is to describe a design and prototyping process creating a low-cost entirely 3-D printed external fixator for fracture stabilization of extremity fractures. The secondary objective of this manuscript is to facilitate future advancements, modifications, and innovations in this area of 3-D printing in medicine.MethodsThis manuscript describes the computer aided design process using desktop fused deposition modeling to create a 3-D printed external fixator system designed for fracture stabilization. The device was created using the orthopaedic goals for fracture stabilization with external fixation. However, special modifications and considerations had to be accounted for given the limitations of desktop fused deposition modeling and 3-D printing with plastic polymers.ResultsThe presented device accomplishes the goals of creating a construct that can be attached to 5.0 mm metal pins, allows for modularity in placement orientations, and facilitates adjustable lengths for fracture care. Furthermore, the device provides length stability, prevention of bending, and resists torque forces. The device can be printed on a desktop 3-D printer using standard low-cost polylactic acid filament. The print time is less than two days and can be completed on one print bed platform.ConclusionsThe presented device is a potential alternative for fracture stabilization. The concept of a desktop 3-D printed external fixator design and method of production allows for numerous diverse applications. This includes assisting areas with remote or limited access to advanced medical care and large-scale natural disasters or global conflicts where large volumes of fractures exceed the local medical supply chain capabilities. The presented device creates a foundation for future devices and innovations in this fracture care space. Further research is needed on mechanical testing and clinical outcomes with this design and initiative in fracture care before clinical application.

【 授权许可】

CC BY   
© The Author(s) 2023

【 预 览 】

附件列表

Files	Size	Format	View
RO202309078384862ZK.pdf	1980KB	PDF	download
Fig. 2	621KB	Image	download
Fig. 2	221KB	Image	download
Fig. 4	3514KB	Image	download
40854_2023_495_Article_IEq32.gif	1KB	Image	download
Fig. 5	389KB	Image	download
MediaObjects/12974_2023_2824_MOESM1_ESM.tiff	6070KB	Other	download
Fig. 7	49KB	Image	download
Fig. 19	48KB	Image	download
40517_2023_252_Article_IEq41.gif	1KB	Image	download
40517_2023_252_Article_IEq82.gif	1KB	Image	download
40517_2023_252_Article_IEq109.gif	1KB	Image	download
Fig. 2	415KB	Image	download

【 图 表 】

Fig. 2

40517_2023_252_Article_IEq109.gif

40517_2023_252_Article_IEq82.gif

40517_2023_252_Article_IEq41.gif

Fig. 19

Fig. 7

Fig. 5

40854_2023_495_Article_IEq32.gif

Fig. 4

Fig. 2

Fig. 2

【 参考文献 】

• [1]
• [2]
• [3]
• [4]
• [5]
• [6]
• [7]
• [8]
• [9]
• [10]
• [11]
• [12]
• [13]
• [14]
• [15]
• [16]
• [17]
• [18]
• [19]
• [20]