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http://dx.doi.org/10.17946/JRST.2018.41.1.61

Comparison of the Quality of Clavicle Fracture Three-dimensional Model Printing by Open Source and Commercial use Digital Imaging and Communications in Medicine Stereolithography File Conversion Program  

Oh, Wang-Kyun (Department of Radiology, Chungcheongbuk-do Cheongju Medical Center)
Kim, Hyeong-Gyun (Department of Radiological Science, Far East University)
Publication Information
Journal of radiological science and technology / v.41, no.1, 2018 , pp. 61-66 More about this Journal
Abstract
The recent 3D printing technology is used in various medical, manufacturing, and education fields and is more efficient in terms of production process, time, and cost than existing production. Especially in fracture surgery, interest and research have been focused on improving accuracy, shortening of operation time and recovery time, and reducing reoperation. However, because of the financial and technical problems of the 3D printer and the file conversion program, the 3D printing is made directly at the hospital, and it is not generally used for diagnosis of fracture and surgical research. In this study, to solve those problems, clavicle CT imaging was switched into Osirix Open Source DICOM Viewer, Stereolithography file conversion programs and commercial Terarecon 3D DICOM Viewer, file conversion programs, and then clavicle fracture model was directly made through 3D printer of fused filament fabrication wire additive processing method, and then the accuracy of the shape was compared and analyzed. Clavicle fracture models printed in two methods were blind-tested on clinicians of general hospitals' orthopedics and radiologic technicians with over 10 years of experiences, and then their analysis opinions of resolution reviews were analyzed. The result showed no difference. The 3D printing model with open source DICOM STL file conversion program used was applicable to clinical, so it is considered useful in precision diagnosis of fracture and operation plans.
Keywords
STL file; 3D Printing; DICOM Viewer; fused filament fabrication; OsiriX;
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Times Cited By KSCI : 5  (Citation Analysis)
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