4.6 Article

Study on the application of 3D printing head film fixation technology in cranial radiotherapy

Journal

JOURNAL OF CANCER
Volume 14, Issue 6, Pages 981-988

Publisher

IVYSPRING INT PUBL
DOI: 10.7150/jca.82909

Keywords

3D printing; traditional thermoplastic; head film; cranial radiotherapy; CBCT

Categories

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The objective of this study was to investigate the use of 3D printing technology for customizing precise radiotherapy head masks in cranial radiotherapy patients. The results showed that the 3D printing head masks had good performance in terms of deep dose attenuation, body surface dose, and positioning accuracy compared to traditional thermoplastic head films.
Objective: To investigate the use of 3D printing technology to customize individualized precise radiotherapy head masks for cranial radiotherapy patients. Through the comparison with thermoplastic head film, evaluate the effect of this material on deep dose attenuation and body surface dose, and evaluate its positioning accuracy and repeatability for clinical application.Methods: Thirty patients with head and neck radiotherapy were divided into the control group and the experimental group. The control group used the traditional thermoplastic head film fixation technique for body position fixation, and the experimental group used the 3D printing head film fixation technique. The patient setup was verified by kV-CBCT scanning to obtain the translational setup error and rotational setup error in the X, Y, and Z directions.Results: At a depth of 5 cm, both materials have a radiation attenuation rate of <1%. At the surface location, the body surface dose of control group increased by approximately 27%. With a 3D printing head film, the body surface dose increased by approximately 18%. The positioning of two groups of patients was verified by the kV-CBCT, and a total of 232 data sets were obtained. The average translation positioning errors in the X, Y, and Z direction of control group and experimental group were 1.29 mm, 1.42 mm, 1.38 mm and 1.16 mm, 1.24 mm, 1.16 mm, respectively. The average rotation positioning error in the X, Y, and Z direction of control group and experimental group were 1.29 degrees, 1.02 degrees, 1.01 degrees and 1.08 degrees, 0.96 degrees, 1.00 degrees, respectively. The translational setup errors in the Y and Z directions and rotational setup errors in the X direction significantly differed between the control and experimental groups (all p<0.05), but no statistical significance was found in the other directions (all p>0. 05). Conclusion: Compared to the traditional thermoplastic head membranes, 3D printing head membranes has shown a reliable and reproducible interactional positioning accuracy. Of course, further investigations are needed before the new technology can be used on a regular basis.

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