Additive manufacturing of patient specific bolus for radiotherapy: large scale production and quality assurance
Details
Publication Year 2024-06,Volume 47,Issue #2,Page 551-561
Journal Title
Physical and Engineering Sciences in Medicine
Publication Type
Research article
Abstract
Bolus is commonly used to improve dose distributions in radiotherapy in particular if dose to skin must be optimised such as in breast or head and neck cancer. We are documenting four years of experience with 3D printed bolus at a large cancer centre. In addition to this we review the quality assurance (QA) program developed to support it. More than 2000 boluses were produced between Nov 2018 and Feb 2023 using fused deposition modelling (FDM) printing with polylactic acid (PLA) on up to five Raise 3D printers. Bolus is designed in the radiotherapy treatment planning system (Varian Eclipse), exported to an STL file followed by pre-processing. After checking each bolus with CT scanning initially we now produce standard quality control (QC) wedges every month and whenever a major change in printing processes occurs. A database records every bolus printed and manufacturing details. It takes about 3 days from designing the bolus in the planning system to delivering it to treatment. A 'premium' PLA material (Spidermaker) was found to be best in terms of homogeneity and CT number consistency (80 HU +/- 8HU). Most boluses were produced for photon beams (93.6%) with the rest used for electrons. We process about 120 kg of PLA per year with a typical bolus weighing less than 500 g and the majority of boluses 5 mm thick. Print times are proportional to bolus weight with about 24 h required for 500 g material deposited. 3D printing using FDM produces smooth and reproducible boluses. Quality control is essential but can be streamlined.
Publisher
Springer Nature
Keywords
Humans; *Printing, Three-Dimensional; Quality Assurance, Health Care/standards; Quality Control; Radiotherapy Planning, Computer-Assisted; Tomography, X-Ray Computed; Radiotherapy Dosage; Polyesters/chemistry; 3D printing; Bolus; Quality assurance; Radiotherapy; Surface guidance
Department(s)
Physical Sciences; Radiation Therapy
Open Access at Publisher's Site
https://doi.org/10.1007/s13246-024-01385-1
Terms of Use/Rights Notice
Refer to copyright notice on published article.


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Last Modified: 2024-07-30 06:34:36

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