Clinical applications of 3-dimensional printing in radiation therapy

Clinical applications of 3-dimensional printing in radiation therapy

Abstract Three-dimensional (3D) printing is suitable for the fabrication of complex radiotherapy bolus. Although investigated from dosimetric and feasibility standpoints, there are few reports to date of its use for actual patient treatment. This study illustrates the versatile applications of 3D pr...

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Veröffentlicht in:Medical dosimetry : official journal of the American Association of Medical Dosimetrists 2017, Vol.42 (2), p.150-155
Hauptverfasser: Zhao, Yizhou, M.D, Moran, Kathryn, B.Sc., RT(T), Yewondwossen, Mammo, Ph.D, Allan, James, B.Sc, Clarke, Scott, M.Sc, Rajaraman, Murali, M.D, Wilke, Derek, M.D., M.Sc, Joseph, Paul, M.D, Robar, James L., Ph.D
Format: Artikel
Sprache:eng
Schlagworte:
3D printing
ANATOMY
Biomimetic Materials
Bolus
BRACHYTHERAPY
Brachytherapy - instrumentation
Brachytherapy applicator
CARCINOMAS
COMPARATIVE EVALUATIONS
COMPLEXES
COMPUTERIZED TOMOGRAPHY
DOSE RATES
Equipment Design
EYES
FABRICATION
Female
HAZARDS
Hematology, Oncology and Palliative Medicine
Humans
INTERFACES
Male
Modulated electron radiotherapy
MYCOSES
Neoplasms - radiotherapy
NOSE
PATIENTS
PHOTONS
PLANNING
Printing, Three-Dimensional
RADIATION DOSES
Radiation Protection - instrumentation
RADIATION PROTECTION AND DOSIMETRY
Radiology
RADIOLOGY AND NUCLEAR MEDICINE
Radiotherapy Dosage
Radiotherapy Planning, Computer-Assisted - methods
Radiotherapy, Intensity-Modulated - instrumentation
Radiotherapy, Intensity-Modulated - methods
Surface brachytherapy
THICKNESS
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Zusammenfassung:Abstract Three-dimensional (3D) printing is suitable for the fabrication of complex radiotherapy bolus. Although investigated from dosimetric and feasibility standpoints, there are few reports to date of its use for actual patient treatment. This study illustrates the versatile applications of 3D printing in clinical radiation oncology through a selection of patient cases, namely, to create bolus for photon and modulated electron radiotherapy (MERT), as well as applicators for surface high-dose rate (HDR) brachytherapy. Photon boluses were 3D-printed to treat a recurrent squamous cell carcinoma (SCC) of the nasal septum and a basal cell carcinoma (BCC) of the posterior pinna. For a patient with a mycosis fungoides involving the upper face, a 3D-printed MERT bolus was used. To treat an SCC of the nose, a 3D-printed applicator for surface brachytherapy was made. The structures' fit to the anatomy and the radiotherapy treatment plans were assessed. Based on the treatment planning computed tomography (CT), the size of the largest air gap at the interface of the 3D-printed structure was 3 mm for the SCC of the nasal septum, 3 mm for the BCC of the pinna, 2 mm for the mycosis fungoides of the face, and 2 mm for the SCC of the nose. Acceptable treatment plans were obtained for the SCC of the nasal septum (95% isodose to 99.8% of planning target volume [PTV]), the BCC of the pinna (95% isodose to 97.7% of PTV), and the mycosis fungoides of the face (90% isodose to 92.5% of PTV). For the latter, compared with a plan with a uniform thickness bolus, the one featuring the MERT bolus achieved relative sparing of all the organs at risk (OARs) distal to the target volume, while maintaining similar target volume coverage. The surface brachytherapy plan for the SCC of the nose had adequate coverage (95% isodose to 95.6% of clinical target volume [CTV]), but a relatively high dose to the left eye, owing to its proximity to the tumor. 3D printing can be implemented effectively in the clinical setting to create highly conformal bolus for photon and MERT, as well as applicators for surface brachytherapy.
ISSN:0958-3947
1873-4022
DOI:10.1016/j.meddos.2017.03.001