Three‐dimensional printing in radiation oncology: A systematic review of the literature

Rooney, Michael K.; Rosenberg, David M.; Braunstein, Steve; Cunha, Adam; Damato, Antonio L.; Ehler, E.; Pawlicki, Todd; Robar, James L.; Tatebe, K.; Golden, Daniel W.

doi:10.1002/acm2.12907

Cited by 48 publications

(79 citation statements)

References 57 publications

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“…Three-dimensional printing in radiation oncology is still in its infancy with potential applications undiscovered. The most common uses include creation of quality assurance phantoms and custom bolus [6] , with rare reports of custom shielding [11] , [12] , [13] . This report describes a novel technique for patient-specific scalp-shielding in TSEBT using 3D-printing which provided similar hair-preservation as would be expected for lead shielding, with the added benefit of customized shielding at the hairline.…”

Section: Discussionmentioning

confidence: 99%

“…Two patients have been treated with this technique thus far; one patient underwent shielding for the entire course with promising results. Application of 3D-printing in radiation oncology has been expanding since its introduction several years ago given the promise of patient-specific conformality, ease of production, and cost-effectiveness [6] ; however, it has not been studied in scalp shielding for total skin treatments.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Technical report: 3D-printed patient-specific scalp shield for hair preservation in total skin electron beam therapy

Rahimy

Skinner

Kim

et al. 2021

Technical Innovations & Patient Support in Radiation Oncolo

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Technical report: 3D-printed patient-specific scalp shield for hair preservation in total skin electron beam therapy

Rahimy

Skinner

Kim

et al. 2021

Technical Innovations & Patient Support in Radiation Oncolo

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“…This is explained by some centralization of mechanical support services to larger centers for the design/fabrication of specialized devices, with 70% of small centers in Ontario (<6 Linacs) reporting that they no longer have any in‐house mechanical engineering (or machinist) staff. The widespread adoption of IMRT and volumetric modulated arc therapy (VMAT) has greatly reduced the need for custom‐made devices, while the introduction of 3D printers has simplified the fabrication of selected custom‐made accessories 23 . Furthermore, modern Linacs have less requirements for complex mechanical procedures to access components during routine servicing (e.g., hoisting the Linac head).…”

Section: Discussionmentioning

confidence: 99%

“…The widespread adoption of IMRT and volumetric modulated arc therapy (VMAT) has greatly reduced the need for custom‐made devices, while the introduction of 3D printers has simplified the fabrication of selected custom‐made accessories. 23 Furthermore, modern Linacs have less requirements for complex mechanical procedures to access components during routine servicing (e.g., hoisting the Linac head). Indeed, many facilities have integrated the positions of mechanical and electronics engineering to a single classification of a service engineer, following the example set by Linac vendors.…”

Section: Discussionmentioning

confidence: 99%

COMP Report: An updated algorithm to estimate medical physics staffing levels for radiation oncology

Malkoske

Sixel

Hunter

et al. 2021

J Applied Clin Med Phys

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Purpose Medical physics staffing models require periodic review due to the rapid evolution of technology and clinical techniques in radiation oncology. We present an update to a grid‐based physics staffing algorithm for radiation oncology (originally published in 2012) that has been widely used in Canada over the last decade. Materials and Methods The physics staffing algorithm structure was modified to improve the clarity and consistency of input data. We collected information on clinical procedures, equipment inventory, and teaching activities from 15 radiation treatment centers in the province of Ontario from April 1, 2018, to March 31, 2019. Using these data sets, the algorithm's weighting parameters were adjusted to align the prediction of full‐time equivalent (FTE) personnel with actual staffing levels in Ontario. The algorithm computes FTE estimates for medical physicists, physics assistants, engineering (electrical and mechanical), and information technology (IT) support. The performance of the algorithm was also tested in eight Canadian cancer centers outside of Ontario. Results The mean difference between the algorithm and actual staffing for the 23 Canadian cancer centers did not exceed 0.5 FTE for any staffing group. The results were slightly better in Ontario than in other provinces, as expected since the algorithm was optimized using Ontario data. There was a linear correlation between the algorithm predictions and the number of annual‐treated cases for physicists, and physicists plus physics assistants. For other staff categories, the algorithm weighting parameters were not significantly altered, except for a reduction in mechanical engineering staff. Comparison with other published models suggests that the updated algorithm should be considered as a minimum recommended staffing level for the clinical support of radiation oncology programs. Conclusions We support the use of grid‐based physics staffing algorithms that account for clinical workload with flexibility to adapt to local conditions with variable academic and research demands.

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“…Within cancer applications, recent advances include the use of 3D-printed template-assisted CT-guided radioactive seed for radiation therapy, where the printed template was personalized and supported more targeted radiation. However, these clinical studies utilizing 3D-printed platforms are still in their early stages, with a small number of patients, and might not be indicative of their long-term and wide-spread clinical performances [ 96 , 97 ]. In bone regeneration applications, large animal models had been studied with a 3D-printed bioceramic scaffold, implanted via surgical procedures.…”

Section: Challenges and Prospectsmentioning

confidence: 99%

Advances in 3D-Printed Surface-Modified Ca-Si Bioceramic Structures and Their Potential for Bone Tumor Therapy

et al. 2021

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Bioceramics such as calcium silicate (Ca-Si), have gained a lot of interest in the biomedical field due to their strength, osteogenesis capability, mechanical stability, and biocompatibility. As such, these materials are excellent candidates to promote bone and tissue regeneration along with treating bone cancer. Bioceramic scaffolds, functionalized with appropriate materials, can achieve desirable photothermal effects, opening up a bifunctional approach to osteosarcoma treatments—simultaneously killing cancerous cells while expediting healthy bone tissue regeneration. At the same time, they can also be used as vehicles and cargo structures to deliver anticancer drugs and molecules in a targeted manner to tumorous tissue. However, the traditional synthesis routes for these bioceramic scaffolds limit the macro-, micro-, and nanostructures necessary for maximal benefits for photothermal therapy and drug delivery. Therefore, a different approach to formulate bioceramic scaffolds has emerged in the form of 3D printing, which offers a sustainable, highly reproducible, and scalable method for the production of valuable biomedical materials. Here, calcium silicate (Ca-Si) is reviewed as a novel 3D printing base material, functionalized with highly photothermal materials for osteosarcoma therapy and drug delivery platforms. Consequently, this review aims to detail advances made towards functionalizing 3D-printed Ca-Si and similar bioceramic scaffold structures as well as their resulting applications for various aspects of tumor therapy, with a focus on the external surface and internal dispersion functionalization of the scaffolds.

show abstract

Three‐dimensional printing in radiation oncology: A systematic review of the literature

Cited by 48 publications

References 57 publications

Technical report: 3D-printed patient-specific scalp shield for hair preservation in total skin electron beam therapy

Technical report: 3D-printed patient-specific scalp shield for hair preservation in total skin electron beam therapy

COMP Report: An updated algorithm to estimate medical physics staffing levels for radiation oncology

Advances in 3D-Printed Surface-Modified Ca-Si Bioceramic Structures and Their Potential for Bone Tumor Therapy

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