Low-cost optical scanner and 3-dimensional printing technology to create lead shielding for radiation therapy of facial skin cancer: First clinical case series

Sharma, Ankur; Sasaki, David; Rickey, Daniel W.; Leylek, Ahmet; Harris, Chad; Johnson, Kate; Aviles, Jorge E. Alpuche; McCurdy, Boyd; Egtberts, Andy; Koul, Rashmi; Dubey, Arbind

doi:10.1016/j.adro.2018.02.003

Cited by 25 publications

(27 citation statements)

References 29 publications

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“…Furthermore, because the surface-scanner is used freehand, the patient is not restricted to a specific position, improving patient anatomy scan “access” and comfort. The scan can be stopped and continued, which would be impossible using a consumer-grade scanner such as the one described by Sharma et al [ 5 ]. It is possible with the high-end 3D-scanner tested to acquire images of large anatomical sites (e.g.…”

Section: Discussionmentioning

confidence: 99%

“…Several non-expensive 3D-scanners can be found on the market. One has recently been tested on patients, for other purposes than the production of bolus, and needed a workaround for its use [ 5 ] (construction of a gantry support for the 3D-scanner, allowing a restricted angle of scan). Another scanner was tested on a dark phantom, Alderson RANDO® phantom, (The Phantom Laboratory, Salem, NY, USA) which needed to be powder sprayed because the 3D-scanner was not able to scan dark surfaces [ 6 ].…”

Section: Introductionmentioning

confidence: 99%

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Improving 3D-printing of megavoltage X-rays radiotherapy bolus with surface-scanner

et al. 2018

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BackgroundComputed tomography (CT) data used for patient radiotherapy planning can nowadays be used to create 3D-printed boluses. Nevertheless, this methodology requires a second CT scan and planning process when immobilization masks are used in order to fit the bolus under it for treatment.This study investigates the use of a high-grade surface-scanner to produce, prior to the planning CT scan, a 3D-printed bolus in order to increase the workflow efficiency, improve treatment quality and avoid extra radiation dose to the patient.MethodsThe scanner capabilities were tested on a phantom and on volunteers. A phantom was used to produce boluses in the orbital region either from CT data (resolution ≈1 mm), or from surface-scanner images (resolution 0.05 mm). Several 3D-printing techniques and materials were tested. To quantify which boluses fit best, they were placed on the phantom and scanned by CT. Hounsfield Unit (HU) profiles were traced perpendicular to the phantom’s surface. The minimum HU in the profiles was compared to the HU values for calibrated air-gaps. Boluses were then created from surface images of volunteers to verify the feasibility of surface-scanner use in-vivo.ResultsPhantom based tests showed a better fit of boluses modeled from surface-scanner than from CT data. Maximum bolus-to-skin air gaps were 1-2 mm using CT models and always < 0.6 mm using surface-scanner models. Tests on volunteers showed good and comfortable fit of boluses produced from surface-scanner images acquired in 0.6 to 7 min. Even in complex surface regions of the body such as ears and fingers, the high-resolution surface-scanner was able to acquire good models. A breast bolus model generated from images acquired in deep inspiration breath hold was also successful. None of the 3D-printed bolus using surface-scanner models required enlarging or shrinking of the initial model acquired in-vivo.ConclusionsRegardless of the material or printing technique, 3D-printed boluses created from high-resolution surface-scanner images proved to be superior in fitting compared to boluses created from CT data. Tests on volunteers were promising, indicating the possibility to improve overall radiotherapy treatments, primarily for megavoltage X-rays, using bolus modeled from a high-resolution surface-scanner even in regions of complex surface anatomy.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Improving 3D-printing of megavoltage X-rays radiotherapy bolus with surface-scanner

et al. 2018

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“…Beyond phantoms, 3D printing has been investigated for radiation therapy immobilization devices, bolus, electron blocks, and other treatment aids. In fact, the strongest argument for clinical acquisition of 3D printing technology is for the fabrication of treatment devices due to the unique nature of patient anatomy and the high frequency of use of treatment devices.…”

Section: Opening Statementsmentioning

confidence: 99%

3D printing technology will eventually eliminate the need of purchasing commercial phantoms for clinical medical physics QA procedures

Ehler

Craft

Rong

2018

J Applied Clin Med Phys

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“…A structured light scanner that employs an infrared light source and camera, along with an optical camera to capture color information (Sense 3D Scanner, 3D Systems, USA) was used in this work. We have previously described the commissioning, operation and accuracy of this device . As the intention of this project at our center was to increase efficiency, the optical scanner was used whenever possible as it can be operated by only one therapist in a standard examination room.…”

Section: Methodsmentioning

confidence: 99%

“…To date a handful of authors have investigated their use for patient position monitoring, improving the extended field‐of‐view in computed tomography (CT) and total body irradiation (TBI) compensator design . We have previously documented the use of this technology to help streamline our lead shielding fabrication process for orthovoltage treatments …”

Section: Introductionmentioning

confidence: 99%

A modern mold room: Meshing 3D surface scanning, digital design, and 3D printing with bolus fabrication

Sasaki

McGeachy²,

Aviles

et al. 2019

J Applied Clin Med Phys

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Purpose This case series represents an initial experience with implementing 3‐dimensional (3D) surface scanning, digital design, and 3D printing for bolus fabrication for patients with complex surface anatomy where traditional approaches are challenging. Methods and Materials For 10 patients requiring bolus in regions with complex contours, bolus was designed digitally from 3D surface scanning data or computed tomography (CT) images using either a treatment planning system or mesh editing software. Boluses were printed using a fused deposition modeling printer with polylactic acid. Quality assurance tests were performed for each printed bolus to verify density and shape. Results For 9 of 10 patients, digitally designed boluses were used for treatment with no issues. In 1 case, the bolus was not used because dosimetric requirements were met without the bolus. QA tests revealed that the bulk density was within 3% of the reference value for 9 of 12 prints, and with more judicious selection of print settings this could be increased. For these 9 prints, density uniformity was as good as or better than our traditional sheet bolus material. The average shape error of the pieces was less than 0.5 mm, and no issues with fit or comfort were encountered during use. Conclusions This study demonstrates that new technologies such as 3D surface scanning, digital design and 3D printing can be safely and effectively used to modernize bolus fabrication.

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Low-cost optical scanner and 3-dimensional printing technology to create lead shielding for radiation therapy of facial skin cancer: First clinical case series

Cited by 25 publications

References 29 publications

Improving 3D-printing of megavoltage X-rays radiotherapy bolus with surface-scanner

Improving 3D-printing of megavoltage X-rays radiotherapy bolus with surface-scanner

3D printing technology will eventually eliminate the need of purchasing commercial phantoms for clinical medical physics QA procedures

A modern mold room: Meshing 3D surface scanning, digital design, and 3D printing with bolus fabrication

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