P Reich scite author profile

In this study, we investigate whether an acceptable dosimetric plan can be obtained for a surface applicator designed using photogrammetry and compare the plan quality to a CT-derived applicator. The nose region of a RANDO anthropomorphic phantom was selected as the treatment site due to its high curvature. Photographs were captured using a Nikon D5600 DSLR camera and reconstructed using Agisoft Metashape while CT data was obtained using a Canon Aquillion scanner. Virtual surface applicators were designed in Blender and printed with ABS plastic. Treatment plans with a prescription dose of 3.85 Gy x 10 fractions with 100 % dose to PTV on the bridge of the nose at 2 mm depth were generated separately using AcurosBV in the Varian BrachyVision TPS. PTV D 98% , D 90% and V 100% , and OAR D 0.1cc , D 2cc and V 50% dose metrics and dwell times were evaluated, with the applicator t assessed by air-gap volume measurements. Both types of surface applicators were printed with minimal defects and visually tted well to the target area. The measured air-gap volume between the photogrammetry applicator and phantom surface was 44 % larger than the CT-designed applicator, with a mean air gap thickness of 3.24 and 2.88 mm, respectively. The largest difference in the dose metric observed for the PTV and OAR was the PTV V 100% of -1.27 % and skin D 0.1cc of -0.28 %. PTV D 98% and D 90% and OAR D 2cc and V 50% for the photogrammetry based plan were all within 0.5 % of the CT based plan. Total dwell times were also within 5 %. A 3D printed surface applicator for the nose was successfully constructed using photogrammetry techniques. Although it produced a larger air gap between the surface applicator and phantom surface, a clinically acceptable dose plan was created with similar PTV and OAR dose metrics to the CT-designed applicator. Additional future work is required to comprehensively evaluate its suitability in a clinically environment.

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Verification of dose delivery for a prostate sIMRT treatment using a SLIC–EPID

Mohammadi

Bezak

Reich

2008

Applied Radiation and Isotopes

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P Reich

Evaluation of camera settings for photogrammetric reconstruction of humanoid phantoms for EBRT bolus and HDR surface brachytherapy applications

A dosimetric comparison of CT- and photogrammetry- generated 3D printed HDR brachytherapy surface applicators

Verification of dose delivery for a prostate sIMRT treatment using a SLIC–EPID

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