Treatment planning for metals using an extended CT number scale

Mullins, John P.; Grams, Michael P.; Herman, Michael; Brinkmann, Debra H.; Antolak, John A.

doi:10.1120/jacmp.v17i6.6153

Cited by 31 publications

(38 citation statements)

References 14 publications

(11 reference statements)

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“…According to the CT image, the total volume of each tumor was calculated using a treatment planning system (TPS) [14]. The dose of 125 I seed implantation was prescribed as the minimal peripheral dose (MPD), which encompassed the planning treatment volume (PTV).…”

Section: Treatment Processmentioning

confidence: 99%

Efficacy of Iodine-125 Seed Implantation in Locoregionally Recurrent and Unresectable Breast Cancer: a Retrospective Study

Wei

Qin

et al. 2017

Pathol. Oncol. Res.

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The management of locoregionally recurrent and unresectable breast cancer is a therapeutic challenge. This retrospective study aimed to assess the efficacy of 125 I seed implantation brachytherapy as a palliative management in locoregionally recurrent breast cancer. We analyzed 36 locoregionally recurrent and unresectable breast cancers in our hospital between 2012 and 2016. All patients were treated with CT-guided 125 I seed permanent implantation. The dose distribution of 125 I seeds was calculated using a computerized treatment planning system. Complete response, partial response, stable disease, and local tumor control rates were calculated. Long-term efficacy was assessed based on survival rates ranging from 1 to 4 years. The follow-up period ranged from 6 to 53 months. The median local control was 28 months (95% CI: 16.2-39.8 months). The percentage of patients who showed 6-month, 1-year, 2-year, and 3-year local control was 97.2%, 77.8%, 52.8%, and 33.3%, respectively. Median survival time for all patients was 48 months (95% CI: 40.9-55.1 months); 1-year, 2-year, 3-year, and 4-year survival rates were 97.2%, 80.6%, 63.9%, and 46.5%, respectively. Pain relief response rate was 88.9%. No serious complications were detected during the follow-up period. The results of this study demonstrate that 125 I seed implantation could be considered a feasible and promising minimally invasive therapy for locoregionally recurrent and unresectable breast carcinoma.

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Section: Treatment Processmentioning

confidence: 99%

Efficacy of Iodine-125 Seed Implantation in Locoregionally Recurrent and Unresectable Breast Cancer: a Retrospective Study

Wei

Qin

et al. 2017

Pathol. Oncol. Res.

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“…4 CT scanners with 12-bit depth DICOM images truncated at 3,071 HU limit their ability to analyse high-density materials. [3][4][5]10,11 High-density materials have high linear attenuation coefficients that lie outside of the Figure 1. Variation of bit depth and greyscale level.…”

Section: Introductionmentioning

confidence: 99%

“…CT scanners with 12-bit depth DICOM images truncated at 3,071 HU limit their ability to analyse high-density materials 3 5 , 10 , 11 High-density materials have high linear attenuation coefficients that lie outside of the 12-bit CT number. Current advancements in CT scanners allow the range of the 12-bit raw data to be extended using a reconstruction algorithm to apply information on high-density materials.…”

Section: Introductionmentioning

confidence: 99%

“…Current advancements in CT scanners allow the range of the 12-bit raw data to be extended using a reconstruction algorithm to apply information on high-density materials. This amends the initial slope by expanding the HU range ten-fold (e.g., ranging from -10,240 to 30,710) 10 . In contrast, scanners with full 16-bit DICOM images (16-bit signed integer) yield 65,535 values (2 16 ) ranging from -32,768 to 32,767 HU, which is a much larger scale compared to that provided by the reconstruction algorithm for the 12-bit system.…”

Section: Introductionmentioning

confidence: 99%

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Determination of computed tomography number of high-density materials in 12-bit, 12-bit extended and 16-bit depth for dosimetric calculation in treatment planning system

et al. 2019

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AimThe main aim was to examine the effect of bit depth on computed tomography (CT) number for high-density materials. Analysis of the CT number for high-density materials using 16-bit scanners will extend the CT scale that currently exists for 12-bit scanners and thus will be beneficial for use in CT–electron density (ED) curve in radiotherapy treatment planning system (TPS). Implementation of this extended CT scale will compensate for tissue heterogeneity during CT–ED conversion in treatment planning.Materials and methodsAn in-house built phantom with 10 different metal samples was scanned using 80, 100 and 120 kVp in two different CT scanners. A region of interest was set at the centre of the material and the mean CT numbers together with data deviation were determined. Dosimetry calculation was performed by applying a direct anterior beam on 12-bit, 12-bit extended and 16-bit.ResultsHigh-density materials (>4·34 g cm−3) in 16-bit depth provide disparities up to 44% compared to Siemens’ 12-bit extended. Influence of tube voltage showed a significant difference (p<0·05) in both bit depth and CT number of the gold and amalgam saturated in 16-bit depth. A 120 kVp energy illustrated a low variation on CT number for different scanners, but dosimetry calculation showed significant disparities at the metal interface in 12-bit, 12-bit extended and 16-bit.FindingsHigh-density materials require 16-bit scanners to obtain CT number to be implemented in treatment planning in radiotherapy. This also suggests that proper tube voltage together with correct CT–ED resulted in accurate TPS algorithm calculation.

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“…16-bit CT reconstruction corrected using metal artifact reduction (MAR) reconstruction techniques may minimize the effects of artifacts on image quality. 10,11 However, even with accurate CT information, convolution dose calculation algorithms are not designed for use with high-Z materials. 12,13 Previous literature has proposed various solutions dealing with TEs in a radiation treatment planning systems (TPS).…”

Section: Introductionmentioning

confidence: 99%

Modeling AeroForm tissue expander for postmastectomy radiation therapy

Dziemianowicz

Gardner

Snyder

et al. 2019

J Applied Clin Med Phys

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The AeroForm chest wall tissue expander (TE) is a silicon shell containing a metallic CO 2 reservoir, placed surgically after mastectomy. The patient uses a remote control to release compressed CO 2 from the reservoir to inflate the expander. AeroForm poses challenges in a radiation therapy setting: The high density of the metallic reservoir causes imaging artifacts on the planning CT, which encumber structure definition and cause misrepresentation of density information, in turn affecting dose calculation. Additionally, convolution‐based dose calculation algorithms may not be well‐suited to calculate dose in and around high‐density materials. In this study, a model of the AeroForm TE was created in Eclipse treatment planning system (TPS). The TPS model was validated by comparing measured to calculated transmission through the AeroForm. Transmission was measured with various geometries using radiochromic film. Dose was calculated with both Varian’s Anisotropic Analytical Algorithm (AAA) and Acuros External Beam (AXB) algorithms. AAA and AXB were compared using dose profile and gamma analyses. While both algorithms modeled direct transmission well, AXB better modeled lateral scatter from the AeroForm TE. Clinical significance was evaluated using clinical data from four patients with AeroForm TEs. The AeroForm TPS model was applied, and RT plans were optimized using AAA, then re‐calculated with AXB. Structures of clinical significance were defined and dose volume histogram analysis was performed. Compared to AXB, AAA overestimates dose in the AeroForm device. Changes in clinically significant regions were patient‐ and plan‐specific. This study proposes a clinical procedure for modeling the AeroForm in a commercial TPS, and discusses the limitations of dose calculation in and around the device. An understanding of dose calculation accuracy in the vicinity of the AeroForm is critical for assessing individual plan quality, appropriateness of different planning techniques and dose calculation algorithms, and even the decision to use the AeroForm in a postmastectomy radiation therapy setting.

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Treatment planning for metals using an extended CT number scale

Cited by 31 publications

References 14 publications

Efficacy of Iodine-125 Seed Implantation in Locoregionally Recurrent and Unresectable Breast Cancer: a Retrospective Study

Efficacy of Iodine-125 Seed Implantation in Locoregionally Recurrent and Unresectable Breast Cancer: a Retrospective Study

Determination of computed tomography number of high-density materials in 12-bit, 12-bit extended and 16-bit depth for dosimetric calculation in treatment planning system

Modeling AeroForm tissue expander for postmastectomy radiation therapy

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