Estimation of Surface Dose in the Presence of Unwanted Air Gaps under the Bolus in Postmastectomy Radiation Therapy: A Phantom Dosimetric Study

Lobo, Dilson; Challapalli, Srinivas; Sourjya, Banerjee; Athiyamaan, M S; Ramamoorthy, Ravichandran; Sunny, Johan; Krishna, A.

doi:10.31557/apjcp.2022.23.9.2973

Cited by 2 publications

(2 citation statements)

References 12 publications

(22 reference statements)

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“…Several studies have suggested that air gaps can affect the dose distribution in the target area, resulting in lower-than-expected doses and decreased uniformity. 19 , 20 However, in this study, the use of SR bolus resulted in a high degree of uniformity in the target area while also meeting clinical requirements for target dosimetry, which may be due to the materials used for the bolus. SR is made using an elastic mold system, which has high flexibility, strong plasticity, resistance to warping and deformation, and low shrinkage.…”

Section: Discussionmentioning

confidence: 72%

Analysis of Individualized Silicone Rubber Bolus Using Fan Beam Computed Tomography in Postmastectomy Radiotherapy: A Dosimetric Evaluation and Skin Acute Radiation Dermatitis Survey

Chen,

Xu,

Zeng

et al. 2024

Technol Cancer Res Treat

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Objective: To investigate the dosimetric effects of using individualized silicone rubber (SR) bolus on the target area and organs at risk (OARs) during postmastectomy radiotherapy (PMRT), as well as evaluate skin acute radiation dermatitis (ARD). Methods: A retrospective study was performed on 30 patients with breast cancer. Each patient was prepared with an individualized SR bolus of 3 mm thickness. Fan-beam computed tomography (FBCT) was performed at the first and second fractions, and then once a week for a total of 5 times. Dosimetric metrics such as homogeneity index (HI), conformity index (CI), skin dose (SD), and OARs including the heart, lungs, and spinal cord were compared between the original plan and the FBCTs. The acute side effects were recorded. Results: In targets' dosimetric metrics, there were no significant differences in Dmean and V105% between planning computed tomography (CT) and actual treatments ( P > .05), while the differences in D95%, V95%, HI, and CI were statistically significant ( P < .05). In OARs, there were no significant differences between the Dmean, V5, and V20 of the affected lung, V5 of the heart and Dmax of the spinal cord ( P > .05) except the V30 of affected lung, which was slightly lower than the planning CT ( P < .05). In SD, both Dmax and Dmean in actual treatments were increased than plan A, and the difference was statistically significant ( P < .05), while the skin-V20 and skin-V30 has no difference. Among the 30 patients, only one patient had no skin ARD, and 5 patients developed ARD of grade 2, while the remaining 24 patients were grade 1. Conclusion: The OR bolus showed good anastomoses and high interfraction reproducibility with the chest wall, and did not cause deformation during irradiation. It ensured accurate dose delivery of the target and OARs during the treatment, which may increase SD by over 101%. In this study, no cases of grade 3 skin ARD were observed. However, the potential of using OR bolus to reduce grade 1 and 2 skin ARD warrants further investigation with a larger sample size.

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Section: Discussionmentioning

confidence: 72%

Analysis of Individualized Silicone Rubber Bolus Using Fan Beam Computed Tomography in Postmastectomy Radiotherapy: A Dosimetric Evaluation and Skin Acute Radiation Dermatitis Survey

Chen,

Xu,

Zeng

et al. 2024

Technol Cancer Res Treat

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“… 9 Dilson et al studied surface doses when air gap depths varied uniformly between 0 and 15 mm using 3D-CRT technology, showing varying degrees of dose increase on the surface. 28 Butson et al demonstrated that vertical beam incidence on the phantom surface results in a slight decrease in skin dose, with 90% of the maximum dose still passing through a 10-mm air gap between the bolus and skin surface. 7 Benoit et al have proven that air gaps disrupt the electron equilibrium of the radiation beam, potentially affected by factors such as photon energy, air gaps, field size, and bolus thickness, thereby re-establishing dose accumulation in near-surface regions.…”

Section: Discussionmentioning

confidence: 99%

Quantify the Effect of Air Gap Errors on Skin Dose for Breast Cancer Radiotherapy

Tang,

Yuan,

Guo

et al. 2024

Technol Cancer Res Treat

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Purpose: Determining the impact of air gap errors on the skin dose in postoperative breast cancer radiotherapy under dynamic intensity-modulated radiation therapy (IMRT) techniques. Methods: This was a retrospective study that involved 55 patients who underwent postoperative radiotherapy following modified radical mastectomy. All plans employed tangential IMRT, with a prescription dose of 50 Gy, and bolus added solely to the chest wall. Simulated air gap depth errors of 2 mm, 3 mm, and 5 mm were introduced at depression or inframammary fold areas on the skin, resulting in the creation of air gaps named Air2, Air3, and Air5. Utilizing a multivariable GEE, the average dose ( Dmean) of the local skin was determined to evaluate its relationship with air gap volume and the lateral beam's average angle (AALB). Additionally, an analysis was conducted on the impact of gaps on local skin. Results: When simulating an air gap depth error of 2 mm, the average Dmean in plan2 increased by 0.46 Gy compared to the initial plan (planO) ( p < .001). For the 3-mm air gap, the average Dmean of plan3 was 0.51 Gy higher than that of planO ( p < .001). When simulating the air gap as 5 mm, the average Dmean of plan5 significantly increased by 0.59 Gy compared to planO ( p < .001). The TCP results showed a similar trend to those of Dmean. As the depth of air gap error increases, NTCP values also gradually rise. The linear regression of the multivariable GEE equation indicates that the volume of air gaps and the AALB are strong predictors of Dmean. Conclusion: With small irregular air gap errors simulated in 55 patients, the values of skin's Dmean, TCP, and NTCP increased. A multivariable linear GEE regression model may effectively explain the impact of air gap volume and AALB on the local skin.

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Estimation of Surface Dose in the Presence of Unwanted Air Gaps under the Bolus in Postmastectomy Radiation Therapy: A Phantom Dosimetric Study

Cited by 2 publications

References 12 publications

Analysis of Individualized Silicone Rubber Bolus Using Fan Beam Computed Tomography in Postmastectomy Radiotherapy: A Dosimetric Evaluation and Skin Acute Radiation Dermatitis Survey

Analysis of Individualized Silicone Rubber Bolus Using Fan Beam Computed Tomography in Postmastectomy Radiotherapy: A Dosimetric Evaluation and Skin Acute Radiation Dermatitis Survey

Quantify the Effect of Air Gap Errors on Skin Dose for Breast Cancer Radiotherapy

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