A New Proton Therapy Solution Provides Superior Cardiac Sparing Compared With Photon Therapy in Whole Lung Irradiation for Pediatric Tumor Patients

• Published in: Frontiers in oncology Vol. 10; p. 611514
• Main Authors: Sha, Xue, Duan, Jinghao, Lin, Xiutong, Zhu, Jian, Zhang, Ruohui, Sun, Tao, Wang, Hui, Meng, Xiangjuan, Yin, Yong
• Format: Journal Article
• Language: English
• Published: Switzerland Frontiers Media S.A 02.02.2021
• Subjects: cardiac sparing; Oncology; pediatric tumor; photon radiotherapy; proton radiotherapy; whole lung irradiation; proton radiotherapy; cardiac sparing; pediatric tumor; whole lung irradiation; photon radiotherapy
• ISSN: 2234-943X; 2234-943X
• DOI: 10.3389/fonc.2020.611514

Whole lung irradiation (WLI) plays a crucial role in local control in pediatric patients with lung metastases and improves patient survival. The intention of this research was to explore the advantage of cardiac sparing between photons and protons during WLI. We also propose a new solution for cardiac sparing with proton techniques. Eleven patients with pediatric tumors and pulmonary metastasis treated with 12 Gy WLI (all received volumetric-modulated arc therapy (VMAT)) in our institute between 2010 and 2019 were retrospectively selected. Each patient was replanned with intensity-modulated radiation therapy (IMRT), helical tomotherapy (HT), and two intensity-modulated proton radiotherapy (IMPT) plans (IMPT-1 and IMPT-2). IMPT-1 considered the whole lung as the planning target volume (PTV), utilizing the anteroposterior technique (0/180°). IMPT-2 was a new proton solution that we proposed in this research. This approach considered the unilateral lung as the PTV, and 3 ipsilateral fields were designed for each lung. Then, IMPT-2 was generated by summing two unilateral lung plans. The primary objective was to obtain adequate coverage (95% of the prescription dose to the PTV) while maximally sparing the dose to the heart. The PTV coverage, conformity index (CI), homogeneity index (HI), and dose-volume statistics of the heart and substructures were assessed by means of the averages of each comparison parameter. All treatment techniques achieved the target volume coverage required by clinical practice. HT yielded the best coverage and homogeneity for the target structure compared with other techniques. The CI from IMRT was excellent. For photon radiation therapy, the HT plan afforded superior dose sparing for the V , V , V , V , and D of the heart and D of the right ventricle (RV). IMRT displayed the most notable dose reductions in the V , V , V , and V of the heart and D of the right atrium (RA). The VMAT plan was the least effective on the heart and substructures. However, compared with photon radiation therapy, IMPT-1 did not show an advantage for heart protection. Interestingly, IMPT-2 provided significant superiority in cardiac sparing, including maximum dose sparing for the V , V , V , V , V and D of the heart and D of the RA, RV, left atrium (LA) and left ventricle (LV) compared to all other techniques. Considering the complex anatomical relation between target volumes and organs at risk (OARs), IMPT can provide a dose advantage for organs located outside of the target area rather than within or surrounding the area. It is hoped that advances in proton therapy (PT) plan design will lead to further improvements in radiotherapy approaches and provide the best treatment choice for individual patients.