So far, a few studies have demonstrated the results of mtRT in adult cancer patients [
22‐
24]. However, to our knowledge, this is the first study to present the outcome and toxicity rates of tomotherapy in pediatric patients with a focus on mtRT of sarcomas. Fogliata et al. have already compared different radiation techniques for selected pediatric patients and stated helical tomotherapy to be a satisfactory treatment method for pediatric patients with large complex-shaped tumors near organs at risk [
25]. In this study, we analyzed 38 patients diagnosed with histologically different types of sarcomas. At the time of RT, most patients had stage III or IV disease (
n = 30 [79%]), which is generally associated with poor outcome [
26‐
28]. Hence, risking a highly toxic multimodal treatment with RT in a semi-curative intent was the only chance of cure in most cases. In our patient cohort, 20 patients received mtRT and 18 patients single-target RT. Since various entities located in different areas of the body were included in this study, it is unfeasible to compare the general OS and PFS of this study with the survival data of other studies. However, the 5‑year survival rate of patients with stage IV disease receiving mtRT was 37.1% ± 13.2% and had to be emphasized. More precisely, this study shows an excellent 5‑year survival rate of 55.6% ± 18.7% for patients with primary disease multifocal Ewing sarcoma receiving mtRT, especially when compared to the 3‑year OS of only 34% ± 4% for multifocal Ewing sarcoma demonstrated by Ladenstein et al. and the 3‑year OS of 40% shown by Pape et al. [
27,
29]. Further, Hamilton et al. analyzed the outcome of pediatric Ewing sarcomas and stated a 5-year OS of 27% for patients with metastatic disease and 85% for localized disease, where again our abovementioned outcome for multifocal Ewing sarcoma has to be highlighted [
30]. Regarding localized disease, patients receiving single-target RT had a noteworthy 5‑year OS rate of 75 ± 10.8% and mostly included Ewing sarcoma (
n = 9) and nonrhabdomyosarcoma soft tissue sarcoma (
n = 6). The outcome is moreover acceptable, since Spunt et al. and Williams et al. published a 5-year OS of 50–90% depending on the risk profile for localized nonrhabdomyosarcoma soft tissue sarcomas [
2,
31]. However, due to small numbers of patients and the included different entities as well as primary and recurrent diseases, a comparison to survival rates of other studies might not be conclusive. Despite this, the mean OS of 3 patients with a relapsed disease of Ewing sarcoma of 59.3 months (95 CI 0–121.9 months) after single-target RT seems noticeably auspicious considering the poor 5‑year OS of <15% shown by Bacci et al. and Leavey at al.[
32,
33]. Patients with metastatic rhabdomyosarcoma had a 5-year OS of 20% ± 17.9% that is comparatively similar in context to Rudzinski et al., who indicated an approximate OS of 20–40%, and Breneman et al., who mentioned a 3-year OS of 39% (95% CI 30–48%) [
34,
35]. Besides, a good outcome and little toxicity of IMRT in comparison to other RT techniques were demonstrated by Qui et al. in pediatric nasopharyngeal carcinoma [
36]. Therefore, it would be interesting to compare outcomes in pediatric patients with a focus on mtRT using tomotherapy to other radiation techniques in further studies. Due to improving outcomes in pediatric cancer patients, reduction of side effects is more and more important. Especially the risk of second malignancies is a major concern in the treatment of childhood cancers. Particularly in the field of radiation oncology, proton beam therapy offers another approach in the local treatment of pediatric cancers by irradiating sensitive tumor sites very precisely with only a low dose to surrounding healthy tissue and nearby organs at risk [
37,
38]. Due to the excellent dose distribution in proton beam therapy, studies show promising results with low toxicity rates, but also indicate the need for further studies on the long-term toxicity of proton therapy in pediatric patients [
39,
40]. Besides, proton therapy seems to mitigate the risk of developing second cancers as long-term toxicity after radiation compared to photon therapy [
41]. In this study, however, the incidence of severe toxicity caused by tomotherapy was noticeably low, with no significant difference between both groups (single-target RT and mtRT). During RT, 13 patients (65%) with mtRT and 6 patients (33%) with single-target RT had grade 3 toxicity. However, especially non-hematological grade 4 toxicities occurred rarely (
n = 2 [5%]) during RT. Such low rates of non-hematological grade 4 toxicity are even more surprising considering the poor prognosis of most patients with a need for aggressive RT (median dose 54 Gy) and concomitant chemotherapy (76%). Furthermore, the latter was the only significant factor associated with severe leucopenia during RT in patients receiving single-target RT. When comparing both subgroups concerning hematological toxicity, the percentage of patients receiving mtRT (
n = 18 [90%]) was higher than that of patients with single-target RT (
n = 12 [67%]). Lee et al. also mentioned high rates of severe leucopenia for patients undergoing mtRT [
23]. In patients with mtRT, the duration of RT in minutes was significantly related to the KPS of the patient, due to the size of target lesions and, therefore, the severity of disease. After RT only a few patients presented acute severe toxicity. Grade 3 toxicity occurred in five cases acutely after mtRT and in four individual cases after single-target RT. Only 1 patient who had a multifocal unclassified soft tissue sarcoma suffered from several non-hematological grade 4 toxicities (gastritis, pericarditis, and pericardial effusion) acutely after mtRT. Patients with single-target RT had no acute non-hematological grade 4 toxicity. The same applies to severe toxicity as a late effect, with 1 patient suffering from severe grade 3 dyspnea after receiving mtRT for a multifocal and pulmonary spread Ewing sarcoma. Another patient had a grade 3 pericardial effusion as a late effect after mtRT for an alveolar rhabdomyosarcoma in the posterior mediastinum. Patients with single-target RT did not show any severe toxicity as a late effect.
We acknowledge that the limited patient number in our study leads to insufficient statistical power. Hence, further studies on long-term toxicities and outcomes of pediatric patients after tomotherapy and especially mtRT are needed in the future. In particular, concerning the risk of second malignancies after tomotherapy, a longer follow-up period is necessary for a relevant conclusion. It would also be helpful to analyze toxicities regarding different tumor sites as well as tumor entities, making a higher number of patients necessary.
In conclusion, our results show acceptable levels of acute and late toxicities considering the highly advanced diseases and multimodal treatment. Hence, tomotherapy is a suitable treatment method, especially for young patients with tumors of complex-shaped anatomy or multiple targets. Further analysis of long-term toxicity rates showed that side effects caused by RT are rare, despite the relatively short follow-up period. In particular, children with multifocal tumor stages treated with mtRT had no long-term side effects compared to patients receiving RT of just one tumor site. Furthermore, patients treated with mtRT showed a 5-year survival rate of 37.1 ± 13.2% and a median OS of 36.1 months (95% CI 0.0–74.6 months). Thus, mtRT is a promising approach and an innovative treatment method for pediatric sarcomas.