key: cord-0959584-dfm8rv18
authors: Fadavi, Pedram; Nafissi, Nahid; Mahdavi, Seied Rabi; Jafarnejadi, Bahareh; Javadinia, Seyed Alireza
title: Outcome of hypofractionated breast irradiation and intraoperative electron boost in early breast cancer: A randomized non‐inferiority clinical trial
date: 2021-04-01
journal: Cancer Rep (Hoboken)
DOI: 10.1002/cnr2.1376
sha: f83d4692785f017a11f0786fb8df3d3d6e25e436
doc_id: 959584
cord_uid: dfm8rv18

BACKGROUND: Intraoperative electron radiotherapy (IOERT) followed by hypofractionated whole breast irradiation (HWBI) provides the shortest possible time of adjuvant breast irradiation. The efficacy of either method has been described in previous reports; however, to our knowledge, the efficacy of combined therapy has not been reported. AIM: To compare the toxicity and cosmetic outcome of IOERT as a tumor bed boost followed by HWBI with conventional whole breast irradiation (CWBI) followed by external electron tumor bed boost (EETBB) after breast conserving surgery (BCS) in patients with invasive breast cancer. METHODS: In 2019, a prospective noninferiority trial (IRCT20180919041070N2) was started. After BCS, early‐stage breast cancer patients were treated by IOERT (10 Gy) and HWBI (42.56 Gy in 16 fractions) or CWBI (50 Gy in 25 fraction) and EETBB (10 Gy in 5) in a double‐arm design. Acute/late toxicity and cosmetic outcome were evaluated by common toxicity criteria (CTC) after 1‐year follow‐up (FUP) at the level of p < .05. RESULTS: Of 60 eligible patients, 30 were allocated to each group. Regarding acute effects after a median FUP of 12 months, CTC‐score of grade II‐III erythema (p = .001) and desquamation (p = .005) were significantly higher in CWBI+EETBB compared to IOERT+ HWBI. However, there were no significant differences at the end of radiotherapy and after 1 month, 6 months, and 1 year. Cosmetic outcome after radiation was similar in both groups mostly rating as good/excellent after 1‐year FUP. CONCLUSIONS: Boost‐IOERT/HWBI regimen has comparable acute and late treatment toxicity profiles compared to the CWBI.

Adjuvant whole breast irradiation followed by tumor bed boost with a total dose of 60 Gray (Gy) is the current standard of care in breast cancer radiation therapy after breast conserving surgery and is usually done by external beam radiotherapy during 6 weeks. Because of the low α/β ratio of breast cancer cells, 1 hypofractionated radiation therapy regimens utilizing higher dose per fractions up to 2.6-3.2 Gy leading to considerable shorter duration of treatment time is considerably gaining great interest in the recent years. [2] [3] [4] [5] Two common methods that utilize large dose per fraction in breast cancer radiation therapy include hypofractionated whole breast irradiation (HWBI) and intraoperative electron radiotherapy (IOERT).

Both of these methods have been assessed separately in recent studies. 5, 6 However, the role of tumor bed boost in HWBI regimens has not yet been fully addressed but available data support its integration into these regimens in order to decrease the long term in-breast recurrence rates. 5, 7 Nevertheless the role of tumor bed irradiation boost dose on overall survival is unclear. 7 Moreover, the outcome and toxicity profile of IOERT followed by HWBI has not been explicitly addressed, and current data come from phase II and/or single arm clinical trials. 8, 9 The first study by Ivaldi et al showed that IOERT of 12 Gy is feasible and has an acceptable acute and late toxicity. 8 Subsequently, Fastner et al confirmed the safety and tolerability of Boost-IOERT/HWBI regimen in a larger scale with longer follow up period. 9 However, a comparative study assessing the noninferiority of Boost-IOERT/HWBI regimen relative to conventional whole breast irradiation (CWBI) followed by external electron tumor bed boost (EETBB) has not been reported. This study has been conducted to compare the toxicity and cosmetic outcome of IOERT as a tumor bed boost followed by HWBI with conventional whole breast irradiation (CWBI) followed by external electron tumor bed boost (EETBB) after breast conserving surgery (BCS) in patients with invasive breast cancer.

F I G U R E 1 CONSORT subject flow diagram shows the number of subjects screened, enrolled, randomized, and included in the primary analysis 2 | MATERIALS AND METHODS with biopsy-confirmed invasive breast carcinoma, regardless of the molecular subtypes of the tumor, on pathology were eligible to enroll in this study. Inclusion criteria consisted of tumor size ≤5 cm (pT1-2), no regional nodal involvement or involvement of ≤3 nodes (pN0-1), and clear surgical margin in postsurgical pathological examination.

There was no limitation regarding the hormone/systemic therapy.

Patients with a Karnofsky Performance Score of <70%, previous history of chest wall irradiation, multicentric breast cancer, history of connective tissue diseases including lupus and scleroderma, and large breasts based on planning target volume in radiotherapy more than 2500 ml were excluded. Patients who fulfilled these criteria were included in the present study.

The study was designed as a double-armed prospective trial. The primary endpoints were defined as treatment tolerance and cosmetic outcome. NCIC common toxicity criteria (CTC) Version. Twenty and the late effects in normal tissuessubjective, objective, management, and analytic (LENT SOMA) scales were used to assess the acute and late toxicities. [10] [11] [12] The acute reactions were assessed during the radiotherapy, at the end of the radiation therapy, and in week four post HWBI/CWBI-EETBB. For late reactions, the assessments were performed after 6 months and a year after the treatment.

Late reactions were classified into two groups; group one that consisted of grade zero and one, group two that included grade two and three. Grade zero and one were categorized in one class and grade two and three in another one. Cosmesis was evaluated by physicians at year one using a 5-point-Scoring

System which was previously introduced by van Limbergen et al. 13 

In Clinical target volumes were delineated in both groups based on the breast cancer contouring atlas that has been introduced by Radiation Therapy Oncology Group (RTOG). 14 The main dose constrains, which were adopted, were V20 of ipsilateral lung and V25 of heart for left sided breast cancers which were kept below 20 and 10%, respectively. 

Sample size was calculated 30 patients in each group to achieve a power of 90% to detect skin toxicity differences between two groups using n = (Z α/2 + Z β ) 2 × (p 1 (1-p 1 ) + p 2 (1-p 2 ))/(p1-p 2 ) 2 formula consider- 

Out of 356 screened patients with breast cancer, 30 patients were enrolled in each group. Figure 1 shows CONSORT subject flow diagram. In long term follow up, CTC at 6 and 12 months, fibrosis/fat necrosis, and pigmentation were the same in both groups ( Figure 3 ).

Most of cosmetic objective scores were reported as excellent/ good without any significant differences (p = .1). No poor/fair cosmesis outcomes were reported in the present study (Table 2) .

This study aimed to compare the toxicity and cosmetic outcome of two different radiation schedules: IOERT as a tumor bed boost followed by HWBI and CWBI followed by EETBB after BCS of patients with invasive breast cancer. The results revealed that acute skin toxicities during the WBI were significantly higher in the conven- The safety and feasibility of applying intraoperative electron tumor bed boost followed by HWBI were first described by Ivaldi et al. 8 They reported that the skin toxicity might be observed in all patients; however, it was mostly grade 1 that peaked at the end of WBI. In long term follow up, less than 2% patients experienced grade 3 or higher toxicity. 8 In a recent study of 627 patient with early breast cancer, Fastner et al described the safety of applying of IOERT of 11.1 Gy as tumor bed boost followed by HWBI of 40.5 using 2.7 Gy per fraction. 9 They showed that most of the patients experienced grade 0/1 skin toxicities at the end of the WBI and in week 4 after completion of treatment. In long term follow up, late skin toxicity was reported in up to 3.5% of patients and cosmesis was mostly scored as excellent/good. Our study, as the third trial testing IOERT followed by HWBI, provided further reassurance regarding the safety of this procedure and confirmed its cosmetic outcome.

Biologic and in vivo effectiveness of the intraoperative tumor bed radiotherapy using electron or photon and hypofractionated external radiation regimens have been previously proven separately in different scenarios such as partial breast irradiation and/or as a part of adjuvant treatment. [16] [17] [18] [19] [20] However, the role of tumor bed boost, regardless of its method of application (like intraoperative, brachytherapy, and external technique) has not been fully described, 5, 7, 21 for all the cancer patients that attend the radiation therapy facilities. [24] [25] [26] This trial has a number of limitations. One-year follow-up is too short for detecting the in breast recurrence especially in patients with early breast cancer and this could limit drawing inference about clinical efficacy of IOERT from the findings of the present study. However, data derived from previous Phase II/III trials shows low local recurrence rate by using IOERT.

In conclusion, the present study showed that applying high dose boost to the tumor bed using IOERT followed by HWBI regimen has a comparable acute and late treatment toxicity profile in comparison to the conventional whole breast irradiation.

We thank all staffs of IOERT and EBRT treatment teams in the Rasoul 

Authors declare there is no conflict of interest.

The study protocol was approved by the Research Ethics Committee of Medical School of Iran University of Medical Sciences (IR.IUMS.FMD.

REC.1398.319). Also, the study has been registered on Iranian Registry of Clinical Trials (IRCT20180919041070N2). Undersigned informed consent was obtained from all patients prior to the enrollment.

All data generated and analyzed during this study can be accessible through direct communication with corresponding author and agreement of all research team members.

Bahareh Jafarnejadi https://orcid.org/0000-0002-8643-4541

Seyed Alireza Javadinia https://orcid.org/0000-0003-2467-837X

The linear-quadratic formula and progress in fractionated radiotherapy

Randomized trial of breast irradiation schedules after lumpectomy for women with lymph nodenegative breast cancer

Clinical experience using hypofractionated radiation schedules in breast cancer

Accelerated hypofractionated whole breast radiotherapy for early breast cancer; a randomized phase III clinical trial

Long-term results of hypofractionated radiation therapy for breast cancer

Clinical efficacy and side effects of IORT as tumor bed boost during breast-conserving surgery in breast cancer patients following neoadjuvant chemotherapy

The UK standardisation of breast radiotherapy (START) trials of radiotherapy hypofractionation for treatment of early breast cancer: 10-year follow-up results of two randomised controlled trials

Preliminary results of electron intraoperative therapy boost and hypofractionated external beam radiotherapy after breast-conserving surgery in premenopausal women

Toxicity and cosmetic outcome after hypofractionated whole breast irradiation and boost-IOERT in early stage breast cancer (HIOB): first results of a prospective multicenter trial (NCT01343459)

Common toxicity criteria: version 2.0. An improved reference for grading the acute effects of cancer treatment: impact on radiotherapy

Overview of late effects normal tissues (LENT) scoring system

Late effects toxicity scoring: the SOMA scale

Cosmetic evaluation of breast conserving treatment for mammary cancer. 1. Proposal of a quantitative scoring system

Comparison of two radiotherapeutic hypofractionated schedules in the application of tumor bed boost

Intraoperative radiotherapy for breast cancer

Intraoperative radiotherapy for breast cancer

Intraoperative radiation therapy: a critical analysis of the ELIOT and TARGIT trials. Part 2-TARGIT

Intraoperative radiation therapy: a critical analysis of the ELIOT and TARGIT trials. Part 1-ELIOT

OC-0474: Hypofractionated WBI plus IOERT-boost in early stage breast cancer (HIOB): updated results of a prospective trial

The role of boost in hypofractionated irradiation after breast-conserving surgery

Cancer patients in SARS-CoV-2 infection: a nationwide analysis in China

Cancer guidelines during the COVID-19 pandemic

COVID-19: global radiation oncology's targeted response for pandemic preparedness

Practice recommendations for lung cancer radiotherapy during the COVID-19 pandemic: An ESTRO-ASTRO consensus statement

Recommendations for the use of radiation therapy in managing patients with gastrointestinal malignancies in the era of COVID-19