- Open Access
Hypofractionated irradiation of infra-supraclavicular lymph nodes after axillary dissection in patients with breast cancer post-conservative surgery: impact on late toxicity
© Guenzi et al. 2015
Received: 17 March 2015
Accepted: 7 August 2015
Published: 20 August 2015
The aim of the present work was to analyse the impact of mild hypofractionated radiotherapy (RT) of infra-supraclavicular lymph nodes after axillary dissection on late toxicity.
From 2007 to 2012, 100 females affected by breast cancer (pT1- T4, pN1-3, pMx) were treated with conservative surgery, Axillary Node Dissection (AND) and loco-regional radiotherapy (whole breast plus infra-supraclavicular fossa). Axillary lymph nodes metastases were confirmed in all women. The median age at diagnosis was 60 years (range 34–83). Tumors were classified according to molecular characteristics: luminal-A 59 pts (59 %), luminal-B 24 pts (24 %), basal-like 10 pts (10 %), Her-2 like 7 pts (7 %). 82 pts (82 %) received hormonal therapy, 9 pts (9 %) neo-adjuvant chemotherapy, 81pts (81 %) adjuvant chemotherapy. All patients received a mild hypofractionated RT: 46 Gy in 20 fractions 4 times a week to whole breast and infra-supraclavicular fossa plus an additional weekly dose of 1,2 Gy to the lumpectomy area. The disease control and treatment related toxicity were analysed in follow-up visits. The extent of lymphedema was analysed by experts in Oncological Rehabilitation.
Within a median follow-up of 50 months (range 19–82), 6 (6 %) pts died, 1 pt (1 %) had local progression disease, 2 pts (2 %) developed distant metastasis and 1 subject (1 %) presented both. In all patients the acute toxicity was mainly represented by erythema and patchy moist desquamation. At the end of radiotherapy 27 pts (27 %) presented lymphedema, but only 10 cases (10 %) seemed to be correlated to radiotherapy. None of the patients showed a severe damage to the brachial plexus, and the described cases of paresthesias could not definitely be attributed to RT. We did not observe symptomatic pneumonitis.
Irradiation of infra-supraclavicular nodes with a mild hypofractionated schedule can be a safe and effective treatment without evidence of a significant increase of lymphedema appearance radiotherapy related.
In high-risk node-positive women with breast cancer, national and international guidelines (AIRO/NCCN/DEGRO) recommended to extend radiotherapy to lymph nodal area (apex axilla - III level and/or supraclavicular regions) after axillary dissection to improve loco-regional control and survival, especially in the presence of additional clinical and biological risk factors [1–4]. The standard given dose post conservative surgery remains 50 Gy in 25 fractions over 5 weeks and it is recommended a boost to the tumor bed to further improve the local control . Several randomized trials proved that in selected low-risk patients, shorter treatment regimens (3 to 4 weeks) with a hypofractionated schedule may be safe and effective with comparable medical outcome and cosmesis [6, 7]. A task force group endorsed by the American Society for Radiation Oncology (ASTRO) asserted that data are now sufficient to support the use of hypofractionated whole breast irradiation (HF-WBI) for selected patients with early-stage breast cancer  and recently the same association has recommended the administration of such therapeutic schedule . Published data supportive of hypo-fractionated schedules are limited to breast irradiation and only few clinical trials are available on regional lymph node irradiation with short schemes . The hypo-fractionated loco-regional radiotherapy scheme used in our Institute is not particularly compressed in time but provides a smaller number of fractions (20 versus 25), during which the boost to the tumor bed is simultaneously administered once-a-week, reducing the patient accesses . This is a retrospective study about one hundred consecutive patients treated with mild hypofractionated locoregional radiotherapy. The aim of the present work was to analyse the impact on late toxicity of this hypofractionated scheme in order to assess safety and efficacy in infrasupraclavicular area.
Pathological tumor stage
Pathological nodal stage
Molecular characteristics of patients
BED comparison between standard and explored RT schedule 
BED tumor control α/β 4
BED acute effects α/β 10
BED fibrosis α/β 1.7
BED vascular damage α/β 2.5
W.B. = whole breast
B.S. = tumor bed side
60 Gy/30 F/6 W
(50 Gy + 10 Gy seq.boost)
52 Gy/20/F/5 W (46 Gy + 6 Gy cc.boost)
UK START TRIAL A
41.6 Gy/13 F/5 W
UK START TRIAL A
39 Gy/13 F/5 W
Regional Nodal Contours: anatomical boundaries 
bounded by the deep surface of the sternocleidomastoid and the deep cervical fascia
Lat: the anterior and medial borders of the anterior scalene muscle.
the posterior border was defined by the subclavian artery
lateral edge of the trachea excluding the thyroid gland and thyroid cartilage superiorly
Med: medially to the carotid artery and internal jugular vein
the deep surface of the pectoralis major muscle
the most superior aspect of the pectoralis minor muscle
level of the insertion of the clavicle into the manubrium
lateral edge of the clavicle
medial border of the pectoralis minor muscle
Constraints for organs at risk in adjuvant radiotherapy of early breast cancer
Organ at risk
Normofractionation 2 Gy per fraction\5fr\week
Hypofractionated schedule 2,3 Gy per fraction\4 fr\week
V20Gy = 0 %
V19Gy = 0 %
V20Gy = 10 % V40Gy =5 %
V19Gy = 0 %
V20Gy = 25 % (exclusive periclavicular LN)
V19Gy = 25 % (exclusive periclavicular LN)
V20Gy = 35 % (inclusive periclavicular LN)
V19Gy = 35 % (inclusive periclavicular LN)
Max 45 Gy
Max 42 Gy
Within a median follow-up of 50 months (range 19–82), 6 patients (6 %) died, one patient (1 %) had local progression disease, 2 patients (2 %) developed distant metastasis and 1 (1 %) subject presented both. In all patients the acute toxicity, according to the RTOG/EORTC classification , was mainly represented by erythema and patchy moist desquamation. In 27 patients (27 %) a lymphedema was recorded during the visit at the Department of Oncological Rehabilitation of our institute: 15 cases (15 %) as a likely consequence of chemotherapy and surgery because they appeared before radiotherapy. In only three cases, a preexisting lymphedema was worsened by radiotherapy. In 12 patients (12 %) it appeared after the end of radiotherapy: in 2 patients as a result of disease progression to the lymph nodes, in the remaining 10 patients appears to be related to radiotherapy. The time of onset of lymphedema in the latter 10 cases was very variable (from 1 to 48 months from the end of radiotherapy). The cases of radio induced lymphedema were classified as follows: 4 mild, 2 moderate and 4 severe. These patients were treated with manual lymph drainage and compression therapy. Post-RT, three patients showed paresthesias of upper limbs, two bilaterally, already present before starting radiation treatment, the last one ipsilateral, which resolved spontaneously in few months. All patients received chemotherapy regimens containing taxanes, of which paresthesias are one of the side effects. Treatment was generally well tolerated: a limited number of severe lymphedema (4 %), none of the patients showed a severe damage to the brachial plexus, the described cases of paresthesias could not definitely be attributed to RT and we did not observed symptomatic pneumonitis.
The aim of the present work is to investigate the outcomes of a mild HF-WBI for the treatment of breast cancer when delivered to women who need irradiation to the infra-supraclavicular lymph nodal region. Our results seem to suggest that this hypofractionated schedule to the breast and the regional nodes is as effective as a standard RT regimen in the absence a significant increase of side effects. This evidence is of note since many concerns emerge when an altered fractionated regimen is proposed for the irradiation of locoregional node areas. As reported in the literature, the irradiation of the lymph node area may increase the risk of side effects such as radiation pneumonitis, lymphedema and brachial plexopathy. Since acute and late side effects are correlated to the volume of irradiated parenchyma, regional nodal radiotherapy can increase the pneumonitis rates (1.3 % vs 0.2 %) . In order to reduce the risk of radio-induced pneumonitis, internationally approved protocols should be strictly applied . Lymphedema may represent a standard complication after any axillary surgery. Its incidence can be difficult to define, as no standardized definition of lymphedema exists. The onset of lymphedema is related different causes including the extension of axillary dissection (5–15 % after dissection, 1–3 % after sentinel node biopsy), obesity, the association with chemotherapy and RT delivery [19–23]. Shah et al., provides the incidence of lymphedema according to the extent of RT after dissection, reporting a rate from 2–35 % after breast irradiation and an increased incidence to 9–65 % in the case of loco-regional irradiation . The different findings of lymphedema may be related not only to individual clinical situations and radiation techniques applied (extension of treatment volumes, type of planning, others) but also to the different methods of evaluation and classification used. Inter-limb circumferential discrepancy has been the most widely used outcome measure. Moreover, brachial plexopathy is a major concern with loco-regional RT: the induced damage may be related to dose per fraction, total dose, and volume irradiated. Using standard fractionation schedule (50Gy/25fr) the rates of brachial plexopathy are less than 5 % . In recent years several schemes of hypofractionated WBI were developed and tested in randomized trials. The results with long-term follow-up demonstrated that the adoption of a shorter schedule may be safe and effective with comparable medical outcome and cosmesis to the standard irradiation: no statically significant differences both in local control and aesthetic result emerged in women who received the standard or the hypofractionated breast radiation [6, 7].
However, few data are still available as regards the late effects of hypofractionated radiotherapy when extended to the regional lymph nodes. A recent update of START A and START B evaluated the loco-regional RT in a limited group of patients and neither the 5 week nor the 3 week treatment developed significantly worse normal tissue impacts: the assessments of arm and shoulder effects showed no evidence of a detrimental effect for the hypofractionated schedules . In 2011 Yarnolds et al. already showed no radio-induced brachial plexus toxicity after hypofractionated irradiation of the axilla and/or supraclavicular fossa. Those Authors stated that the START B regimen (40 Gy in 15 fractions/3 weeks) is equivalent to 47 Gy in 2.0-Gy fractions if the α/β value for brachial plexus is 2.0 Gy or to 49 Gy in 2.0-Gy fractions, if α/β = 1.0 Gy . Haffty and Buchholz commented on the absence of side effects in the small group of patients (116pts of 2215, 7 %) enrolled in the START B trial and receiving regional hypofractionated RT: they confirmed that these results are consistent with modelling of normal tissue effects, which predicts that 40 Gy in 15 fractions should be as safe as the standard scheme for all normal tissues . The results of several randomized studies demonstrated the feasibility and effectiveness of the hypofractionated WBI. Although limited, other data collected during hypofractionated regional nodes irradiation did not reveal increased toxicity as compared to standard fractionation RNI . Badiyan N. et al. reviewed prospective and randomized data to analyse the efficacy and toxicity of hypofractionated radiation schedules in breast cancer with RNI to the axilla and supraclavicular regions. They noted that RNI with standard fractionation is associated with increased toxicity compared to WBI alone but current data do not support an increased rate of toxicity with hypofractionated RNI compared with standard fractionation RNI . The outcomes of our investigation seem to confirm what emerges from the literature: patients treated with hypofractionated RT (46Gy in 20 fractions with 4 times a week) to the whole breast and infra-supraclavicular fossa (plus once weekly concomitant boost dose of 1,2 Gy to the lumpectomy area) did not show a higher rate of side effects, in 10 patients the lymphedema was radio induced, which only 4 severe. We observed no symptomatic pneumonitis, no radiation-related damage to the brachial plexus and only 11 % of lymphedema. The favorable results obtained with this fractionation can be the basis for investigating new radiation schemes with a smaller number of fractions administered in reduced times.
Mild hypofractionated WBI delivered in 20 fractions represents a safe and effective treatment for the infrasupraclavicular node areas. ASTRO board reported that shorter treatment schedules can significantly benefit patients in terms of convenience, acceptance of therapy, and cost. They suggest to do not initiate whole-breast radiation therapy as a part of breast conservation therapy in women age ≥50 with early-stage invasive breast cancer without considering shorter treatment schedule . The limited experience available on hypofractionated scheme extended to lymph nodes do not seem to show an increased toxicity. In our department the adoption of this mild hypofractionated loco-regional radiation schedule in the context of a policy of gradual reduction of the numbers of the fractions has shown to be safe when delivered on locoregional nodal areas. This preliminary evidence should be further investigated and confirmed by large-scale prospective studies.
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