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Adjuvant radiation therapy in metastatic lymph nodes from melanoma

Radiation Oncology volume 6, Article number: 12 (2011) Cite this article

Abstract

Purpose

To analyze the outcome after adjuvant radiation therapy with standard fractionation regimen in metastatic lymph nodes (LN) from cutaneous melanoma.

Patients and methods

86 successive patients (57 men) were treated for locally advanced melanoma in our institution. 60 patients (69%) underwent LN dissection followed by radiation therapy (RT), while 26 patients (31%) had no radiotherapy.

Results

The median number of resected LN was 12 (1 to 36) with 2 metastases (1 to 28). Median survival after the first relapse was 31.8 months. Extracapsular extension was a significant prognostic factor for regional control (p = 0.019). Median total dose was 50 Gy (30 to 70 Gy). A standard fractionation regimen was used (2 Gy/fraction). Median number of fractions was 25 (10 to 44 fractions). Patients were treated with five fractions/week. Patients with extracapsular extension treated with surgery followed by RT (total dose ≥50 Gy) had a better regional control than patients treated by surgery followed by RT with a total dose <50 Gy (80% vs. 35% at 5-year follow-up; p = 0.004).

Conclusion

Adjuvant radiotherapy was able to increase regional control in targeted sub-population (LN with extracapsular extension).

Introduction

The incidence of cutaneous melanoma is increasing in fair-skinned populations. Surgery is the main treatment for melanoma and has a central role in the management of many patients [1]. Despite appropriate excision, locally invasive melanomas bring risks of both local and distant relapses [2]. While distant metastasis is often considered as the main factor for overall survival, regional control is still very important for the quality of life of these patients (figure 1). Systemic therapies for metastatic patients have led to modest improvements in locoregional control or overall survival [3]. Other ways to improve patients' survival have been explored in vain. The use of sentinel lymph node (SL) is gaining popularity in staging and treatment of patients with melanoma [4]. However, even with this approach, no survival benefit from SL with subsequent radical regional lymphadenectomy in malignant melanoma patients with lymph node (LN) metastases was found [5]. Additional treatments are therefore needed to improve the patient's outcome for melanomas with a high risk of locoregional or distant recurrence.

Figure 1
figure 1

Inflammatory axillary nodal recurrence from cutaneous melanoma.

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Radiation therapy forms the third cornerstone of cancer management, together with surgery and systemic treatments. Although the role of radiotherapy in achieving locoregional control and palliation is recognised, it is not often used for the management of melanoma. Use of radiation therapy for these patients has been hindered by the belief that melanoma is resistant to radiation [6]. This point of view is not shared by everyone [7].

Several retrospective studies on radiation therapy for the management of metastatic lymph nodes from cutaneous melanoma have been published [812]. They showed the benefit of radiation therapy in preventing local recurrence in metastatic lymph nodes from cutaneous melanoma after lymphadenectomy. This treatment had no impact on disease-free survival or overall survival. Most of these retrospective studies used a hypofractionated radiation regimen (30 Gy in 5 fractions).

In our centre, we chose to use a standard fractionation regimen for the management of these patients. In this study, we reviewed our experience in the treatment of locally advanced melanoma in order to identify prognostic factors. We tried to assess whether adjuvant radiation therapy was advantageous in locally advanced melanoma, which minimal dose and radiation regimen should be used, and for which patients it should be used.

Material and methods

Patients

Between 2000 and 2009, 86 successive patients were diagnosed with lymph node metastases from melanoma and treated with lymphadenectomy, followed by or without radiation therapy, and without systemic therapy.

Having four or more involved lymph nodes, extracapsular extension and node size greater than 3 centimetres were our main indications for radiation therapy in this study. Patients with visceral metastases at the time of RT were excluded from the analysis.

Technical features of radiation therapy

Three-dimensional conformal radiation therapy was used. Areas treated included the axillary, cervical and groin lymph node areas. Organs at risk were contoured according to locations: for the axillary area: lung, heart, head of homolateral humerus; for cervical lymph nodes: parotid, larynx, thyroid; for groin lymph nodes: homolateral femoral head, rectum, bladder. Radiation was delivered by X-rays.

Follow-up

Tumour relapse was established on the base of any clinical or radiological evidence of relapse. Any dermal, subcutaneous, soft tissue or lymph node relapse within or around the dissected and irradiated nodal basin was considered to be a local recurrence. The toxicity was analyzed using the grading scale introduced by Ballo et al in 2006 [9]. The classification consisted in grade 1 toxicity for an asymptomatic finding noted at the time of the follow-up physical examination; grade 2 for a symptomatic finding requiring any form of medical therapy (e.g., compressive sleeve for lymphedema, physical therapy for neuropathy, or long-term use of pain medication); and grade 3 for toxicity requiring surgical intervention. The follow-up period and survival were calculated from the date of surgery to November 2009.

Statistical method

The distribution of categorical variables was tested using a Fisher exact test and chi-square test for trends. The primary endpoint was regional control, which was defined as complete and permanent eradication of tumour in treated area.. The secondary endpoint was overall survival. We carried out 3 successive analyses: (i) an identification of prognostic factors on the whole cohort (ii) a crude survival analysis according to the treatment performed (iii) a stratified survival analysis according to prognostic factor(s) identified.

Univariate analysis of the patients' survival was carried out using the Kaplan-Meier method with 95% confidence intervals (CI) and a log-rank comparison to evaluate the difference between the survival curves. Univariate analysis was performed according to Cox's proportional hazard. All statistical tests were two-sided, and a p value of <0.05 was considered statistically significant. The statistical package SPSS 13.0 (SPSS Inc., Chicago, IL, USA) was used to perform the analysis.

Results

Patient characteristics

Eighty-six patients were treated for metastatic lymph nodes from melanoma between August 1996 and November 2009. Fifty-seven were men. The median age at which the melanoma was diagnosed was 51 years (18 to 87 years). The median Breslow index was 2.5 mm (0.15 to 33 mm). The Clark level was known in 66 patients and was: level I in 1 patient, level II in 1 patient, level III in 16 patients, level IV in 44 patients and level V in 4 patients. Ulceration of the primary tumour was found in 12 patients. Initial treatment was not known for 2 patients. Seventy-nine patients had a complete resection of the initial melanoma (92%). Three patients had lymphadenectomy (3.4%) only, and 4 patients had concomitant resection of melanoma and lymphadenectomy (4.6%).

The clinical and pathologic characteristics are presented in Table 1. Median time lapse between initial diagnosis and lymph node metastases was 11 months (0 to 165 months). Median age when lymph node metastases were diagnosed was 52 years old (19 to 87 years old). The sites of the metastatic lymph nodes were: 20 cervical (23.3%), 26 axillary (30.2%) and 40 inguinal (46.5%). Twenty-six patients (30%) had no radiation therapy (group 1). Sixty patients (70%) underwent lymphadenectomy followed by conformal radiation therapy: 30 patients were treated with a total dose <50 Gy (group 2) and 30 patients with a total dose >50 Gy (group 3).

Table 1 Patients, tumors and lymph nodes characteristic according to treatments (surgery alone vs surgery followed by radiation therapy).
Full size table

No systemic therapy was used for these patients until progression.

The median number of resected lymph nodes was 12 (1 to 36). The median number of positive lymph nodes was 2 (1 to 28). Forty-two patients presented at least one extracapsular extension (50.6%). The median total dose was 50 Gy (30 to 70 Gy). For a majority of treatments (37 patients; 63.8%) a standard fractionation regimen was used. The median dose/fraction was 2 Gy (1.8 to 3 Gy). The median number of fractions was 25 (10 to 44 fractions). Patients were treated with five fractions/week.

The median biological equivalent dose (BED with α/β = 2 Gy) was 50 Gy (18 to 71 Gy).

Median follow-up was 73 months (2 to 158 months). 18 patients were lost to follow-up.

Overall survival

Survival analysis was performed from the admitted date of lymph node recurrence. 43 patients (47.8%) died from an evolution of melanoma. Median survival after lymph node recurrence was 31.8 months ([CI] 23.3 to 40.3 months).

Regional control

16 patients (22.5%) presented a recurrence within the treated area.

Prognostic factors

Regional control

Age (p = 0.2), sex (p = 0.64), initial site (p = 0.32), Breslow index (p = 0.88), Clark index (p = 0.7), number of resected lymph nodes (p = 0.2), number of metastatic lymph nodes (p = 0.88), and size of metastatic lymph node greater than 3 cm (p = 0.64) were not significantly associated with worse regional control. Extracapsular extension was significantly associated with worse regional control (p = 0.019).

Overall survival

The following putative predictive factors were considered for the analysis: sex (p = 0.059), age (p = 0.3), time between initial cutaneous melanoma diagnosis and relapse (0.49), initial site (0.12), relapse site (0.25), Breslow index (0.7), Clark index (p = 0.1) and metastatic lymph node size greater than 3 cm (p = 0.2). Extracapsular extension was significantly associated with a worse survival (p = 0.03; figure 2).

Figure 2
figure 2

Extracapsular extension was significantly associated with a worse overall survival (p = 0.03).

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Outcome of patients with and without radiotherapy

Radiation therapy did not improve regional control (p = 0.17) or overall survival (p = 0.18). Patients treated with a total dose >50 Gy (group 3) had better regional control (p = 0.004; figure 3) and overall survival (p = 0.005; figure 4) than patients treated by surgery alone (group 1).

Figure 3
figure 3

Radiation therapy with a total dose of more than 50 Gy was associated with better regional control (p = 0.004).

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Figure 4
figure 4

A total dose of more than 50 Gy was associated with better overall survival (p = 0.005) for patients treated with surgery followed by radiation therapy.

Full size image

Regional control rates for each tumour location were (radiation therapy >50 Gy vs. without radiation therapy): 90% vs. 70% for axillary LN metastasis, 80% vs. 72% for inguinal LN metastasis and 85% vs. 50% for cervical LN metastasis.

No statistical difference was found for regional control between the three LN metastasis locations (p = 0.4).

Impact of radiotherapy after stratification according to the identified prognostic factor

An analysis stratified on extracapsular extension showed that patients with extracapsular extension treated with surgery followed by radiation therapy with a total dose ≥50 Gy (group 3) experienced a better regional control than those treated by surgery followed by adjuvant radiotherapy with a total dose <50 Gy (group 2): 80% vs. 35% at 5-year follow-up (p = 0.03; figure 5). This difference was not found for patients without extracapsular extension (p = 0.8).

Figure 5
figure 5

Radiation therapy with a dose greater than 50 Gy was associated with better regional control (p = 0.03) for patients with extracapsular extension.

Full size image

Toxicity

Grade 1 toxicity was found in 5 patients (5.5%). Grade 2 toxicity was found in 21 patients (23.3%): 6 patients (27.3%) treated with only surgery and 15 patients (22%) treated with surgery followed by radiation therapy. There was no grade 3 toxicity. Two patients (8.3%) treated for cervical LN metastasis, 4 patients (19%) treated for axillary LN metastasis and 15 patients (39.5%) for inguinal LN metastasis had grade 2 toxicity. Toxicity rates were 9% grade 1 and 9% grade 2 for cervical, 20% grade 2 for axillary and 45% for inguinal nodal regions.

There was a statistical increase in toxicity for patients treated for groin metastases (p = 0.01) compared to other treated areas, whichever treatment was performed (surgery alone or surgery followed by radiation therapy). No statistical correlation between radiation therapy and higher toxicity was found for cervical and inguinal regions (p > 0.05). There were more grade 2 toxicities for the axillary region when radiation therapy was used (p = 0.047). Dose >50 Gy was also not associated with higher toxicity (p = 0.36).

Discussion

Our analysis aimed to identify the patient subgroups that could benefit from adjuvant radiation therapy. Extracapsular extension was the only significant prognostic factor for regional control and overall survival. Patients with this anatomopathologic feature were those who benefited the most from adjuvant radiation therapy. Our results are consistent with previous publications [13, 14].

Cervical nodal regions

In our study, regional control rate was 85% for cervical nodal metastasis for patients treated with surgery followed by radiotherapy. Recurrence rates for metastatic melanoma in cervical lymph nodes range from 30 to 50% after neck dissection alone [1518]. Postoperative radiotherapy leads to regional control rates of about 90% for high-risk cervical metastases [1921]. However, treatment-related morbidity is an issue with adjuvant RT. Toxicity was still very low for our patients: 9% grade 1 and 9% grade 2 toxicities. Ballo et al reported that 10% of patients had complications that required medical intervention at 5 years (ipsilateral hearing loss, hypothyroidism, wound breakdown and bone exposure) [10].

Axillary nodal regions

Regional control rate in our study was 90% for patients treated with surgery and radiation therapy for axillary nodal regions. Axillary lymph node recurrence rates range from 23 to 50% [22, 23]. Toxicity in our study was higher than that found for cervical nodal regions (20% grade 2 toxicity). Beadle et al reported treatment-related complications in 32% of patients treated with the hypofractionated regimen (30 Gy in five fractions, twice-weekly) after 5 years [11]. Lymphoedema occurred in 42 of 200 patients and was the most common complication. A study published by Starritt et al on lymphoedema occurrence in 107 patients treated with axillary dissection alone or axillary dissection plus postoperative radiation therapy [24] reported that lymphoedema occurred in 10% of patients who received dissection alone and in 53% treated with radiotherapy (p < 0.005). The hypofractionated regimen used in this study might explain this high rate.

Inguinal nodal regions

The regional control rate for our patients treated with surgery and radiotherapy was 80%. However, the grade 2 toxicity rate was (45%). It is therefore important to select patients with high-risk anatomopathological features such as: extracapsular extension, 2 or more involved lymph nodes, or large nodal disease. Inguinal lymph node recurrence rates range from 19 to 40% of patients treated with dissection [17, 25]. Ballo et al (8) reported a 3-year regional control of 74% in patients treated for high-risk inguinal nodal metastases with 30 Gy at 6 Gy per fraction. Complications are more common than in other tumour locations: 25 to 45% of patients were reported to develop lymphoedema [1, 15, 2629]. Obesity (BMI >25 kg/m2) entailed higher rates of treatment-related complications (55%).

Radiobiology of melanoma

Melanomas in vitro seem less radiosensitive than other tumour cell lines, but actually have a wide range of sensitivities [3032]. Overgaard analyzed the radiation response of a clinical series of more than 600 metastatic melanoma lesions, mainly skin metastases [33]. One of the conclusions was that the response rate was dependent on the size of the fraction, with complete response rates of 57% when fractions of more than 4 Gy were used. This has led many to advocate a hypofractionated radiation therapy regimen. However, RTOG 83-05, the only study designed to assess whether a high dose per fraction irradiation was preferable in melanoma treatment, showed no difference in regional control between conventional and hypofractionated schedules [34]. A more recent study published in 2009 by Strojan et al[12] opted for more conventionally fractionated radiotherapy schedules (2-2.5 Gy/fractions).

Our study would also lead us to believe that a more conventionally fractionated schedule could be used (1.8 to 2.5 Gy) with a higher total dose (>50 Gy) in order to minimize toxicities. However, its unicentric, retrospective design and the limited number of patients included limits the interpretation of our results (our low toxicity rates might be underevaluated), even if our groups of patients were well balanced.

Overall, we would recommend using adjuvant radiation therapy for patients with lymph node metastases from cutaneous melanoma, especially if they present one or more LN with extracapsular extension. Total dose should be strictly greater than 50 Gy for this kind of treatment, with a standard fractionation regimen (ex: 2 Gy/fraction, 5 fractions a week) in order to maximize the efficacy and to minimize the toxicity. An even better approach would be to use the biological equivalent dose (BED), which should be greater than 50 Gy.

Conclusion

Melanoma is often considered to be a radioresistant tumour. Our data, in accordance with previously reported series, show that adjuvant radiation therapy provides good regional control. However, since toxicity is not negligible, especially for axillary and inguinal lymph nodes, this treatment should be considered only for patients with poor anatomopathological features. The first factor that should be taken into account is extracapsular extension.

Conflict of interest notification

The authors declare that they have no competing interests.

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Authors and Affiliations

  1. Academic Radiotherapy Departement, CLCC Oscar Lambret Comprehensive Cancer Center, Lille-Nord de France University, LILLE, France

    Jean-Emmanuel Bibault, Sylvain Dewas, Xavier Mirabel & Eric Lartigau

  2. Department of Dermatology, CHRU Lille, University Lille II, LILLE, France

    Laurent Mortier

  3. General Oncology Department, CLCC Oscar Lambret, University Lille II, LILLE, France

    Nicolas Penel & Luc Vanseymortier

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Authors' contributions

JEB and XM conceived the study. JEB collected data and drafted the manuscript. SD, XM, LM, NP, LV and EL participated in coordination and helped to draft the manuscript. SD performed the statistical analyses. EL provided mentorship and edited the manuscript. All authors have read and approved the final manuscript.

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Bibault, JE., Dewas, S., Mirabel, X. et al. Adjuvant radiation therapy in metastatic lymph nodes from melanoma. Radiat Oncol 6, 12 (2011). https://doi.org/10.1186/1748-717X-6-12

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Radiation Oncology

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