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Contemporary Oncology/Współczesna Onkologia
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vol. 18
 
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Original paper

Preliminary results of proton radiotherapy for choroidal melanoma – the Kraków experience

Beata Sas-Korczyńska
,
Anna Markiewicz
,
Bożena Romanowska-Dixon
,
Elżbieta Pluta

Contemp Oncol (Pozn) 2014; 18 (5): 359–366
Online publish date: 2014/06/26
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- Preliminary results.pdf  [0.31 MB]
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Introduction

Ocular melanoma is a rare malignant neoplasm with the incidence rate estimated at 6–8 cases per one million [1, 2]. This translates into 3.7% of all cases of melanoma and makes it the second most frequent location for this neoplasm (after skin melanomas [1, 3]). On the other hand, choroidal melanoma is one of the most common primary intraocular malignant tumours affecting the eyeball and in most cases (82.5%) develops in the uvea.
The following are predisposing factors for choroidal melanoma: congenital ocular or oculodermal melanocytosis (nevus of Ota) and uveal nevus [4]. Furthermore, more than half of all patients have somatic mutations of the following genes: GNAQ, PTEN, GNA11 [5–10]. This carcinoma is most commonly diagnosed in persons aged 50–80 with fair skin colour, light eye colour and with reduced tolerance to sunlight.
Symptoms of choroidal melanoma depend on the location and dimensions of the tumour. They include the following: various visual disturbances (impaired vision with varying degrees of severity up to visual loss in the affected eye), photopsia, irritation and pain. It is important to note that 30% of tumours are asymptomatic and are only detected by accident during eye examinations [11, 12].
The basic treatment methods applied to patients with ocular choroidal melanoma are surgery and radiotherapy. The choice of treatment for patients with ocular choroidal melanoma depends on the location and size of the tumour, its local advancement, the effectiveness of a given method and its impact on maintaining the patient’s visual function.
Possible surgical treatment includes procedures aimed at preserving the eyeball (endoresection or exoresection of the tumour) as well as more extensive operations such as enucleation of the eyeball [3].
Radiotherapy treatment is aimed at preserving the eyeball. It can take the form of either brachytherapy or teletherapy.
In the case of brachytherapy applicators are used (in the form of plaques) with a radioactive isotope (iodine-125, ruthenium-106, palladium-103) [13, 14]. This method has been practised since the 1930s and its 5-year survival rate of around 80% is comparable with the results observed for enucleation [15, 16]. Thanks to these factors and the possibility of preserving the eyeball, brachytherapy has become the standard procedure for patients with choroidal melanoma. However, the method has certain limitations due to post-radiation reaction and the risk of complications occurring in the healthy tissue surrounding tumours. This is the case with tumours located in the region of the macula and the optic disc, those that infiltrate the sclera and which are large in size.
The second radiotherapy method for treating patients with choroidal melanoma is teleradiotherapy, which makes use of stereotactic techniques (e.g. a gamma knife) together with intensity-modulated radiation therapy (IMRT) or a proton beam [3, 17, 18].
Local treatment makes it possible to preserve the eyeball and its functioning. However, it does have some effect on the survival rate [19, 20]. A particular role is played here by proton radiotherapy, which has been used to treat choroidal melanoma since the 1970s as an alternative procedure to enucleation (in the case of large tumours) or brachytherapy (in the case of tumours located close to the macula or the optic disc) [19, 21–24].
According to data from the PTCOG (Particle Therapy Co-Operative Group), patients with ocular melanoma make up 20% of all patients treated with proton radiotherapy [25].
In February 2011 in Kraków patients with choroidal melanoma began to be treated with proton radiotherapy.

Aim of the study

The objective of the study was to present the preliminary results of proton radiotherapy as a method for treating patients with choroidal melanoma.

Material and methods

Between February 2011 and March 2012 a total of 15 patients with choroidal melanoma underwent proton radiotherapy.
This group consisted of 7 women (46.7%) and 8 men (53.3%). The patients ranged in age between 38 and 74 with an average age of 56.1 (median 57 years).
The location and size of the tumour in the eyeball were determined in eye examinations conducted at the Department of Ophthalmology and Ocular Oncology Clinic, Jagiellonian University.

Patients

Presented in Table 1 are the characteristics of choroidal melanoma in the 15 patients.
In 10 of the 15 patients (66.7%) the tumour was located in the right eyeball. The tumour was predominantly located in the temporal quadrants of the choroid (53.3% of patients). Advanced T3 stage cancer was observed in 40% of the patients. The average distance of the margin of the tumour from the optic disc was 3.5 mm, and from the macula it was 2.21 mm. The average dimensions of the transverse (crosswise) and longitudinal (lengthwise) base of the tumour were 11.24 mm and 11.44 mm, respectively. The tumour thickness varied between 1.4 mm and 10.6 mm and was on average 5.05 mm.

Proton radiotherapy procedure

The proton radiotherapy was administered using beams emitted from an AIC-144 isochronic cyclotron at the Institute of Nuclear Physics PAN in Kraków. These beams provide energy levels of 60 MeV, which ensures a clinical range of 28.4 mm. In addition, the beam has a very narrow penumbra of 1.3 mm and a sharp distal dose fall-off.
Prior to administering proton radiotherapy tantalum markers were sown to the sclera of the eyeball (an example is presented in Fig. 1) and the distance was measured between the markers and the corneal limbus as well as between the markers and the edge of the tumour. The position of the markers was verified using imaging tests (USG, CT, MRI). Figure 2 shows an example of marker position verification using magnetic resonance imaging (MRI).
Based on the measurements and the clinical data and using a computerised treatment planning system, we created a virtual model of the eyeball with a reconstructed tumour. Radiotherapy planning was based on the Eclipse Ocular Proton Planning system developed by the company Varian Medical Systems.
The plan was to cover 90% of the planning target volume (PTV) content (tumour with margin of 2.5 mm) with isodose.
Figure 3 presents the dose distribution in PTV and dose-volume histograms in PTV and critical organs.
To ensure that the beam had the appropriate range and achieved a homogeneous dosage in PTV, we used individually selected beam modifiers (range discriminator, power modulator and collimator).
A dose of 60 CGE was administered in 4 fractions over 4 successive days of treatment.

Methods

At the end of the treatment the patients continued to be monitored as outpatients at the Department of Ophthalmology and Ocular Oncology Clinic, Jagiellonian University. During the study the clinical effects of proton radiotherapy were measured in terms of effectiveness and toxicity.
The effectiveness of proton radiotherapy was assessed as the degree of tumour regression while taking into account changes in the dimensions of the tumour. During the follow-up the side effects of the treatment and the patient’s vision function were also monitored.
Student’s t-test was used to compare the sizes of tumours and change of vision function prior to and after treatment, adopting  = 0.05 as the level of statistical significance.

Results

The effects of the treatment, assessed as the frequency of regression and change in tumour size and change of vision function, are presented in Table 2.
Measurements of the tumours (their transverse and longitudinal base as well as their thickness) showed a significant reduction in size following proton radiotherapy.
Figure 4 presents an example of a USG image taken before and after proton radiotherapy.
Following proton radiotherapy the tumour had regressed in 8 patients (53.3%) and remained stable in 3 patients (20%). The large tumours in another 3 patients (20%) were removed during vitrectomy (endoresection), which increased the number of patients with tumour regression up to 11 (73.3%). In the case of 1 patient, despite intraocular tumour regression occurring the choroidal melanoma had spread multifocally into the orbit, which necessitated orbit exenteration.
The results ensured that the eyeballs of 14 patients (93.3%) could be saved.
After proton radiotherapy distant best corrected visual acuity (BCVA) increased in 1 case, was stable in 5 and decreased in 9 patients.
The follow-up period for the 15 patients ranged between 8 and 26 months (average: 17.4 months, median value: 19 months). In this period some side effects were noted in the observation period, which are presented in Table 3.
An increase in intraocular pressure was observed in 9 of the patients (60%). This increase amounted on average to 2.8 mm Hg (range 1–6 mm Hg) compared with the pre-treatment levels. On the other hand, in certain individual cases other complications developed, such as retinal detachment, cataract, maculopathy, neuropathy and vitreous haemorrhaging.

Discussion

Proton radiotherapy treatment for patients with uveal melanoma is a conservative local method that has been employed since the 1970s and is regarded as one of the basic approaches to treating such patients [21].
Proton beams are used in radiotherapy due to their physical properties (limited range, sharp lateral penumbra, no increased dose effect on beam entry and practically no dose on beam exit), thanks to which it is possible to achieve a homogeneous distribution of a large dose in a limited volume (tumour with margin) while simultaneously ensuring excellent protection for healthy tissue and the vital organs by limiting the dose and irradiated volume [26, 27].
This method offers very good results in terms of local control (89–99%), with the eyeball preserved in more than 90% of cases and vision function maintained in more than 50% [19, 23, 28–38].
In the case of our own material, tumour regression was achieved in 73% of patients, the eyeball was saved in 93% and vision function in 90% of cases. It is important to note that these are only preliminary results for a group of 15 patients and were obtained over a relatively short observation period (median 19 months).
Proton radiotherapy represents an alternative to brachytherapy as a means of treating tumours located close to the macula or optic disc. Better results in terms of local control were observed following proton radiotherapy than was the case with brachytherapy, with no significant differences in survival rates [13, 39, 40]. The positive impact of proton radiotherapy on treatment can be seen in the reduced frequency of relapses or complications (primarily retinopathy and cataracts) following such treatment [41]. This translates into fewer cases requiring enucleation. The risk of enucleation due to complications is reduced by 47% after proton radiotherapy compared with brachytherapy [13].
In turn, Wilson et al. observed greater vision impairment with proton radiotherapy than was the case with brachytherapy [14].
A very important factor to consider is proton radiotherapy’s impact on the patient’s vision. According to data from the literature, the chances of preserving the patient’s sight depends on the location of the tumour. The vision function of 33–47% of the patients had deteriorated 1–2 years after proton radiotherapy when the tumour was located in the region of the macula or optic disc and in 17–28% of cases when the tumour was in a different location [24, 33].
In our material choroidal melanoma were located close to the macula and/or optic disc in 9 of 15 cases and it explains the visual acuity of 60% of patients during an average 17.4-month observation period.
The clinical effectiveness of proton radiotherapy (local control) can be improved by ensuring possible endoresection of the remaining part of the tumour [42]. This helps improve the outcome of treatment while at the same time preserving the eyeball.
Through local control and limiting the frequency of complications the eyeball can be saved, which is a very important argument in favour of proton radiotherapy.
Egger et al. analysed the material from 15 years ago (1984–1999) covering 2648 eyes in 2645 patients. They demonstrated that the most common reasons for enucleation were the following: loss of function, glaucoma, inflammation and cancer relapse. According to these researchers, the size of the tumour has a significant influence on whether the eyeball can be preserved. The 5- and 10-year eyeball preservation rates were 100% and 96.1% (for small tumours) and 99.7% and 64.8% (for large tumours), respectively [19].
Aziz et al. noted the following complications following proton radiotherapy: retinopathy (39%), cataracts (20%), inflammation of the uvea (17%), neuropathy (16%) and maculopathy (4%). Despite this fact, when the results in terms of local control are considered, the authors believe that proton radiotherapy is an effective method for treating patients with choroidal melanoma [15].
The most common side effect of proton radiotherapy revealed in our own material was increased intraocular pressure (60% of patients), while other complications only occurred in individual cases. As mentioned earlier, it is important to bear in mind that the observation period for the group in the present study was short and the group itself comprised 15 patients.
One advantage of proton radiotherapy is that it ensures a homogeneous dose distribution in a limited volume. The application of advanced photon radiotherapy techniques (stereotactic, gamma knife, IMRT) makes it possible to achieve a comparable high dose distribution [17, 18]. The differences lie in the excellent protection of healthy tissue and the critical organs, and it is precisely here where proton radiotherapy has the edge. In summary, our preliminary results concerning a small group of 15 patients with a median observation period of 19 months confirm that proton radiotherapy is an effective method for treating patients with choroidal melanoma.
This method ensures an eyeball preservation rate of 93%, with the vision function of 80% of the patients being saved.
Nevertheless, our preliminary results and those published in the literature confirm that proton radiotherapy is an effective and safe method for treating patients with choroidal melanoma.

The authors declare no conflict of interest.

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Address for correspondence
Beata Sas-Korczyńska
MD, PhD
Clinic of Oncology – Department of Breast and Chest Cancer
Centre of Oncology – Maria Sklodowska-Curie Memorial Institute
Krakow Branch
Garncarska 11
31-115 Krakow, Poland
e-mail: z5korczy@cyf-kr.edu.pl
Submitted: 25.10.2013
Accepted: 3.02.2014
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