Purpose: Nasal lymphoma created dosimetric challenges in radiotherapy due to the complex anatomical structures. This study was to evaluate the efficacy and toxicity of helical Tomotherapy (HT) in the treatment of nasal NK/T-cell lymphoma (NKTCL) patients. Methods and Materials: Between August 2008 and April 2013, a total of 25 NKTCL patients were treated with HT in our department; Among them, three patients have not received chemotherapy, one patient has received concurrent chemo-radiation with CHOP plus L-ASP, two patients have received the sequential chemotherapy regimen following irradiation, and all the others have received 1 - 2 cycles of induction chemotherapy followed by irradiation and then with sequential chemotherapy. CHOP-L with 1 - 7 cycles (median: 4 cycles) was utilized as the main chemotherapy regimen. As for HT, the gross tumor volume (GTV) received target doses (TD) ranging from 50 to 56 Gy (median: 50 Gy) at 2 - 2.78 Gy per fraction; and the clinical target volume (CTV) from 36 to 50 Gy (median: 40 Gy) at 1.6 - 2 Gy per fraction. Results: For those patients who had received irradiation, thirteen achieved complete remission (CR), four partial responses (PR); four had progressive disease (PD), two were lost to follow-up, two died within one month after irradiation and were not followed. In 21 patients with follow-up records, the overall response (CR + PR) was 81.0% with the 3-year survival rate of 87.2%, and the mean survival time was 52.8 months [95% confidence interval (CI): 45.2 - 60.4 months]. After radiotherapy the majority of patients had dry mouth and taste changes in varying degrees, and a small portion of patients had compromised hearing or vision functions. No brain injury symptoms occurred during radiation radiotherapy. Conclusions: As compared with conventional three-dimensional conformal radiotherapy (3D-CRT) and intensity modulated radiation therapy (IMRT) performed with HT, HT appears to have more favorable efficacy and toxicity profiles in the treatment of NKTCL. Further systematic and randomized clinical research is under investigation.
Nasal NK/T-cell lymphoma (NKTCL) is an uncommon disease, but it is much more frequent in Asia and Latin American countries than in Western countries. NKTCL is classified as a special type of non-Hodgkin’s lymphoma (NHL) with clinical staging [
Following the rapid development of imaging techniques and radiotherapy devices, 3D-CRT, IMRT and HT were introduced in quick succession into clinical practice between the 1990s and the beginning of this century. In 2005 the US began to use HT, and in 2007 our hospital installed the first HT treatment unit in China. As compared with conventional IMRT, HT features a wider selection of radiation fields, higher dose to the tumor, and relatively short treatment time. HT is an image-guided radiation therapy (IGRT). Dosimetric coverage of the target with HT is highly conformal and homogeneous. This paper aims to examine the benefits of HT in clinical practice, by reviewing 25 cases receiving HT to treat NKTCL and assessing its efficacy and toxicity.
1) Patient characteristics
Between August 2008 and April 2013, a total of 25 NKTCL patients were treated with radiotherapy in our department, among those patients who received HT and had medical records that were kept intact. All of them had a KPS score of more than 80. The clinical characteristics of the patients are summarized in
2) Chemotherapy
In patients treated with HT, three of them had not received chemotherapy, one received concurrent chemo- radiation with CHOP plus L-ASP, two received sequential chemotherapy following irradiation, and the others received 1 - 2 cycles of induction chemotherapy followed by irradiation and then sequential chemotherapy. CHOP-L with 1 - 7 cycles (median: 4 cycles) was used as the main chemotherapy regimen.
3) Methodology
Patients were immobilized in the supine position with a thermoplastic mask. Treatment-planning CT images were acquired from the top of the head to inion with a 3-mm slice thickness. The dose rate was calibrated at 860 cGy/min. The leaf width was 6.25 mm at isocenter. A 6 MV linear accelerator delivered radiation in a helical mode. The GTV was the gross demonstrable extent and location of the tumor. If the visible tumor disappeared following chemotherapy treatment, the CTV will then be delineated, which included the tumor location and its possible extension pathways (such as nasopharynx, palate and paranasal sinuses). If the tumor was confined to one side of the nasal cavity, and no neighboring organs or tissues were affected, the CTV should include nasal cavities and anterior ethmoid sinuses on both sides; hard palate, as well as maxillary sinus on the same side. If the tumor spread beyond the nasal cavity, the CTV should extend to neighboring organs or tissues which had been affected. Prophylactic neck irradiation was recommended at the same time for patients with a confirmed diagnosis of cervical metastases. Expansion of the CTV by 3 mm in all directions resulted in the planning target volume (PTV) to account for immobilization inaccuracy. In this study the GTV received TD ranging from 50 to
Characteristics | Cases | % |
---|---|---|
Gender | ||
Male | 15 | 60 |
Female | 10 | 40 |
Age | ||
Median | 48 | |
Range | 22 - 67 | |
Ann Arbor staging | ||
IE | 11 | 44 |
IIE | 13 | 52 |
IVE | 1 | 4 |
B symptoms | ||
Yes | 16 | 64 |
No | 9 | 36 |
Modified Ann Arbor staging | ||
Limited stage IE | 8 | 32 |
Extensive stage IE | 3 | 12 |
IIE | 13 | 52 |
IVE | 1 | 4 |
Neck lymph node metastasis | ||
Yes | 3 | 12 |
No | 22 | 88 |
Lacto dehydrogenase | ||
Elevated | 2 | 8 |
Normal | 14 | 56 |
Unknown | 9 | 36 |
IPI index | ||
Low risk (0 - 1 points) | 15 | 60 |
Low-intermediate risk (2 points) | 1 | 4 |
High-intermediate risk (3 points) | 1 | 4 |
High risk (4 - 5 points) | 0 | 0 |
Unclassified | 8 | 32 |
56 Gy (median: 50 Gy) at 2 - 2.78 Gy per fraction; and the CTV from 36 to 50 Gy (median: 40 Gy) at 1.6 - 2 Gy per fraction. A dose of 50 Gy in 25 fractions was prescribed in patients for whom only the CTV was delineated.
4) Efficacy assessment and criteria for adverse reactions
One month after the end of treatment patients were re-examined to assess the efficacy. According to the WHO definitions published in 1979, patients were assigned the four categories of complete response (CR), partial response (PR), stable disease (SD), and progressive disease (PD) on the basis of the measurement criteria. Survival time is defined as the time from the end of radiotherapy to the last follow-up visit or death. The criteria of the Radiation Therapy Oncology Group (RTOG) were used to assess adverse reactions and acute and late toxicity. Acute toxicities include dry mouth, painful swallowing, dysphagia, and skin and mucosa reactions. Late toxicities include dry mouth, taste changes, impaired hearing and vision, and brain injury.
5) Follow-up and statistical analysis
Patients were re-examined at regular intervals at the outpatient clinic after the radiotherapy. Within 2 years after the treatment follow-up took place once every 3 months; once every 6 months in between 2 - 5 years; over 5 years then once a year. Telephone follow-ups were conducted from the date when the radiotherapy finished or terminated before 28 August 2013. Follow-up telephone calls enquired about the patient’s performance status, time for the latest follow-up and results, whether there were adverse reactions, when the reactions had occurred and extent of the adverse effects. If the patient had died we should enquire about the time and cause of death. The Kaplan-Meier method was used to conduct the survival rate analysis. Results from all cases were analyzed using SPSS™ (Chicago, IL) Statistics version 13 with a significance level of 0.05 as the basic guidelines for clinical dosimetry significance representation in this study.
1) Follow-up
As of 28th August 2013, four patients in the study group were lost to follow-up, who received the last follow- up call at, respectively, 60, 36, 24, 14 months after radiotherapy. The follow-up rate was 84%. The follow-up lasted 4 - 49 months, with a median follow-up time of 31 months.
2) Dosimetry Analysis
The total scheduled time from the simulation to the starting treatment was averaged 5 - 6 days (standard deviation 3 - 8 days). From the acquired planning data from the Tomotherapy planning results, total delivery time was reported with 368.4 seconds (Standard deviation = 197.4 - 614.8 seconds). The mean pGTV and PTV doses were 53.6 Gy and 49.1 Gy, respectively (p < 0.001). All the critical structures were reported within clinical tolerances, and brain stem and spinal cord were reported 37.3 Gy and 28.8 Gy, respectively (p < 0.001). All lens’ doses were less than 5 Gy, and the bi-lateral parotid glands mean doses were 19.7 Gy and 20.0 Gy, respectively (p < 0.001). All the correlated dose distributions were summarized in
3) Efficacy
One patient terminated before the last 3 treatment sessions due to being unable to tolerate adverse reactions. The others completed radiotherapy as planned. Following the radiotherapy, within 25 patients, thirteen achieved CR, four PR; four had PD; two were lost during follow-up and were not re-examined; two died within one month after radiotherapy. In 21 patients with follow-up records, the overall response (CR + PR) was 81.0%.
In this group, the 3-year overall survival rate was 87.2%, and the mean survival time was 52.8 months (95% CI: 45.2 - 60.4 months). As of the last follow-up, the patients in this group had no recurrence or metastasis. A total of three patients died, two resulting from deterioration of health conditions one month after radiotherapy, one resulting from multiple organ failure following bone marrow transplantation at 9 months period. The overall survival rate of 25 patients in the study group was depicted in
4) Side-effects
During the radiotherapy the blood test results for three patients were lost. Within the other 22 patients, only one had serious bone marrow suppression (
Late toxicity is defined as the adverse reactions occurring 6 months after radiotherapy. In nineteen patients who were successfully traced and lived for more than 6 months after radiotherapy, the majority had dry mouth and taste changes in varying degrees, and a small portion of patients had compromised hearing or vision. No brain injury symptoms occurred (
Target | pGTV | PTV |
---|---|---|
Prescription dose | 51.1 ± 2.1 (50.0 - 56.0) | 45.7 ± 5.1 (36.0 - 50.0) |
Maximum dose | 57.3 ± 3.0 (54.0 - 64.7) | 56.5 ± 3.58 (50.0 - 66.9) |
Minimum dose | 44.4 ± 8.2 (21.7 - 54.0) | 34.6 ± 9.93 (8.88 - 48.1) |
Mean dose | 53.6 ± 2.6 (51.5 - 59.3) | 49.1 ± 4.6 (42.1 - 58.6) |
Volume (cm3) | 139.1 ± 137.8 (24.4 - 535.5) | 468.2 ± 308.8 (79.7 - 1031.6) |
Mean value (Range, Gy) | |
---|---|
Brainstem Dmax | 37.3 (19.4 - 57.8) |
Spinal cord Dmax | 28.8 (3.7 - 50.8) |
Left optic nerve | |
Dmax | 48.1 (37.3 - 63.8) |
Dmean | 39.8 (23.8 - 56.6) |
Right optic nerve | |
Dmax | 47.1 (34.8 - 62.9) |
Dmean | 38.7 (26.5 - 59.2) |
Left eyeball | |
Dmax | 39.1 (21.2 - 51.3) |
Dmean | 14.0 (5.3 - 27.7) |
Right eyeball | |
Dmax | 40.3 (20.7 - 49.9) |
Dmean | 14.8 (7.45 - 48.5) |
Left lens Dmax | 4.7 (2.7 - 7.8) |
Right lens Dmax | 4.5 (2.8 - 6.6) |
Left parotid glands Dmean | 19.7 (7.0 - 40.0) |
Right parotid glands Dmean | 20.0 (6.7 - 38.9) |
Oral cavity Dmean | 30.2 (16.3 - 45.8) |
WBC | Platelet | Anemia | |
---|---|---|---|
Grade 0 | 17 (77.3) | 19 (86.4) | 17 (77.3) |
Grade 1 | 2 (9.1) | 1 (4.5) | 5 (22.7) |
Grade 2 | 2 (9.1) | 2 (9.1) | 0 |
Grade 3 | 0 | 0 | 0 |
Grade 4 | 1 (4.5) | 0 | 0 |
Skin reactions | Salivary gland | Dysphagia | |
---|---|---|---|
Grade 0 | 3 (12) | 7 (28) | 3 (12) |
Grade 1 | 22 (88) | 14 (56) | 18 (72) |
Grade 2 | 0 | 4 (16) | 4 (16) |
Grade 3 | 0 | 0 | 0 |
Grade 4 | 0 | 0 | 0 |
Salivary gland | Taste | Vision | Hearing | |
---|---|---|---|---|
Grade 0 | 9 (47.4) | 10 (52.7) | 17 (89.4) | 16 (84.2) |
Grade 1 | 8 (42.1) | 7 (36.8) | 1 (5.3) | 2 (10.5) |
Grade 2 | 2 (10.5) | 2 (10.5) | 1 (5.3) | 1 (5.3) |
Grade 3 | 0 | 0 | 0 | 0 |
Grade 4 | 0 | 0 | 0 | 0 |
The NKTCL shows a strong association with Epstein-Barr virus. One of the obvious pathological features is the angio-centric distribution of the tumor cells and angio-destruction pattern. Patients usually present with necrotic changes in the nasal cavity. Patients are usually diagnosed with the disease at the localized Stage I - II, and regional lymph node metastases are very rare. Although resistant to chemotherapy, the tumor is sensitive to irradiation. Therefore, radiotherapy is chosen as the main treatment method for early-stage NKTCL. A higher radiation dose and wider radiation field can help improve the local control. NKTCL at the limited Stage IE, if consisting of no negative prognostic indicators, can be treated with radiotherapy alone. Irradiation followed by chemotherapy is recommended for patients at Stage IIE and IE with negative prognostic indicators. Patients with disease above Stage III should use chemotherapy as the main treatment modality, coupled with irradiation at the local site. Many studies have shown that the medians of total radiation doses for NKTCL are 50 - 58 Gy [
An ideal treatment plan for radiotherapy was to achieve cure by prescribing as high a radiation dose as possible to the target volumes, and simultaneously reduced the impact or damage to healthy surrounding tissues. Side effects of radiation therapy depend on which critical organs were irradiated and the doses were given with respect to the critical dose tolerances. In most of the planning situation, HT possessed better conformal target coverage and more homogeneous dose distribution, with superior dose shaping capability and critical organ sparing compared with conventional 3D/IMRT plans [
There has been limited research work conducted on whether HT’s advantage from the dosimetric aspect can be embodied in the treatment of NKTCL. In early-stage NKTCL patients, using radiotherapy only or chemo- radiation can achieve a CR rate of 70% - 94% [
As for evaluation of acute toxicities, only one patient had a grade 4 low white blood cell count during radiotherapy, while no bone marrow suppression above grade 2 occurred in the other patients. On the other hand, Yamaguchi et al. treated 33 NKTCL patients with 3D-CRT coupled with combination chemotherapy, and found there were low counts of white blood cell, platelet and hemoglobin at grade 3 or 4 [
Late toxicity is defined as the adverse reactions occurring at 6 months after the end of radiotherapy. In this study the most common late toxicities include dry mouth and taste changes. Zheng et al. conducted a study about the efficacy and safety of IMRT in treating NKTCL patients, in which there were fewer patients not presenting with dry mouth than in this study (42.9% vs. 47.4%), and more patients with grade 1 and 2 dry mouth symptom (42.9% vs. 42.1%, 14.3% vs. 10.5%). As for taste changes, there were fewer patients not presenting with this reaction than in this study (42.9% vs. 52.7%), and more patients with grade 1 taste changes (50.0% vs. 36.8%); however, Zheng et al.’s study had fewer patients with grade 2 taste changes (7.1% vs.10.5) [
From this first clinical systematic study, our research results showed that there were very few clinical subjects which experienced compromised hearing and vision loss at late stage. In summary, only 2 patients had impaired vision (grade 1: 1 case; grade 2: 1 case), and 3 had impaired hearing (grade 1: 2 cases; grade 2: 1 case). No severe late reactions (above grade 2) had occurred. As a whole, HT has, in general, a better safety profile in terms of occurrence of late toxicities resulting from radiotherapy to treat NKTCL patients in our follow-up cases.
However, the direct comparison of HT and IMRT in terms of the above mentioned variables depends on future research and more clinical data with long term analysis. Results generated from this study can provide a basis for choice of treatment options in routine clinical practice. With current follow-up trend in our clinic, we hope that HT dosimetric benefits could eventually translated into more NKTCL patient survival with good quality of life index.
We are very grateful to the patients and their families for participating in this study. We also thank all of the clinicians, nurses, pathologists and study coordinators for their contributions to the work.