The factors affecting local tumor control after stereotactic body radiotherapy for non-small cell lung cancer
Commentary

The factors affecting local tumor control after stereotactic body radiotherapy for non-small cell lung cancer

Satoru Ochiai1, Yasufumi Yamashita1, Yoshihito Nomoto2

1Department of Radiation Oncology, Matsusaka Central Hospital, Matsusaka, Japan; 2Department of Radiology, Mie University School of Medicine, Tsu, Japan

Correspondence to: Satoru Ochiai, MD. Department of Radiation Oncology, Matsusaka Central Hospital, 102 Kobou Kawai-machi, Matsusaka, Mie 515-8566, Japan. Email: sochiai1981@gmail.com.

Comment on: Davis JN, Medbery C, Sharma S, et al. Stereotactic body radiotherapy for centrally located early-stage non-small cell lung cancer or lungmetastases from the RSSearch(®) patient registry. Radiat Oncol 2015;10:113.


Submitted Sep 28, 2015. Accepted for publication Oct 01, 2015.

doi: 10.3978/j.issn.2218-676X.2015.10.08


Stereotactic body radiotherapy (SBRT), also called stereotactic ablative radiotherapy (SABR), has been widely used as an effective treatment for early-stage lung cancer, especially in medically inoperable cases (1,2). The local control (LC) rates after SBRT for early-stage non-small cell lung cancer (NSCLC) have been reported to be 85-98% (1). Although the treatment results seem to be favorable, several risk factors for local tumor progression have been reported. Here, we would like to summarize and discuss about reported factors that affect local tumor control after SBRT.

Tumor stage

Tumor stage is one of the most well recognized risk factor for local tumor progression after SBRT. Onimaru et al. analyzed the treatment results of 41 patients with stage I NSCLC (25 with T1 and 16 with T2 tumor) treated by SBRT (3). The dose fractionation schedule of SBRT was 40 or 48 Gy in 4 fractions within 1 week. They reported that T stage was a significant factor for LC in multivariate analysis. Dunlap et al. compared the LC rates of 40 patients with peripheral T1 and T2 NSCLC treated with SBRT (4). SBRT was delivered at a median dose of 60 Gy in 3 or 5 fractions. Increasing tumor size correlated with worse LC. LC at 2 years was 90% and 70% in T1 and T2 tumors, respectively (P=0.03). Matsuo et al. investigated the factors that influence clinical outcomes after SBRT for NSCLC (5). A total of 101 patients underwent SBRT with 48 Gy in 4 fractions were evaluated. Factors including age, maximum tumor diameter, sex, performance status, operability, histology, and overall treatment time were evaluated. Tumor diameter was the only significant factor for local progression in a Cox proportional hazards model. Shirata et al. investigated the prognostic factors for LC of stage I NSCLC in SBRT (6). Eighty patients (81 lesions) treated with 3 dose levels, 48 Gy in 4 fractions, 60 Gy in 8 fractions and 60 Gy in 15 fractions were evaluated. The 3-year LC rates were 89.0% with T1 tumors and 64.8% in those with T 2 tumors (log-rank P=0.001) and T factor was shown to be a significant factor for LC with a Cox proportional hazard model analysis (P=0.013).

These findings indicate that T2 tumor, compared with T1 tumor, is the risk factor for local progression after SBRT for early-stage NSCLC.


The maximum standardized uptake value (SUVmax) on F18-fluorodeoxyglucose positron emission tomography (FDG-PET)

Pre-treatment SUVmax of primary tumor on FDG-PET is also described predictive factor for LC after SBRT in several reports. Takeda et al. evaluated the relationship between SUVmax on FDG-PET of 95 patients with 97 tumors and local recurrence (7). By multivariate analysis, the SUVmax of a primary tumor was the only predictive factor for local recurrence (P=0.002). Two-year LC rates for lower SUV-max (less than 6.0) and higher SUV-max (6.0 or more) were 93% and 42%, respectively. Clarke et al. investigated if SUVmax on pre-treatment FDG-PET would predict clinical outcome after SBRT for early-stage NSCLC (8). Eighty two patients who were evaluated with FDG-PET before SBRT were analyzed. On univariate analysis SUVmax predicted for local failure (P=0.044). Na et al. reported a meta-analysis of prediction value of SUVmax for the outcome in NSCLC receiving radiotherapy (9). In the analysis of SBRT group, hazard ratio for LC was reported to be 1.11 (95% confidence interval, 1.06-1.18) for SUVmax of pre-treatment FDG-PET.

Although the optimal cut-off value of SUVmax is still controversial, “high” primary tumor SUVmax seemed to be a risk factor for local tumor progression.


Overall treatment time of SBRT

Kestin et al. investigated the factors that affect the clinical outcome for lung SBRT (10). Five hundred five tumors in 483 patients with clinical stage T1-T2N0 NSCLC treated with SBRT at 5 institutions were evaluated. In their analysis, overall treatment time of SBRT correlated to 2-year local recurrence. Two-year local tumor progression rates for longer overall treatment time of SBRT (11 or more elapsed days) and shorter overall treatment time (less than 10 days) were 14% and 4%, respectively (P<0.01). The longer overall treatment time might have a negative effect on the outcome after SBRT.


Dose-response relationship

The applicability of biologically equivalent dose (BED) employing a large dose per fraction is criticized by the likelihood overestimating the BED (11). However many clinicians often use the linear-quadratic (LQ) model and BED to estimate the effects of various radiation schedules. It has been also reported that the LQ model fits the radiation response of epithelial tissues <23 Gy per fraction (12). Onishi et al. reported multicenter retrospective study of SBRT for stage I NSCLC (13). Two hundred fifty five patients were analyzed and the median BED 10 was 111 Gy (range, 57-180 Gy). The local tumor progression rate was 8.4% for a BED of 100 Gy or more compared with 42.9% for less than 100 Gy (P<0.001). Kestin et al. examined dose-response relationships with various NSCLC SBRT fraction regimens (10). Five hundred five tumors in 483 patients with clinical stage T1-T2N0 NSCLC treated with SBRT at 5 institutions were evaluated. Median prescription BED 10 was 132 Gy (50.4-180). Two-year local recurrence rates were 4% and 15% for BED10 >105 Gy and BED <105 Gy, respectively (P<0.01). According to these findings, BED 100 Gy or more generally seemed to be necessary for SBRT in order to achieve a more than 90% LC rate.


Dose-escalation

Although the LC rate of small tumor after SBRT seemed to be excellent, that of larger tumor, such as T2 tumor, is not still unsatisfied. Davis et al. reported the clinical outcome of patients with T1-T2N0M0 and treated with SBRT. The RSSearch® Patient Registry was screened for 723 patients (517 with T1 and 244 with T2) (14). Median SBRT dose was 54 Gy (range, 10-80 Gy) delivered in a median of 3 fractions (range, 1-5), and median BED10 was 151.2 Gy (range, 20-240 Gy). LC was associated with higher BED10 for T2 tumors. Seventeen-month LC rate for T2 tumors treated with BED10 <105 Gy, BED10 105-149, and BED10 150 or more was 43%, 74%, and 95% respectively (P=0.011). On the other hand, there was not significant association between higher BED10 and T1 tumors. These results indicate that dose-escalation in SBRT might be beneficial for the treatment of larger tumor. On the other hand, Mehta et al. reported that dose-escalation beyond a BED10 of 159 Gy likely translates to a clinically insignificant gain in tumor control probability but may result in clinically significant toxicity (15). Zhang et al. reported a meta-analysis of SBRT for stage I NSCLC (16). BED was divided into four groups: low (<83.2 Gy), medium (83.2-106 Gy), medium to high (106-146 Gy), high (>146 Gy) and the treatment outcome was evaluated. The overall survival for the medium or medium to high BED groups was higher than those for the low or high BED groups. Therefore medium or medium to high BED (range, 83.2-146 Gy) was indicated to be more beneficial and reasonable BED. Thus, careful attention should be paid in case of dose-escalation of SBRT for early-stage NSCLC.

Recently, the results of JCOG0702 trial (multicenter phase I study of SBRT for T2N0M0 NSCLC with planning target volume <100 cc) were reported (17). The dose of SBRT was prescribed at D95 of the PTV. The recommend dose was determined to be 55 Gy in 4 fractions in the study. Further prospective studies are needed to determine whether dose-escalated SBRT improve clinical outcomes.


Centrally located tumor

Timmerman et al. reported a phase II study of SBRT for medically inoperable stage I NSCLC (18). SBRT treatment dose was 60 to 66 Gy total in 3 fractions. In their study, SBRT for central tumors was associated with a greater than 10-fold increase risk of high grade toxicity or death. According to the results, SBRT with high dose for centrally located tumor has been considered to be risky. On the other hand, several investigators have reported favorable outcomes and toxicity profiles with moderate dose of SBRT (19).

Recently, Davis et al. reported treatment patterns and outcomes of SBRT for centrally located NSCLC or lung metastases from the RSSearch® (20). One hundred eleven patients with 114 centrally located lung tumors (48 T1-T2N M0 NSCLC) were evaluated. Median dose to centrally located NSCLC was 48 Gy and median BED10 was 105.6 Gy. Two-year LC rate was 76.4% and toxicity was low with no grade 3 or higher acute or late toxicities.

JROSG10-1 and RTOG0813 are dose escalation studies of SBRT for centrally located stage I NSCLC. Data from these trials will provide prospective date to determine the feasibility and optimal dose fractionation of SBRT for these tumors.

In summary, SBRT has been considered as highly effective treatment for early-stage NSCLC. However, there are still many unsolved issues, such as optimal dose fractionation or tolerable dose of normal organs. Further studies are warranted to provide the optimal treatment.


Acknowledgments

Funding: None.


Footnote

Provenance and Peer Review: This article was commissioned by the editorial office, Translational Cancer Research. The article did not undergo external peer review.

Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at http://dx.doi.org/10.3978/j.issn.2218-676X.2015.10.08). The authors have no conflicts of interest to declare.

Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

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References

  1. Nagata Y. Stereotactic body radiotherapy for early stage lung cancer. Cancer Res Treat 2013;45:155-61. [PubMed]
  2. Onishi H, Araki T. Stereotactic body radiation therapy for stage I non-small-cell lung cancer: a historical overview of clinical studies. Jpn J Clin Oncol 2013;43:345-50. [PubMed]
  3. Onimaru R, Fujino M, Yamazaki K, et al. Steep dose-response relationship for stage I non-small-cell lung cancer using hypofractionated high-dose irradiation by real-time tumor-tracking radiotherapy. Int J Radiat Oncol Biol Phys 2008;70:374-81. [PubMed]
  4. Dunlap NE, Larner JM, Read PW, et al. Size matters: a comparison of T1 and T2 peripheral non-small-cell lung cancers treated with stereotactic body radiation therapy (SBRT). J Thorac Cardiovasc Surg 2010;140:583-9. [PubMed]
  5. Matsuo Y, Shibuya K, Nagata Y, et al. Prognostic factors in stereotactic body radiotherapy for non-small-cell lung cancer. Int J Radiat Oncol Biol Phys 2011;79:1104-11. [PubMed]
  6. Shirata Y, Jingu K, Koto M, et al. Prognostic factors for local control of stage I non-small cell lung cancer in stereotactic radiotherapy: a retrospective analysis. Radiat Oncol 2012;7:182. [PubMed]
  7. Takeda A, Yokosuka N, Ohashi T, et al. The maximum standardized uptake value (SUVmax) on FDG-PET is a strong predictor of local recurrence for localized non-small-cell lung cancer after stereotactic body radiotherapy (SBRT). Radiother Oncol 2011;101:291-7. [PubMed]
  8. Clarke K, Taremi M, Dahele M, et al. Stereotactic body radiotherapy (SBRT) for non-small cell lung cancer (NSCLC): is FDG-PET a predictor of outcome? Radiother Oncol 2012;104:62-6. [PubMed]
  9. Na F, Wang J, Li C, et al. Primary tumor standardized uptake value measured on F18-Fluorodeoxyglucose positron emission tomography is of prediction value for survival and local control in non-small-cell lung cancer receiving radiotherapy: meta-analysis. J Thorac Oncol 2014;9:834-42. [PubMed]
  10. Kestin L, Grills I, Guckenberger M, et al. Dose-response relationship with clinical outcome for lung stereotactic body radiotherapy (SBRT) delivered via online image guidance. Radiother Oncol 2014;110:499-504. [PubMed]
  11. Park C, Papiez L, Zhang S, et al. Universal survival curve and single fraction equivalent dose: useful tools in understanding potency of ablative radiotherapy. Int J Radiat Oncol Biol Phys 2008;70:847-52. [PubMed]
  12. Fowler JF, Tomé WA, Fenwick JD, et al. A challenge to traditional radiation oncology. Int J Radiat Oncol Biol Phys 2004;60:1241-56. [PubMed]
  13. Onishi H, Shirato H, Nagata Y, et al. Hypofractionated stereotactic radiotherapy (HypoFXSRT) for stage I non-small cell lung cancer: updated results of 257 patients in a Japanese multi-institutional study. J Thorac Oncol 2007;2:S94-100. [PubMed]
  14. Davis JN, Medbery C 3rd, Sharma S, et al. Stereotactic body radiotherapy for early-stage non-small cell lung cancer: clinical outcomes from a National Patient Registry. J Radiat Oncol 2015;4:55-63. [PubMed]
  15. Mehta N, King CR, Agazaryan N, et al. Stereotactic body radiation therapy and 3-dimensional conformal radiotherapy for stage I non-small cell lungcancer: A pooled analysis of biological equivalent dose and local control. Pract Radiat Oncol 2012;2:288-95. [PubMed]
  16. Zhang J, Yang F, Li B, et al. Which is the optimal biologically effective dose of stereotactic body radiotherapy for Stage I non-small-cell lungcancer? A meta-analysis. Int J Radiat Oncol Biol Phys 2011;81:e305-16. [PubMed]
  17. Onimaru R, Shirato H, Shibata T, et al. Phase I study of stereotactic body radiation therapy for peripheral T2N0M0 non-small cell lung cancer with PTV<100cc using a continual reassessment method (JCOG0702). Radiother Oncol 2015;116:276-80. [PubMed]
  18. Timmerman R, McGarry R, Yiannoutsos C, et al. Excessive toxicity when treating central tumors in a phase II study of stereotactic body radiation therapy for medically inoperable early-stage lung cancer. J Clin Oncol 2006;24:4833-9. [PubMed]
  19. Senthi S, Haasbeek CJ, Slotman BJ, et al. Outcomes of stereotactic ablative radiotherapy for central lung tumours: a systematic review. Radiother Oncol 2013;106:276-82. [PubMed]
  20. Davis JN, Medbery C, Sharma S, et al. Stereotactic body radiotherapy for centrally located early-stage non-small cell lung cancer or lungmetastases from the RSSearch(®) patient registry. Radiat Oncol 2015;10:113. [PubMed]
Cite this article as: Ochiai S, Yamashita Y, Nomoto Y. The factors affecting local tumor control after stereotactic body radiotherapy for non-small cell lung cancer. Transl Cancer Res 2015;4(5):574-577. doi: 10.3978/j.issn.2218-676X.2015.10.08

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