NTCP modelling of lung toxicity after SBRT comparing the universal survival curve and the linear quadratic model for fractionation correction

Abstract Background. In SBRT of lung tumours no established relationship between dose-volume parameters and the incidence of lung toxicity is found. The aim of this study is to compare the LQ model and the universal survival curve (USC) to calculate biologically equivalent doses in SBRT to see if th...

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Bibliographic Details
Published in:Acta oncologica 2011, Vol.50 (4), p.518-527
Main Authors: Wennberg, Berit M., Baumann, Pia, Gagliardi, Giovanna, Nyman, Jan, Drugge, Ninni, Hoyer, Morten, Traberg, Anders, Nilsson, Kristina, Morhed, Elisabeth, Ekberg, Lars, Wittgren, Lena, Lund, Jo-Åsmund, Levin, Nina, Sederholm, Christer, Lewensohn, Rolf, Lax, Ingmar
Format: Article
Language:English
Subjects:
Aged
Aged, 80 and over
Cancer and Oncology
Cancer och onkologi
Clinical Medicine
Clinical Trials, Phase II as Topic
Dose Fractionation
Female
Humans
Klinisk medicin
Linear Models
Lung - pathology
Lung - radiation effects
Lung Neoplasms - diagnostic imaging
Lung Neoplasms - pathology
Lung Neoplasms - radiotherapy
Male
Medical and Health Sciences
MEDICIN
Medicin och hälsovetenskap
MEDICINE
Middle Aged
Multicenter Studies as Topic
Prognosis
Radiation Injuries - etiology
Radiography
Radiosurgery - adverse effects
Survival Rate
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Summary:Abstract Background. In SBRT of lung tumours no established relationship between dose-volume parameters and the incidence of lung toxicity is found. The aim of this study is to compare the LQ model and the universal survival curve (USC) to calculate biologically equivalent doses in SBRT to see if this will improve knowledge on this relationship. Material and methods. Toxicity data on radiation pneumonitis grade 2 or more (RP2+) from 57 patients were used, 10.5% were diagnosed with RP2+. The lung DVHs were corrected for fractionation (LQ and USC) and analysed with the Lyman- Kutcher-Burman (LKB) model. In the LQ-correction α/β = 3 Gy was used and the USC parameters used were: α/β = 3 Gy, D0 = 1.0 Gy, = 10, α = 0.206 Gy−1 and dT = 5.8 Gy. In order to understand the relative contribution of different dose levels to the calculated NTCP the concept of fractional NTCP was used. This might give an insight to the questions of whether "high doses to small volumes" or "low doses to large volumes" are most important for lung toxicity. Results and Discussion. NTCP analysis with the LKB-model using parameters m = 0.4, D50 = 30 Gy resulted for the volume dependence parameter (n) with LQ correction n = 0.87 and with USC correction n = 0.71. Using parameters m = 0.3, D50 = 20 Gy n = 0.93 with LQ correction and n = 0.83 with USC correction. In SBRT of lung tumours, NTCP modelling of lung toxicity comparing models (LQ,USC) for fractionation correction, shows that low dose contribute less and high dose more to the NTCP when using the USC-model. Comparing NTCP modelling of SBRT data and data from breast cancer, lung cancer and whole lung irradiation implies that the response of the lung is treatment specific. More data are however needed in order to have a more reliable modelling.
ISSN:0284-186X
1651-226X
1651-226X
DOI:10.3109/0284186X.2010.543695