Radiation pneumonitis after hypofractionated radiotherapy: evaluation of the LQ(L) model and different dose parameters

Gerben R Borst; Masayori Ishikawa; Jasper Nijkamp; Michael Hauptmann; Hiroki Shirato; Gerard Bengua; Rikiya Onimaru; A de Josien Bois; Joos V Lebesque; Jan-Jakob Sonke

doi:10.1016/j.ijrobp.2009.10.015

Radiation pneumonitis after hypofractionated radiotherapy: evaluation of the LQ(L) model and different dose parameters

Gerben R Borst, Masayori Ishikawa, Jasper Nijkamp, Michael Hauptmann, Hiroki Shirato, Gerard Bengua, Rikiya Onimaru, A de Josien Bois, Joos V Lebesque, Jan-Jakob Sonke

Division of Cancer Sciences (L5)

Research output: Contribution to journal › Article › peer-review

Abstract

PURPOSE: To evaluate the linear quadratic (LQ) model for hypofractionated radiotherapy within the context of predicting radiation pneumonitis (RP) and to investigate the effect if a linear (L) model in the high region (LQL model) is used.

METHODS AND MATERIALS: The radiation doses used for 128 patients treated with hypofractionated radiotherapy were converted to the equivalent doses given in fractions of 2 Gy for a range of alpha/beta ratios (1 Gy to infinity) according to the LQ(L) model. For the LQL model, different cut-off values between the LQ model and the linear component were used. The Lyman model parameters were fitted to the events of RP grade 2 or higher to derive the normal tissue complication probability (NTCP). The lung dose was calculated as the mean lung dose and the percentage of lung volume (V) receiving doses higher than a threshold dose of xGy (V(x)).

RESULTS: The best NTCP fit was found if the mean lung dose, or V(x), was calculated with an alpha/beta ratio of 3 Gy. The NTCP fit of other alpha/beta ratios and the LQL model were worse but within the 95% confidence interval of the NTCP fit of the LQ model with an alpha/beta ratio of 3 Gy. The V(50) NTCP fit was better than the NTCP fit of lower threshold doses.

CONCLUSIONS: For high fraction doses, the LQ model with an alpha/beta ratio of 3 Gy was the best method for converting the physical lung dose to predict RP.

Original language	English
Pages (from-to)	1596-603
Number of pages	8
Journal	International journal of radiation oncology, biology, physics
Volume	77
Issue number	5
DOIs	https://doi.org/10.1016/j.ijrobp.2009.10.015
Publication status	Published - 1 Aug 2010

Keywords

Confidence Intervals
Dose Fractionation, Radiation
Dose-Response Relationship, Radiation
Humans
Incidence
Likelihood Functions
Linear Models
Lung Neoplasms/radiotherapy
Radiation Pneumonitis/epidemiology

Research Beacons, Institutes and Platforms

Manchester Cancer Research Centre

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.ijrobp.2009.10.015

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Borst, G. R., Ishikawa, M., Nijkamp, J., Hauptmann, M., Shirato, H., Bengua, G., Onimaru, R., de Josien Bois, A., Lebesque, J. V., & Sonke, J.-J. (2010). Radiation pneumonitis after hypofractionated radiotherapy: evaluation of the LQ(L) model and different dose parameters. International journal of radiation oncology, biology, physics, 77(5), 1596-603. https://doi.org/10.1016/j.ijrobp.2009.10.015

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title = "Radiation pneumonitis after hypofractionated radiotherapy: evaluation of the LQ(L) model and different dose parameters",

abstract = "PURPOSE: To evaluate the linear quadratic (LQ) model for hypofractionated radiotherapy within the context of predicting radiation pneumonitis (RP) and to investigate the effect if a linear (L) model in the high region (LQL model) is used.METHODS AND MATERIALS: The radiation doses used for 128 patients treated with hypofractionated radiotherapy were converted to the equivalent doses given in fractions of 2 Gy for a range of alpha/beta ratios (1 Gy to infinity) according to the LQ(L) model. For the LQL model, different cut-off values between the LQ model and the linear component were used. The Lyman model parameters were fitted to the events of RP grade 2 or higher to derive the normal tissue complication probability (NTCP). The lung dose was calculated as the mean lung dose and the percentage of lung volume (V) receiving doses higher than a threshold dose of xGy (V(x)).RESULTS: The best NTCP fit was found if the mean lung dose, or V(x), was calculated with an alpha/beta ratio of 3 Gy. The NTCP fit of other alpha/beta ratios and the LQL model were worse but within the 95% confidence interval of the NTCP fit of the LQ model with an alpha/beta ratio of 3 Gy. The V(50) NTCP fit was better than the NTCP fit of lower threshold doses.CONCLUSIONS: For high fraction doses, the LQ model with an alpha/beta ratio of 3 Gy was the best method for converting the physical lung dose to predict RP.",

keywords = "Confidence Intervals, Dose Fractionation, Radiation, Dose-Response Relationship, Radiation, Humans, Incidence, Likelihood Functions, Linear Models, Lung Neoplasms/radiotherapy, Radiation Pneumonitis/epidemiology",

author = "Borst, {Gerben R} and Masayori Ishikawa and Jasper Nijkamp and Michael Hauptmann and Hiroki Shirato and Gerard Bengua and Rikiya Onimaru and {de Josien Bois}, A and Lebesque, {Joos V} and Jan-Jakob Sonke",

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day = "1",

doi = "10.1016/j.ijrobp.2009.10.015",

language = "English",

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Borst, GR, Ishikawa, M, Nijkamp, J, Hauptmann, M, Shirato, H, Bengua, G, Onimaru, R, de Josien Bois, A, Lebesque, JV & Sonke, J-J 2010, 'Radiation pneumonitis after hypofractionated radiotherapy: evaluation of the LQ(L) model and different dose parameters', International journal of radiation oncology, biology, physics, vol. 77, no. 5, pp. 1596-603. https://doi.org/10.1016/j.ijrobp.2009.10.015

TY - JOUR

T1 - Radiation pneumonitis after hypofractionated radiotherapy

T2 - evaluation of the LQ(L) model and different dose parameters

AU - Borst, Gerben R

AU - Ishikawa, Masayori

AU - Nijkamp, Jasper

AU - Hauptmann, Michael

AU - Shirato, Hiroki

AU - Bengua, Gerard

AU - Onimaru, Rikiya

AU - de Josien Bois, A

AU - Lebesque, Joos V

AU - Sonke, Jan-Jakob

PY - 2010/8/1

Y1 - 2010/8/1

N2 - PURPOSE: To evaluate the linear quadratic (LQ) model for hypofractionated radiotherapy within the context of predicting radiation pneumonitis (RP) and to investigate the effect if a linear (L) model in the high region (LQL model) is used.METHODS AND MATERIALS: The radiation doses used for 128 patients treated with hypofractionated radiotherapy were converted to the equivalent doses given in fractions of 2 Gy for a range of alpha/beta ratios (1 Gy to infinity) according to the LQ(L) model. For the LQL model, different cut-off values between the LQ model and the linear component were used. The Lyman model parameters were fitted to the events of RP grade 2 or higher to derive the normal tissue complication probability (NTCP). The lung dose was calculated as the mean lung dose and the percentage of lung volume (V) receiving doses higher than a threshold dose of xGy (V(x)).RESULTS: The best NTCP fit was found if the mean lung dose, or V(x), was calculated with an alpha/beta ratio of 3 Gy. The NTCP fit of other alpha/beta ratios and the LQL model were worse but within the 95% confidence interval of the NTCP fit of the LQ model with an alpha/beta ratio of 3 Gy. The V(50) NTCP fit was better than the NTCP fit of lower threshold doses.CONCLUSIONS: For high fraction doses, the LQ model with an alpha/beta ratio of 3 Gy was the best method for converting the physical lung dose to predict RP.

AB - PURPOSE: To evaluate the linear quadratic (LQ) model for hypofractionated radiotherapy within the context of predicting radiation pneumonitis (RP) and to investigate the effect if a linear (L) model in the high region (LQL model) is used.METHODS AND MATERIALS: The radiation doses used for 128 patients treated with hypofractionated radiotherapy were converted to the equivalent doses given in fractions of 2 Gy for a range of alpha/beta ratios (1 Gy to infinity) according to the LQ(L) model. For the LQL model, different cut-off values between the LQ model and the linear component were used. The Lyman model parameters were fitted to the events of RP grade 2 or higher to derive the normal tissue complication probability (NTCP). The lung dose was calculated as the mean lung dose and the percentage of lung volume (V) receiving doses higher than a threshold dose of xGy (V(x)).RESULTS: The best NTCP fit was found if the mean lung dose, or V(x), was calculated with an alpha/beta ratio of 3 Gy. The NTCP fit of other alpha/beta ratios and the LQL model were worse but within the 95% confidence interval of the NTCP fit of the LQ model with an alpha/beta ratio of 3 Gy. The V(50) NTCP fit was better than the NTCP fit of lower threshold doses.CONCLUSIONS: For high fraction doses, the LQ model with an alpha/beta ratio of 3 Gy was the best method for converting the physical lung dose to predict RP.

KW - Confidence Intervals

KW - Dose Fractionation, Radiation

KW - Dose-Response Relationship, Radiation

KW - Humans

KW - Incidence

KW - Likelihood Functions

KW - Linear Models

KW - Lung Neoplasms/radiotherapy

KW - Radiation Pneumonitis/epidemiology

U2 - 10.1016/j.ijrobp.2009.10.015

DO - 10.1016/j.ijrobp.2009.10.015

M3 - Article

C2 - 20231066

SN - 0360-3016

VL - 77

SP - 1596

EP - 1603

JO - International journal of radiation oncology, biology, physics

JF - International journal of radiation oncology, biology, physics

IS - 5

ER -

Radiation pneumonitis after hypofractionated radiotherapy: evaluation of the LQ(L) model and different dose parameters

Abstract

Keywords

Research Beacons, Institutes and Platforms

UN SDGs

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