Modeling radiation pneumonitis of pulmonary stereotactic body radiotherapy: The impact of a local dose-effect relationship for lung perfusion loss.

Abstract

PURPOSE

To investigate if a local dose-effect (LDE) relationship for perfusion loss improves the NTCP model fit for SBRT induced radiation pneumonitis (RP) compared to conventional LDEs.

RESULTS

The median time to grade ≥2 RP was 4.2 months and plateaued after 17 months at 5.4%. A strong dose-effect relationship for RP incidence was observed. The EUD_Perfusion based NTCP model had the lowest AIC. The Aw were 0.53, 0.19, 0.11, 0.11, 0.05 for the EUD_Perfusion, V_x, MLD, EUD_log-free and EUD_power LDEs respectively.

METHODS AND MATERIALS

Multi-institutional data of 1015 patients treated with SBRT were analyzed. Dose distributions were converted to NTD with α/β = 3 Gy. The Lyman-Kutcher-Burman NTCP model was fitted to the incidence grade ≥2 RP by maximum likelihood estimation with mean lung dose (MLD), equivalent uniform doses (EUD) using three LDE functions (power-law (EUD_power), logistic with 2 free parameters (EUD_log-free) and logistic with fixed parameters describing local perfusion loss (EUD_Perfusion)) and volume above a threshold dose (V_x). Models were compared with the Akaike weights (Aw) derived from the Akaike information criteria (AIC).

CONCLUSION

A LDE for perfusion loss provided modest improvement in NTCP model fit for SBRT induced radiation pneumonitis.