BACKGROUND AND PURPOSE: For stereotactic body radiotherapy (SBRT), typically a scheme of 60 Gy in 3-8 fractions is applied, producing local tumour control rates around 90%. The dose specification is in one point only and ignores possible underdosages at the edge of the planning target volume (PTV). We investigated the doses at the edge of the PTV and correlated this with local tumour control with the aim to shed light on the radiation dose needed to eradicate stage I NSCLC. MATERIALS AND METHODS: Published data on the freedom from local progression (FFLP) data from SBRT and accelerated high-dose conventional radiotherapy series for stage I NSCLC with a follow up of at least 30 months were included. The EQD(2,T) was calculated from the dose at the periphery of the PTV. RESULTS: Fifteen studies for SBRT (1076 patients) showed a median FFLP of 88.0±10.4% with a median EQD(2,T) of 76.9±17.4 Gy. The median FFLP was 87.6±6.0% for the accelerated schedules with an EQD(2,T) of 86.9±39.1 Gy, respectively. No significant relation was found between FFLP and the EQD(2,T) (p=0.23). CONCLUSIONS: Several fractionated and accelerated schedules with equal biological doses achieve the same tumour control rates as SBRT. Lower, but more uniform doses to the whole PTV may be sufficient to achieve similar control rates, with the possibility to deliver SBRT in adapted schedules, beneficial to centrally located tumours in the vicinity of critical structures like the oesophagus and great vessels.
BACKGROUND AND PURPOSE: For stereotactic body radiotherapy (SBRT), typically a scheme of 60 Gy in 3-8 fractions is applied, producing local tumour control rates around 90%. The dose specification is in one point only and ignores possible underdosages at the edge of the planning target volume (PTV). We investigated the doses at the edge of the PTV and correlated this with local tumour control with the aim to shed light on the radiation dose needed to eradicate stage I NSCLC. MATERIALS AND METHODS: Published data on the freedom from local progression (FFLP) data from SBRT and accelerated high-dose conventional radiotherapy series for stage I NSCLC with a follow up of at least 30 months were included. The EQD(2,T) was calculated from the dose at the periphery of the PTV. RESULTS: Fifteen studies for SBRT (1076 patients) showed a median FFLP of 88.0±10.4% with a median EQD(2,T) of 76.9±17.4 Gy. The median FFLP was 87.6±6.0% for the accelerated schedules with an EQD(2,T) of 86.9±39.1 Gy, respectively. No significant relation was found between FFLP and the EQD(2,T) (p=0.23). CONCLUSIONS: Several fractionated and accelerated schedules with equal biological doses achieve the same tumour control rates as SBRT. Lower, but more uniform doses to the whole PTV may be sufficient to achieve similar control rates, with the possibility to deliver SBRT in adapted schedules, beneficial to centrally located tumours in the vicinity of critical structures like the oesophagus and great vessels.
Authors: Zhiguo Zhou; Michael Folkert; Puneeth Iyengar; Kenneth Westover; Yuanyuan Zhang; Hak Choy; Robert Timmerman; Steve Jiang; Jing Wang Journal: Phys Med Biol Date: 2017-05-08 Impact factor: 3.609
Authors: Jaden D Evans; Daniel R Gomez; Arya Amini; Neal Rebueno; Pamela K Allen; Mary K Martel; Justin M Rineer; Kie Kian Ang; Sarah McAvoy; James D Cox; Ritsuko Komaki; James W Welsh Journal: Radiother Oncol Date: 2013-02-28 Impact factor: 6.280
Authors: Franz Zehentmayr; Karl Wurstbauer; Heinz Deutschmann; Christoph Fussl; Peter Kopp; Karin Dagn; Gerd Fastner; Peter Porsch; Michael Studnicka; Felix Sedlmayer Journal: Strahlenther Onkol Date: 2014-09-23 Impact factor: 3.621