Dose-gradient function-guided re-optimization significantly reduced mean heart dose from 6.190 Gy to 5.322 Gy (P<0.001) compared to the initial helical tomotherapy plan.
Observational (n=26)
Does DGF-guided optimization reduce cardiac radiation exposure and model-based cardiac risk in female patients with left-sided breast cancer treated with helical tomotherapy after mastectomy?
DGF-guided optimization of helical tomotherapy significantly reduces cardiac radiation exposure and estimated risk of major coronary events in patients with left-sided breast cancer undergoing postmastectomy radiotherapy.
Absolute Event Rate: 5.322% vs 6.19%
p-value: p=<0.001
Introduction Radiation-induced heart injury (RIHI) remains an important concern in left-sided postmastectomy radiotherapy (PMRT), particularly when internal mammary lymph nodes (IMLNs) are included in the target volume. Helical tomotherapy (HT) provides excellent target conformity for complex targets, but cardiac sparing remains challenging. This study evaluated whether dose-gradient function (DGF)-guided optimization could further reduce cardiac exposure in left-sided breast cancer patients treated with HT after modified radical mastectomy. Methods Twenty-six female patients with left-sided breast cancer who underwent PMRT were retrospectively included. Initial HT plan was generated and evaluated using DGF, which quantifies dose falloff outside the target volume. The patient with the minimum DGF curve area ( S min ) was used as the internal benchmarking and was not re-optimized. The remaining 25 patients underwent DGF-guided re-optimization. Mean heart dose (MHD), cardiac dose-volume indices, left anterior descending coronary artery (LAD) dose, and the model-based relative risk increase (RRI) of major coronary events, were compared between the original and optimized plans. Results DGF-guided re-optimization significantly reduced cardiac dose parameters while maintaining target coverage and overall plan quality. MHD decreased from 6.190 ± 0.384 Gy to 5.322 ± 0.332 Gy (P V 5 decreased from 43.084 ± 4.807% to 29.260 ± 4.453% (P V 10 , V 20 , and V 30 (all P V 5 decreased from 86.150 ± 8.152% to 81.240 ± 9.100% (P < 0.001), and LAD mean dose decreased from 18.786 ± 2.661 Gy to 18.230 ± 2.691 Gy (P < 0.001). Greater cardiac dose reduction was observed in the IMLNs irradiation group. The estimated relative risk increase decreased from 45.803 ± 2.839% to 39.383 ± 2.459% (P < 0.001). Conclusion DGF-guided optimization may improve HT plan quality for left-sided PMRT and achieve additional reductions in cardiac dose and model-based cardiac risk estimates, particularly in cases requiring IMLNs irradiation.
Yang et al. (Mon,) ont mené une étude d'observation sur le cancer du sein gauche (n=26). La re-optimisation guidée par la fonction de gradient de dose (DGF) par rapport au plan de tomothérapie hélicoïdale initial a été évaluée sur la dose cardiaque moyenne (MHD) (p=<0.001). La re-optimisation guidée par la fonction de gradient de dose a significativement réduit la dose cardiaque moyenne de 6.190 Gy à 5.322 Gy (P<0.001) par rapport au plan de tomothérapie hélicoïdale initial.