Evaluation of indirect damage and damage saturation effects in dose–response curves of hypofractionated radiotherapy of early-stage NSCLC and brain metastases

Gago-Arias, Araceli; Neira, Sara; Pombar, M.; Gómez-Caamaño, Antonio; Pardo-Montero, Juan

doi:10.1016/j.radonc.2021.05.012

Cited by 7 publications

(13 citation statements)

References 55 publications

(78 reference statements)

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“…The formulas for these models are as follows: where n is the number of fractions, d is the dose per fraction, α/γ is 648 Gy 2 , δ is 0.14, and G( χ ) = (2/ χ2 )( χ -1+ e -χ ). 2,[14][15][16][17] In the univariate analysis, we used the Pearson correlation coefficient (r) to evaluate the correlation between the GTV parameters themselves, and we used the Spearman's correlation coefficient to evaluate the correlation between the clinical (treatment) parameters and the GTV parameters. When either coefficient for the candidate prognostic factors was >0.40 in the univariate analysis, we selected only one variable for the multivariate analysis.…”

Section: Discussionmentioning

confidence: 99%

“…It is highly debated which of the following models should be chosen when performing SRT for brain metastases: LQ: α/β = 10; LQ: α/β = 20; LQC: α/β = 12; or LQL: α/β = 10. 2 , 14 , 15 , 16 , 17 , 18 LQ: α/β = 10 is well suited for stereotactic body radiotherapy for early‐stage lung cancer. 14 However, it is not appropriate for late‐stage lung cancer with brain metastases, which are best treated using LQL: α/β = 10.…”

Section: Discussionmentioning

confidence: 99%

“…Doses were stratified according to the biological effective dose (BED). It is a matter of debate which formula should be used to calculate the BED for SRT for brain metastases 2 , 14 , 15 , 16 , 17 , 18 ; hence, we used four models: two linear‐quadratic (LQ) models: α/β = 10 and α/β = 20; the linear‐quadratic cubic (LQC) model: α/β = 12; and the linear‐quadratic linear (LQL) model: α/β = 10. The formulas for these models are as follows:…”

Section: Methodsmentioning

confidence: 99%

“…where n is the number of fractions, d is the dose per fraction, α/γ is 648 Gy 2 , δ is 0.14, and G( χ ) = (2/ χ2 )( χ ‐1+ e ‐χ ). 2 , 14 , 15 , 16 , 17 …”

Section: Methodsmentioning

confidence: 99%

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Volumetric reduction of brain metastases after stereotactic radiotherapy: Prognostic factors and effect on local control

Kanayama

Ikawa

2022

Cancer Medicine

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Background and Purpose Few reports include volumetric measurements as endpoints after stereotactic radiotherapy (SRT) despite the importance of such measurements. This study aimed to (1) investigate the impact of the volumetric response (specifically, an over 65% and over 90% volume reduction in brain metastases) at 6 months post‐SRT on local control and (2) identify the predictive factors for a volumetric response of over 65% and over 90%. Materials and Methods This study included 250 unresected brain metastases (>0.3 cc) treated with SRT. Doses were stratified according to the biological effective dose (BED). The BED was calculated using four models: linear‐quadratic (LQ): α/β = 10; LQ: α/β = 20; LQ cubic: α/β = 12; and LQ linear: α/β = 10. The median prescription dose was 30 Gy/3 fractions (BED20, 45). The median follow‐up time after SRT was 18.6 months (range, 6.4–81.8 months). Results In the multivariate analysis, over 65% volume reduction and over 90% volume reduction were prognostic factors for local control (hazard ratio: 2.370, p = 0.011 and hazard ratio: 3.161, p = 0.014, respectively). A dose of 80% of the gross tumor volume (GTV) D80 > BED20 58 was a predictive factor for over 65% and over 90% volume reductions (odds ratio: 1.975, p = 0.023; odds ratio: 3.204, p < 0.001, respectively). Conclusion Robust volume reduction of brain metastases at 6 months post‐SRT can predict local control. GTV D80 in the LQ model: α/β = 20 may be warranted for good volume reduction.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

“…where n is the number of fractions, d is the dose per fraction, α/γ is 648 Gy 2 , δ is 0.14, and G( χ ) = (2/ χ2 )( χ ‐1+ e ‐χ ). 2 , 14 , 15 , 16 , 17 …”

Section: Methodsmentioning

confidence: 99%

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Volumetric reduction of brain metastases after stereotactic radiotherapy: Prognostic factors and effect on local control

Kanayama

Ikawa

2022

Cancer Medicine

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“…Several effects contribute to this: re-oxygenation (which leads to radiosensitization) depending on the dose per fraction [36], saturation [37], or vascular damage [15]. As those effects apply mostly to the LQ model's, yet it is still not known how much, we have checked whether a simple ad hoc modification of the quadratic term can change the goodness of the fit [38]:…”

Section: Direct Cell Death and Kineticsmentioning

confidence: 99%

A biomathematical model of tumor response to radioimmunotherapy with $α$PDL1 and $α$CTLA4

González-Crespo¹,

Gómez-Caamaño²,

López-Pouso³

et al. 2021

Preprint

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There is evidence of synergy between radiotherapy and immunotherapy. Radiotherapy can increase liberation of tumor antigens, leading to activation of antitumor T-cells. This effect can be boosted with immunotherapy. Radioimmunotherapy is therefore a very promising therapeutic combination against cancer, with potential to increase tumor control rates. Biomathematical response models of radioimmunotherapy may help clinicians to design optimal treatment schedules. In this work we present a biomathematical model of tumor response to radioimmunotherapy. The model uses the linear-quadratic response of tumor cells to radiation, and builds on previous developments to include the radiation-induced immune effect. We have focused this study on the combined effect of radiotherapy and αPDL1/αCTL4 therapies. The model fits recent preclinical data of volume dynamics and control obtained with different dose fractionations and αPDL1/αCTL4. A biomathematical study of optimal combination strategies suggests that a good understanding of the biological delays associated to radoimmunotherapy, the biokinetics of the immunotherapy drug, and the interplay among them, may be of paramount importance to design optimal radioimmunotherapy schedules. Biomathematical models like the one we present can help to interpret experimental data on the synergy between radiotherapy and immunotherapy, and to assist in the design of more effective treatments, could potentially boost the implementation of radioimmunotherapy.

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Radiobiological analysis of the response of prostate cancer to different fractionations

Pardo-Montero

González-Crespo

Gómez-Caamaño

et al. 2023

Preprint

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PurposeTo investigate the response of prostate cancer to different radiotherapy schedules, including hypofractionation, and to evaluate potential departures from the linear-quadratic (LQ) response. To obtain best-fitting parameters for low (LR), intermediate (IR), and high risk (HR) prostate cancer.Methods and MaterialsWe have constructed a dataset of dose-response containing 87 entries (35 LR, 32 IR, 20 HR), with doses per fraction ranging from 1.8 to 10 Gy. These data were fitted to tumor control probability models based on the LQ model, linear-quadratic-linear (LQL), and a modification of the LQ (LQmod) accounting for increasing radiosensitivity at large doses. Fits were performed with the maximum likelihood expectation methodology, and the Akaike-Information-Criterion (AIC) was used to compare models.ResultsThe AIC shows that the LQ model is superior to the LQL and LQmod for all risks, except for IR where the LQL outperforms the other models. The analysis shows a low α/β for all risks: 2.01 Gy for LR (95% confidence interval 1.74-2.26), 3.44 Gy for IR (2.99-4.02), and 2.78 Gy for HR (1.43-4.18). Best-fits do not show proliferation for LR, and only moderate proliferation for IR/HR.ConclusionsIn general, the LQ model describes the response of prostate cancer better than the alternative models. Only for IR the LQL outperforms the LQ. This study confirms a lowα/βfor all risks, with doses per fraction ranging from <2 Gy up to 10 Gy.

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Evaluation of indirect damage and damage saturation effects in dose–response curves of hypofractionated radiotherapy of early-stage NSCLC and brain metastases

Cited by 7 publications

References 55 publications

Volumetric reduction of brain metastases after stereotactic radiotherapy: Prognostic factors and effect on local control

Volumetric reduction of brain metastases after stereotactic radiotherapy: Prognostic factors and effect on local control

A biomathematical model of tumor response to radioimmunotherapy with $α$PDL1 and $α$CTLA4

Radiobiological analysis of the response of prostate cancer to different fractionations

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