Your search keyword '"Relative biological effectiveness"' showing total 395 results

1. Relative biological effectiveness of clinically relevant photon energies for the survival of human colorectal, cervical, and prostate cancer cell lines.

Author

Li, Joanna, Chabaytah, Naim, Babik, Joud, Behmand, Behnaz, Bekerat, Hamed, Connell, Tanner, Evans, Michael, Ruo, Russell, Vuong, Te, and Abbasinejad Enger, Shirin

Subjects

*EXPERIMENTAL literature, *HELA cells, *CELL survival, *PHYSICISTS, *PHOTONS

Abstract

Objective. Relative biological effectiveness (RBE) differs between radiation qualities. However, an RBE of 1.0 has been established for photons regardless of the wide range of photon energies used clinically, the lack of reproducibility in radiobiological studies, and outdated reference energies used in the experimental literature. Moreover, due to intrinsic radiosensitivity, different cancer types have different responses to radiation. This study aimed to characterize the RBE of clinically relevant high and low photon energies in vitro for three human cancer cell lines: HCT116 (colon), HeLa (cervix), and PC3 (prostate). Approach. Experiments were conducted following dosimetry protocols provided by the American Association of Physicists in Medicine. Cells were irradiated with 6 MV x-rays, an 192Ir brachytherapy source, 225 kVp and 50 kVp x-rays. Cell survival post-irradiation was assessed using the clonogenic assay. Survival fractions were fitted using the linear quadratic model, and survival curves were generated for RBE calculations. Main results. Cell killing was more efficient with decreasing photon energy. Using 225 kVp x-rays as the reference, the HCT116 RBESF0.1 for 6 MV x-rays, 192Ir, and 50 kVp x-rays were 0.89 ± 0.03, 0.95 ± 0.03, and 1.24 ± 0.04; the HeLa RBESF0.1 were 0.95 ± 0.04, 0.97 ± 0.05, and 1.09 ± 0.03, and the PC3 RBESF0.1 were 0.84 ± 0.01, 0.84 ± 0.01, and 1.13 ± 0.02, respectively. HeLa and PC3 cells had varying radiosensitivity when irradiated with 225 and 50 kVp x-rays. Significance. This difference supports the notion that RBE may not be 1.0 for all photons through experimental investigations that employed precise dosimetry. It highlights that different cancer types may not have identical responses to the same irradiation quality. Additionally, the RBE of clinically relevant photons was updated to the reference energy of 225 kVp x-rays. [ABSTRACT FROM AUTHOR]

Published

2024

2. Assessing the biological effects of boron neutron capture therapy through cellular DNA damage repair model.

Author

Yu, Chenxi, Geng, Changran, and Tang, Xiaobin

Subjects

*BORON-neutron capture therapy, *LINEAR energy transfer, *PHYSIOLOGICAL effects of radiation, *DNA repair, *DNA damage, *NEUTRON capture, *BORON isotopes

Abstract

Background Purpose Methods Results Conclusions Boron neutron capture therapy (BNCT) is a targeted radiotherapy that relies on the 10B (n, α) 7Li reaction, which produces secondary particles with high linear energy transfer (LET), leading to a high relative biological effectiveness (RBE) in tumors. The biological effectiveness of BNCT is influenced by factors such as boron distribution and concentration, necessitating improved methods for assessing its radiobiological effects and clarifying the sensitivity of the differences in different factors to the biological effects.This paper introduces a method to evaluate the biological effects of BNCT using the cellular repair model. This method aims to overcome some of the limitations of current evaluation approaches. The primary goal is to provide guidance for clinical treatments and the development of boron drugs, as well as to investigate the impact of the synergistic effects of mixed radiation fields in BNCT on treatment outcomes.The approach involves three key steps: first, extending the radial energy deposition distribution of BNCT secondary particles using Geant4‐DNA. This allows for the calculation of initial DNA double‐strand breaks (DSBs) distributions for a given absorbed dose. Next, the obtained initial DSB distributions are used for DNA damage repair simulations to generate cell survival curves, then thereby quantifying RBE and compound biological effectiveness (CBE). The study also explores the synergistic effects of the mixed radiation fields in BNCT on assessing biological effects were also explored in depth.The results showed that the RBE of boronophenylalanine (BPA) and sodium borocaptate (BSH) drugs at cell survival fraction 0.01 was 2.50 and 2.15, respectively. The CBE of the boron dose component was 3.60 and 0.73, respectively, and the RBE of the proton component was 3.21, demonstrating that BPA has a significantly higher biological impact than BSH due to superior cellular permeability. The proton dose significance in BNCT treatment is also underscored, necessitating consideration in both experimental and clinical contexts. The study demonstrates that synergistic effects between disparate radiation fields lead to increased misrepairs and enhanced biological impact. Additionally, the biological effect diminishes with rising boron concentration, emphasizing the need to account for intercellular DNA damage heterogeneity.This methodology offers valuable insights for the development of new boron compounds and precise assessment of bio‐weighted doses in clinical settings and can be adapted to other therapeutic modalities. [ABSTRACT FROM AUTHOR]

Published

2024

3. Ionization detail parameters and cluster dose: a mathematical model for selection of nanodosimetric quantities for use in treatment planning in charged particle radiotherapy

Author

Faddegon, Bruce, Blakely, Eleanor A, Burigo, Lucas, Censor, Yair, Dokic, Ivana, Kondo, Naoki Domínguez, Ortiz, Ramon, Méndez, José Ramos, Rucinski, Antoni, Schubert, Keith, Wahl, Niklas, and Schulte, Reinhard

Subjects

Medical and Biological Physics, Physical Sciences, Cancer, Radiation Oncology, 5.5 Radiotherapy and other non-invasive therapies, Relative Biological Effectiveness, Cell Line, Protons, Models, Biological, nanodosimetry, track structure simulation, particle therapy, treatment planning, RBE, Other Physical Sciences, Biomedical Engineering, Clinical Sciences, Nuclear Medicine & Medical Imaging, Medical and biological physics

Abstract

Objective. To propose a mathematical model for applying ionization detail (ID), the detailed spatial distribution of ionization along a particle track, to proton and ion beam radiotherapy treatment planning (RTP).Approach. Our model provides for selection of preferred ID parameters (Ip) for RTP, that associate closest to biological effects. Cluster dose is proposed to bridge the large gap between nanoscopicIpand macroscopic RTP. Selection ofIpis demonstrated using published cell survival measurements for protons through argon, comparing results for nineteenIp:Nk,k= 2, 3, …, 10, the number of ionizations in clusters ofkor more per particle, andFk,k= 1, 2, …, 10, the number of clusters ofkor more per particle. We then describe application of the model to ID-based RTP and propose a path to clinical translation.Main results. The preferredIpwereN4andF5for aerobic cells,N5andF7for hypoxic cells. Significant differences were found in cell survival for beams having the same LET or the preferredNk. Conversely, there was no significant difference forF5for aerobic cells andF7for hypoxic cells, regardless of ion beam atomic number or energy. Further, cells irradiated with the same cluster dose for theseIphad the same cell survival. Based on these preliminary results and other compelling results in nanodosimetry, it is reasonable to assert thatIpexist that are more closely associated with biological effects than current LET-based approaches and microdosimetric RBE-based models used in particle RTP. However, more biological variables such as cell line and cycle phase, as well as ion beam pulse structure and rate still need investigation.Significance. Our model provides a practical means to select preferredIpfrom radiobiological data, and to convertIpto the macroscopic cluster dose for particle RTP.

Published

2023

4. Technical note: Determination of proton linear energy transfer from the integral depth dose.

Author

Yao, Weiguang, Farr, Jonathan B., Mossahebi, Sina, Yi, Byongyong, and Chen, Shifeng

Subjects

*LINEAR energy transfer, *PROTONS, *IONIZATION chambers, *INTEGRALS

Abstract

Background: Proton linear energy transfer (LET) is associated with the relative biological effectiveness of radiation on tissues. Monte Carlo (MC) simulations have been known to be the preferred method to calculate LET. Detectors have also been built to measure LET, but they need to be calibrated with MC simulations. Purpose: To propose and test a MC‐free method for determining LET from the measured integral depth dose (LFI) of the protons of interest. Method and materials: LFI consists of three steps: (1) IDD measurements, (2) extraction of energy spectrum (ES) from the IDD, and (3) LET determination from the extracted ES and the stopping power of each energy. To validate the accuracy of the extraction of ES, we use Gaussian ES to synthesize IDD, extract ES from the synthesized IDD, and then compare the original (ground truth) and extracted ES. LETs calculated from the original and extracted ES are also compared. To obtain the LET of protons of interest, we measure IDDs by a large‐area plane‐parallel ionization chamber in water. Finally, TOPAS MC is employed to simulate IDDs, ES, and LETs. From the simulated IDD, the extracted ES and LET are compared with the simulations from TOPAS MC. Results: From the synthesized IDDs, the LETs agreed excellently when the peak energies ≥10 and 1.25 MeV with depth resolutions 0.1 and 0.01 mm, respectively. For energy <1.25 MeV, even higher depth resolution than 0.01 mm is required. From the MC simulated IDDs, our track‐averaged LET excellently agreed with MC simulation, but not the LETd. Our LETd was smaller than MC simulated LETd in the shallow region but larger in the distal Bragg peak region. Conclusion: LET can be accurately determined from the IDD. This method can be used in the clinic to commission or validate LETs from other measurement methods or a treatment planning system. [ABSTRACT FROM AUTHOR]

Published

2024

5. DNA‐damage RBE assessment for combined boron and gadolinium neutron capture therapy.

Author

Shamsabadi, Reza and Baghani, Hamid Reza

Subjects

BORON-neutron capture therapy, NEUTRON capture, BRAIN tumors

Abstract

Purpose: Neutron capture therapy (NCT) by 10B and 157Gd agents is a unique irradiation‐based method which can be used to treat brain tumors. Current study aims to quantitatively evaluate the relative biological effectiveness (RBE) and dose distributions during the combined BNCT and GdNCT modalities through a hybrid Monte Carlo (MC) simulation approach. Methods: Snyder head phantom as well as a cubic hypothetical tumor was at first modeled by Geant4 MC Code. Then, the energy spectra and dose distribution relevant to the released secondary particles during the combined Gd/BNCT were scored for different concentrations of 157Gd and 10B inside tumor volume. Finally, the scored energy spectra were imported to the MCDS code to estimate both RBESSB and RBEDSB values for different 157Gd concentrations. Results: The results showed that combined Gd/BNCT increases the fluence‐averaged RBESSB values by about 1.7 times when 157Gd concentration increments from 0 to 2000 µg/g for both considered cell oxygen levels (pO2 = 10% and 100%). Besides, a reduction of about 26% was found for fluence‐averaged RBEDSB values with an increment of 157Gd concentration in tumor volume. Conclusion: From the results, it can be concluded that combined Gd/BNCT technique can improve tumor coverage with higher dose levels but in the expense of RBEDSB reduction which can affect the clinical efficacy of the NCT technique. [ABSTRACT FROM AUTHOR]

Published

2024

6. The sensitivity of radiobiological models in carbon ion radiotherapy (CIRT) and its consequences on the clinical treatment plan: Differences between LEM and MKM models.

Author

Góra, Joanna, Grosshagauer, Sarah, Fossati, Piero, Mumot, Marta, Stock, Markus, Schafasand, Mansure, and Carlino, Antonio

Subjects

LINEAR energy transfer, RADIOTHERAPY, IONS, CARBON

Abstract

Purpose: Carbon ion radiotherapy (CIRT) relies on relative biological effectiveness (RBE)‐weighted dose calculations. Japanese clinics predominantly use the microdosimetric kinetic model (MKM), while European centers utilize the local effect model (LEM). Despite both models estimating RBE‐distributions in tissue, their physical and mathematical assumptions differ, leading to significant disparities in RBE‐weighted doses. Several European clinics adopted Japanese treatment schedules, necessitating adjustments in dose prescriptions and organ at risk (OAR) constraints. In the context of these two clinically used standards for RBE‐weighted dose estimation, the objective of this study was to highlight specific scenarios for which the translations between models diverge, as shortcomings between them can influence clinical decisions. Methods: Our aim was to discuss planning strategies minimizing those discrepancies, ultimately striving for more accurate and robust treatments. Evaluations were conducted in a virtual water phantom and patient CT‐geometry, optimizing LEM RBE‐weighted dose first and recomputing MKM thereafter. Dose‐averaged linear energy transfer (LETd) distributions were also assessed. Results: Results demonstrate how various parameters influence LEM/MKM translation. Similar LEM‐dose distributions lead to markedly different MKM‐dose distributions and variations in LETd. Generally, a homogeneous LEM RBE‐weighted dose aligns with lower MKM values in most of the target volume. Nevertheless, paradoxical MKM hotspots may emerge (at the end of the range), potentially influencing clinical outcomes. Therefore, translation between models requires great caution. Conclusions: Understanding the relationship between these two clinical standards enables combining European and Japanese based experiences. The implementation of optimal planning strategies ensures the safety and acceptability of the clinical plan for both models and therefore enhances plan robustness from the RBE‐weighted dose and LETd distribution point of view. This study emphasizes the importance of optimal planning strategies and the need for comprehensive CIRT plan quality assessment tools. In situations where simultaneous LEM and MKM computation capabilities are lacking, it can provide guidance in plan design, ultimately contributing to enhanced CIRT outcomes. [ABSTRACT FROM AUTHOR]

Published

2024

7. Impact of Relative Biologic Effectiveness for Proton Therapy for Head and Neck and Skull-Base Tumors: A Technical and Clinical Review.

Author

Holtzman, Adam L., Mohammadi, Homan, Furutani, Keith M., Koffler, Daniel M., McGee, Lisa A., Lester, Scott C., Gamez, Mauricio E., Routman, David M., Beltran, Chris J., and Liang, Xiaoying

Subjects

*HEAD & neck cancer treatment, *PROTON therapy, *RISK assessment, *MEDICAL technology, *MEDICAL care, *TREATMENT effectiveness, *METASTASIS, *SKULL, *EVALUATION

Abstract

Simple Summary: Proton therapy is a crucial tool for head and neck and skull-base cancers, offering benefits over photon therapy by lowering the risk of adverse effects. However, its full potential could be further explored by better characterizing the uncertainties related to its relative biological effectiveness. Addressing these uncertainties is crucial for maximizing the potential of proton therapy. We explore the significance of proton therapy's biological impact in these cancers, review relative biological effectiveness uncertainties and modeling, and examine clinical outcomes and evidence linking specific biological factors to patient adverse effects. Additionally, we review the current clinical practices and provide insights into innovative developments and their future clinical implementation. Proton therapy has emerged as a crucial tool in the treatment of head and neck and skull-base cancers, offering advantages over photon therapy in terms of decreasing integral dose and reducing acute and late toxicities, such as dysgeusia, feeding tube dependence, xerostomia, secondary malignancies, and neurocognitive dysfunction. Despite its benefits in dose distribution and biological effectiveness, the application of proton therapy is challenged by uncertainties in its relative biological effectiveness (RBE). Overcoming the challenges related to RBE is key to fully realizing proton therapy's potential, which extends beyond its physical dosimetric properties when compared with photon-based therapies. In this paper, we discuss the clinical significance of RBE within treatment volumes and adjacent serial organs at risk in the management of head and neck and skull-base tumors. We review proton RBE uncertainties and its modeling and explore clinical outcomes. Additionally, we highlight technological advancements and innovations in plan optimization and treatment delivery, including linear energy transfer/RBE optimizations and the development of spot-scanning proton arc therapy. These advancements show promise in harnessing the full capabilities of proton therapy from an academic standpoint, further technological innovations and clinical outcome studies, however, are needed for their integration into routine clinical practice. [ABSTRACT FROM AUTHOR]

Published

2024

8. Variations in linear energy transfer distributions within a European proton therapy planning comparison of paediatric posterior fossa tumours

Author

Peter Lægdsmand, Witold Matysiak, Ludvig P. Muren, Yasmin Lassen-Ramshad, John H. Maduro, Anne Vestergaard, Roberto Righetto, Erik Pettersson, Ingrid Kristensen, Pauline Dutheil, Charlotte Demoor-Goldschmidt, Frances Charlwood, Gillian Whitfield, Marta M. Feijoo, Anthony Vela, Fernand Missohou, Sabina Vennarini, Alfredo Mirandola, Ester Orlandi, Barbara Rombi, Anneleen Goedgebeur, Karen Van Beek, Agata Bannink-Gawryszuk, Fernando C. Campoo, Jacob Engellau, and Laura Toussaint

Subjects

Proton therapy, Linear Energy Transfer, Relative Biological Effectiveness, Paediatric, Posterior fossa tumours, Brainstem, Medical physics. Medical radiology. Nuclear medicine, R895-920, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Background and Purpose: Radiotherapy for paediatric posterior fossa tumours may cause complications in the brainstem and upper spinal cord due to high doses. With proton therapy (PT) this risk may increase due to higher relative biological effectiveness (RBE) from elevated linear energy transfer (LET). This study assesses variations in LET in the brainstem and spinal cord in proton treatment plans from European centres. Materials and Methods: Ten European PT centres using spot-scanning PT planned two paediatric posterior fossa cases: One overlapping partly with the brainstem and upper spinal cord, prescribed 54 Gy(RBE), and the second wrapping around these organs, prescribed 59.4 Gy(RBE). Dose-averaged LET distributions were assessed in volumes of the brainstem and spinal cord irradiated to over 50 Gy(RBE = 1.1). The maximum hinge angle effect on near-maximum RBE-weighted doses using the Unkelbach RBE model was also investigated. Results: In the first case, the mean LET in brainstem volumes receiving more than 50 Gy(RBE = 1.1) ranged from 2.8 keV/µm to 3.6 keV/µm across centres (median: 3.3 keV/µm). In the second case, treatment plans showed a narrower range of mean LET in the brainstem, from 2.5 keV/µm to 2.8 keV/µm (median: 2.7 keV/µm). There was no statistically significant impact of the maximum hinge angle. Conclusions: LET distributions vary across centres due to different techniques but are also influenced significantly by factors like shape and position of the target volume.

Published

2024

9. On the Use of 203Pb Imaging to Inform 212Pb Dosimetry for 203/212Pb Image-Guided Alpha-Particle Therapy for Cancer

Author

Graves, Stephen, Li, Mengshi, Lee, Dongyoul, Schultz, Michael K., and Prasad, Vikas, editor

Published

2024

10. Evaluation of specific RBE in different cells of hippocampus under high-dose proton irradiation in rats

Author

Shengying Zhou, Xingchen Ding, Yiyuan Zhang, Yuanyuan Liu, Xiaowen Wang, Yujiao Guo, Jianguang Zhang, Xiao Liu, Guanzhong Gong, Ya Su, Lizhen Wang, Miaoqing Zhao, and Man Hu

Subjects

Relative biological effectiveness, Proton beam therapy, Hippocampus, Neuronal damage, Radiation-induced brain injury, Medicine, Science

Abstract

Abstract The study aimed to determine the specific relative biological effectiveness (RBE) of various cells in the hippocampus following proton irradiation. Sixty Sprague–Dawley rats were randomly allocated to 5 groups receiving 20 or 30 Gy of proton or photon irradiation. Pathomorphological neuronal damage in the hippocampus was assessed using Hematoxylin–eosin (HE) staining. The expression level of NeuN, Nestin, Caspase-3, Olig2, CD68 and CD45 were determined by immunohistochemistry (IHC). The RBE range established by comparing the effects of proton and photon irradiation at equivalent biological outcomes. Proton20Gy induced more severe damage to neurons than photon20Gy, but showed no difference compared to photon30Gy. The RBE of neuron was determined to be 1.65. Similarly, both proton20Gy and proton30Gy resulted in more inhibition of oligodendrocytes and activation of microglia in the hippocampal regions than photon20Gy and photon30Gy. However, the expression of Olig2 was higher and CD68 was lower in the proton20Gy group than in the photon30Gy group. The RBE of oligodendrocyte and microglia was estimated to be between 1.1 to 1.65. For neural stem cells (NSCs) and immune cells, there were no significant difference in the expression of Nestin and CD45 between proton and photon irradiation (both 20 and 30 Gy). Therefore, the RBE for NSCs and immune cell was determined to be 1.1. These findings highlight the varying RBE values of different cells in the hippocampus in vivo. Moreover, the actual RBE of the hippocampus may be higher than 1.1, suggesting that using as RBE value of 1.1 in clinical practice may underestimate the toxicities induced by proton radiation.

Published

2024

11. Estimation of the relative biological effectiveness for double strand break induction of clinical kilovoltage beams using Monte Carlo simulations.

Author

McElligott, Oran, Nikandrovs, Mihails, McCavana, Patrick, McClean, Brendan, and León Vintró, Luis

Subjects

*PHOTON beams, *WATER depth

Abstract

Background: The Relative Biological Effectiveness (RBE) of kilovoltage photon beams has been previously investigated in vitro and in silico using analytical methods. The estimated values range from 1.03 to 1.82 depending on the methodology and beam energies examined. Purpose: The focus of this work was to independently estimate RBE values for a range of clinically used kilovoltage beams (70–200 kVp) while investigating the suitability of using TOPAS‐nBio for this task. Methods: Previously validated spectra of clinical beams were used to generate secondary electron spectra at several depths in a water tank phantom via TOPAS Monte Carlo (MC) simulations. Cell geometry was irradiated with the secondary electrons in TOPAS‐nBio MC simulations. The deposited dose and the calculated number of DNA strand breaks were used to estimate RBE values. Results: Monoenergetic secondary electron simulations revealed the highest direct and indirect double strand break yield at approximately 20 keV. The average RBE value for the kilovoltage beams was calculated to be 1.14. Conclusions: TOPAS‐nBio was successfully used to estimate the RBE values for a range of clinical radiotherapy beams. The calculated value was in agreement with previous estimates, providing confidence in its clinical use in the future. [ABSTRACT FROM AUTHOR]

Published

2024

12. Impact of gadolinium concentration and cell oxygen levels on radiobiological characteristics of gadolinium neutron capture therapy technique in brain tumor treatment.

Author

Shamsabadi, Reza and Baghani, Hamid Reza

Abstract

Neutron capture therapy (NCT) with various concentrations of gadolinium (157Gd) is one of the treatment modalities for glioblastoma (GBM) tumors. Current study aims to evaluate how variations of 157Gd concentration and cell oxygen levels can affect the relative biological effectiveness (RBE) of gadolinium neutron capture therapy (GdNCT) technique through a hybrid Monte Carlo (MC) simulation approach. At first, Snyder phantom including a spherical tumor was simulated by Geant4 MC code and relevant energy electron spectra to different 157Gd concentrations including 100, 250, 500, and 1000 ppm were calculated following the neutron irradiation of simulated phantom. Scored energy electron spectra were then imported to Monte Carlo damage simulation (MCDS) code to estimate RBE values (both RBESSB and RBEDSB) at different gadolinium concentrations and oxygen levels from 10 to 100%. The results indicate that variations of 157Gd can affect the energy spectrum of released secondary electrons including Auger electrons. Variation of gadolinium concentration from 100 to 1000 ppm in tumor region can change RBESSB and RBEDSB values by about 0.1% and 0.5%, respectively. Besides, maximum variations of 4.3% and 2% were calculated for RBEDSB and RBESSB when cell oxygen level changed from 10 to 100%. From the results, variations of considered gadolinium and oxygen concentrations during GdNCT can influence RBE values. Nevertheless, due to the not remarkable changes in the intensity of Auger electrons, a slight difference in RBE values would be expected at various 157Gd concentrations, although considerable RBE changes were calculated relevant to the oxygen alternations inside tumor tissue. [ABSTRACT FROM AUTHOR]

Published

2024

13. High-LET charged particles: radiobiology and application for new approaches in radiotherapy.

Author

Helm, Alexander and Fournier, Claudia

Abstract

The number of patients treated with charged-particle radiotherapy as well as the number of treatment centers is increasing worldwide, particularly regarding protons. However, high-linear energy transfer (LET) particles, mainly carbon ions, are of special interest for application in radiotherapy, as their special physical features result in high precision and hence lower toxicity, and at the same time in increased efficiency in cell inactivation in the target region, i.e., the tumor. The radiobiology of high-LET particles differs with respect to DNA damage repair, cytogenetic damage, and cell death type, and their increased LET can tackle cells' resistance to hypoxia. Recent developments and perspectives, e.g., the return of high-LET particle therapy to the US with a center planned at Mayo clinics, the application of carbon ion radiotherapy using cost-reducing cyclotrons and the application of helium is foreseen to increase the interest in this type of radiotherapy. However, further preclinical research is needed to better understand the differential radiobiological mechanisms as opposed to photon radiotherapy, which will help to guide future clinical studies for optimal exploitation of high-LET particle therapy, in particular related to new concepts and innovative approaches. Herein, we summarize the basics and recent progress in high-LET particle radiobiology with a focus on carbon ions and discuss the implications of current knowledge for charged-particle radiotherapy. We emphasize the potential of high-LET particles with respect to immunogenicity and especially their combination with immunotherapy. [ABSTRACT FROM AUTHOR]

Published

2023

14. Reformulated McNamara RBE‐weighted beam orientation optimization for intensity modulated proton therapy

Author

Ramesh, Pavitra, Lyu, Qihui, Gu, Wenbo, Ruan, Dan, and Sheng, Ke

Subjects

Medical and Biological Physics, Physical Sciences, Cancer, Clinical Research, Humans, Organs at Risk, Proton Therapy, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Intensity-Modulated, Relative Biological Effectiveness, proton therapy-dose optimization, RBE, RBio-particle therapy-protons, Other Physical Sciences, Biomedical Engineering, Oncology and Carcinogenesis, Nuclear Medicine & Medical Imaging, Biomedical engineering, Medical and biological physics

Abstract

PurposeEmpirical relative biological effectiveness (RBE) models have been used to estimate the biological dose in proton therapy but do not adequately capture the factors influencing RBE values for treatment planning. We reformulate the McNamara RBE model such that it can be added as a linear biological dose fidelity term within our previously developed sensitivity-regularized and heterogeneity-weighted beam orientation optimization (SHBOO) framework.MethodsBased on our SHBOO framework, we formulated the biological optimization problem to minimize total McNamara RBE dose to OARs. We solve this problem using two optimization algorithms: FISTA (McNam-FISTA) and Chambolle-Pock (McNam-CP). We compare their performances with a physical dose optimizer assuming RBE = 1.1 in all structures (PHYS-FISTA) and an LET-weighted dose model (LET-FISTA). Three head and neck patients were planned with the four techniques and compared on dosimetry and robustness.ResultsCompared to Phys-FISTA, McNam-CP was able to match CTV [HI, Dmax, D95%, D98%] by [0.00, 0.05%, 1.4%, 0.8%]. McNam-FISTA and McNam-CP were able to significantly improve overall OAR [Dmean, Dmax] by an average of [36.1%,26.4%] and [29.6%, 20.3%], respectively. Regarding CTV robustness, worst [Dmax, V95%, D95%, D98%] improvement of [-6.6%, 6.2%, 6.0%, 4.8%] was reported for McNam-FISTA and [2.7%, 2.7%, 5.3%, -4.3%] for McNam-CP under combinations of range and setup uncertainties. For OARs, worst [Dmax, Dmean] were improved by McNam-FISTA and McNam-CP by an average of [25.0%, 19.2%] and [29.5%, 36.5%], respectively. McNam-FISTA considerably improved dosimetry and CTV robustness compared to LET-FISTA, which achieved better worst-case OAR doses.ConclusionThe four optimization techniques deliver comparable biological doses for the head and neck cases. Besides modest CTV coverage and robustness improvement, OAR biological dose and robustness were substantially improved with both McNam-FISTA and McNam-CP, showing potential benefit for directly incorporating McNamara RBE in proton treatment planning.

Published

2022

15. Combined RBE and OER optimization in proton therapy with FLUKA based on EF5‐PET.

Author

Henjum, Helge, Dahle, Tordis Johnsen, Mairani, Andrea, Pilskog, Sara, Stokkevåg, Camilla, Boer, Camilla Grindeland, Redalen, Kathrine Røe, Minn, Heikki, Malinen, Eirik, and Ytre‐Hauge, Kristian Smeland

Subjects

PROTON therapy, PROTON beams, LINEAR energy transfer, POSITRON emission tomography, HEAD & neck cancer, TREATMENT effectiveness

Abstract

Introduction: Tumor hypoxia is associated with poor treatment outcome. Hypoxic regions are more radioresistant than well‐oxygenated regions, as quantified by the oxygen enhancement ratio (OER). In optimization of proton therapy, including OER in addition to the relative biological effectiveness (RBE) could therefore be used to adapt to patient‐specific radioresistance governed by intrinsic radiosensitivity and hypoxia. Methods: A combined RBE and OER weighted dose (ROWD) calculation method was implemented in a FLUKA Monte Carlo (MC) based treatment planning tool. The method is based on the linear quadratic model, with α and β parameters as a function of the OER, and therefore a function of the linear energy transfer (LET) and partial oxygen pressure (pO2). Proton therapy plans for two head and neck cancer (HNC) patients were optimized with pO2 estimated from [18F]‐EF5 positron emission tomography (PET) images. For the ROWD calculations, an RBE of 1.1 (RBE1.1,OER) and two variable RBE models, Rørvik (ROR) and McNamara (MCN), were used, alongside a reference plan without incorporation of OER (RBE1.1). Results: For the HNC patients, treatment plans in line with the prescription dose and with acceptable target ROWD could be generated with the established tool. The physical dose was the main factor modulated in the ROWD. The impact of incorporating OER during optimization of HNC patients was demonstrated by the substantial difference found between ROWD and physical dose in the hypoxic tumor region. The largest physical dose differences between the ROWD optimized plans and the reference plan was 12.2 Gy. Conclusion: The FLUKA MC based tool was able to optimize proton treatment plans taking the tumor pO2 distribution from hypoxia PET images into account. Independent of RBE‐model, both elevated LET and physical dose were found in the hypoxic regions, which shows the potential to increase the tumor control compared to a conventional optimization approach. [ABSTRACT FROM AUTHOR]

Published

2023

16. A time-resolved clonogenic assay for improved cell survival and RBE measurements

Author

Robin A Koch, Marc Boucsein, Stephan Brons, Markus Alber, and Emanuel Bahn

Subjects

Radiobiology, Dose-response relationship, radiation, Relative biological effectiveness, Heavy ion radiotherapy, Time-lapse imaging, Supervised machine learning, Medical physics. Medical radiology. Nuclear medicine, R895-920, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Purpose: The in vitro clonogenic assay (IVCA) is the mainstay of quantitative radiobiology. Here, we investigate the benefit of a time-resolved IVCA version (trIVCA) to improve the quantification of clonogenic survival and relative biological effectiveness (RBE) by analyzing cell colony growth behavior. Materials & Methods: In the IVCA, clonogenicity classification of cell colonies is performed based on a fixed colony size threshold after incubation. In contrast, using trIVCA, we acquire time-lapse microscopy images during incubation and track the growth of each colony using neural-net-based image segmentation. Attributes of the resulting growth curves are then used as predictors for a decision tree classifier to determine clonogenicity of each colony. The method was applied to three cell lines, each irradiated with 250 kV X-rays in the range 0–8 Gy and carbon ions of high LET (100 keV/μm, dose-averaged) in the range 0–2 Gy. We compared the cell survival curves determined by trIVCA to those from the classical IVCA across different size thresholds and incubation times. Further, we investigated the impact of the assaying method on RBE determination. Results: Size distributions of abortive and clonogenic colonies overlap consistently, rendering perfect separation via size threshold unfeasible at any readout time. This effect is dose-dependent, systematically inflating the steepness and curvature of cell survival curves. Consequently, resulting cell survival estimates show variability between 3% and 105%. This uncertainty propagates into RBE calculation with variability between 8% and 25% at 2 Gy.Determining clonogenicity based on growth curves has an accuracy of 95% on average. Conclusion: The IVCA suffers from substantial uncertainty caused by the overlap of size distributions of delayed abortive and clonogenic colonies. This impairs precise quantification of cell survival and RBE. By considering colony growth over time, our method improves assaying clonogenicity.

Published

2023

17. Double scattering and pencil beam scanning Monte Carlo workflows for proton therapy retrospective studies on radiation-induced toxicities.

Author

Leite, A.M.M., Bonfrate, A., Da Fonseca, A., Lansonneur, P., Alapetite, C., Mammar, H., and De Marzi, L.

Subjects

*PHYSIOLOGICAL effects of radiation, *PROTON scattering, *TOXICITY testing, *COMPUTER simulation, *PROTON therapy

Abstract

Monte Carlo (MC) simulations can be used to accurately simulate dose and linear energy transfers (LET) distributions, thereby allowing for the calculation of the relative biological effectiveness (RBE) of protons. We present hereby the validation and implementation of a workflow for the Monte Carlo modelling of the double scattered and pencil beam scanning proton beamlines at our institution. The TOPAS/Geant4 MC model of the clinical nozzle has been comprehensively validated against measurements. The validation also included a comparison between simulated clinical treatment plans for four representative patients and the clinical treatment planning system (TPS). Moreover, an in-house tool implemented in Python was tested to assess the variable RBE-weighted dose in proton plans, which was illustrated for a patient case with a developing radiation-induced toxicity. The simulated range and modulation width closely matches the measurements. Gamma-indexes (3%/3 mm 3D), which compare the TPS and MC computations, showed a passing rate superior to 98%. The calculated RBE-weighted dose presented a slight increase at the necrosis location, within the PTV margins. This indicates the need for reporting on the physical and biological effects of irradiation in high dose regions, especially at the healthy tissues and increased LET distributions location. The results demonstrate that the Monte Carlo method can be used to independently validate a TPS calculation, and to estimate LET distributions. The features of the in-house tool can be used to correlate LET and RBE-weighted dose distributions with the incidence of radiation-induced toxicities following proton therapy treatments. [ABSTRACT FROM AUTHOR]

Published

2023

18. Creation, evolution, and future challenges of ion beam therapy from a medical physicist's viewpoint (Part 2). Chapter 2. Biophysical model, treatment planning system and image guided radiotherapy.

Author

Endo, Masahiro

Abstract

When an ion beam penetrates deeply into the body, its kinetic energy decreases, and its biological effect increases due to the change of the beam quality. To give a uniform biological effect to the target, it is necessary to reduce the absorbed dose with the depth. A bio-physical model estimating the relationship between ion beam quality and biological effect is necessary to determine the relative biological effectiveness (RBE) of the ion beam that changes with depth. For this reason, Lawrence Berkeley Laboratory, National Institute of Radiological Sciences (NIRS) and GSI have each developed their own model at the starting of the ion beam therapy. Also, NIRS developed a new model at the starting of the scanning irradiation. Although the Local Effect Model (LEM) at the GSI and the modified Microdosimetric Kinetic Model (MKM) at the NIRS, the both are currently used, can similarly predict radiation quality-induced changes in surviving fraction of cultured cell, the clinical RBE-weighted doses for the same absorbed dose are different. This is because the LEM uses X-rays as a reference for clinical RBE, whereas the modified MKM uses carbon ion beam as a reference and multiplies it by a clinical factor of 2.41. Therefore, both are converted through the absorbed dose. In PART 2, I will describe the development of such a bio-physical model, as well as the birth and evolution of a treatment planning system and image guided radiotherapy. [ABSTRACT FROM AUTHOR]

Published

2023

19. Relative Biological Effectiveness Values of Spot-scanning Proton Beam Therapy at Shonan Kamakura General Hospital.

Author

SHINTARO SHIBA, MASASHI YAMANAKA, KAZUKI MATSUMOTO, AKIHIRO YAMANO, TAKAHIRO SHIMO, SHUNSUKE SUZUKI, TAKAYUKI YAGIHASHI, KAZUNORI NITTA, TATSUYA OHNO, KOICHI TOKUUYE, and MOTOKO OMURA

Subjects

PROTON therapy, OSTEOSARCOMA, CELL lines, X-rays, SALIVARY glands

Abstract

Background/Aim: This study aimed to confirm the relative biological effectiveness (RBE) values of the proton beam therapy (PBT) system installed in Shonan Kamakura General Hospital. Materials and Methods: Clonogenic cellsurvival assays were performed with a human salivary gland (HSG) cell line, a human tongue squamous-cell carcinoma cell line (SAS), and a human osteosarcoma cell line (MG-63). Cells were irradiated with proton beams and X-rays with different doses (1.8, 3.6, 5.5, and 7.3 Gy for proton beams, and 2, 4, 6, and 8 Gy for X-rays). Proton beam irradiation used spot-scanning methods and three different depths (at the proximal, center, and distal sides of the spread-out Bragg peak). RBE values were obtained from a comparison of the dose that resulted in a surviving fraction of 10% (D10). Results: D10 of proton beams at the proximal, center, and distal sides and X-rays in HSG were 4.71, 4.71, 4.51, and 5.25 Gy, respectively; those in SAS were 5.08, 5.04, 5.01, and 5.59 Gy, respectively; and those in MG-63 were 5.36, 5.42, 5.12, and 6.06 Gy, respectively. The RBE10 values at the proximal, center, and distal sides in HSG were 1.11, 1.11, and 1.16 respectively; those in SAS were 1.10, 1.11, and 1.12, respectively; and those in MG-63 were 1.13, 1.12, and 1.18, respectively. Conclusion: RBE10 values of 1.10-1.18 were confirmed by in vitro experiments using the PBT system. These results are considered acceptable for clinical use in terms of therapeutic efficacy and safety. [ABSTRACT FROM AUTHOR]

Published

2023

20. Discussion of uncertainties and the impact of different neutron RBEs on all solid cancer radiation incidence risks obtained from the Japanese A-bomb survivor data.

Author

Hafner, L., Walsh, L., and Rühm, W.

Subjects

*ATOMIC bomb, *NEUTRONS, *RADIATION, *INTERVAL analysis, *LIFE spans, *NEUTRON irradiation

Abstract

The most recent publicly available data on all solid cancer incidence from the Life Span Study (LSS) of Japanese A-bomb survivors provides colon dose contributions weighted with a relative biological effectiveness (RBE) of 10 for neutrons, relative to gammas. However, there is evidence from several investigations that the neutron RBE for A-bomb survivors may be higher than 10. The change in the shape of the corresponding dose–response curves was evaluated by Hafner and co-workers in a previous study by applying sex-specific linear-quadratic dose models to previous LSS data for all solid cancer incidence that include separate neutron and gamma absorbed doses for several organs, in contrast to the most recent data. The resulting curvature change became significantly negative for males at an RBE of 140 for colon, 100 for liver, and 80 for organ averaged dose. For females, the corresponding RBE values were 110, 80, and 60 for colon, liver, and organ averaged doses. The present study compares three different methods to calculate the 95% confidence intervals in an analysis of the curvature with increasing RBE. Further, the impact of a higher neutron RBE on the work of the International Commission on Radiological Protection, and the importance of including uncertainties and performing sensitivity analysis of different parameters in radiation risk assessment are discussed. [ABSTRACT FROM AUTHOR]

Published

2023

21. Linear energy transfer-inclusive models of brainstem necrosis following proton therapy of paediatric ependymoma

Author

Andreas H. Handeland, Daniel J. Indelicato, Lars Fredrik Fjæra, Kristian S. Ytre-Hauge, Helge Egil S. Pettersen, Ludvig P. Muren, Yasmin Lassen-Ramshad, and Camilla H. Stokkevåg

Subjects

Proton therapy, Pediatric, Relative biological effectiveness, Normal tissue complication probability, Brainstem necrosis, Ependymoma, Medical physics. Medical radiology. Nuclear medicine, R895-920, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Background and Purpose: Radiation-induced brainstem necrosis after proton therapy is a severe toxicity with potential association to uncertainties in the proton relative biological effectiveness (RBE). A constant RBE of 1.1 is assumed clinically, but the RBE is known to vary with linear energy transfer (LET). LET-inclusive predictive models of toxicity may therefore be beneficial during proton treatment planning. Hence, we aimed to construct models describing the association between brainstem necrosis and LET in the brainstem. Materials and methods: A matched case-control cohort (n = 28, 1:3 case-control ratio) of symptomatic brainstem necrosis was selected from 954 paediatric ependymoma brain tumour patients treated with passively scattered proton therapy. Dose-averaged LET (LETd) parameters in restricted volumes (L50%, L10% and L0.1cm3, the cumulative LETd) within high-dose thresholds were included in linear- and logistic regression normal tissue complication probability (NTCP) models. Results: A 1 keV/µm increase in L10% to the brainstem volume receiving dose over 54 Gy(RBE) led to an increased brainstem necrosis risk [95% confidence interval] of 2.5 [0.0, 7.8] percentage points. The corresponding logistic regression model had area under the receiver operating characteristic curve (AUC) of 0.76, increasing to 0.84 with the anterior pons substructure as a second parameter. 19 [7, 350] patients with toxicity were required to associate the L10% (D > 54 Gy(RBE)) and brainstem necrosis with 80% statistical power. Conclusion: The established models of brainstem necrosis illustrate a potential impact of high LET regions in patients receiving high doses to the brainstem, and thereby support LET mitigation during clinical treatment planning.

Published

2023

22. Modeling of ionizing radiation-induced chromosome aberration and tumor prevalence based on two classes of DNA double-strand breaks clustering in chromatin domains

Author

Lei Zhao, Aiping Tang, Fei Long, Dong Mi, and Yeqing Sun

Subjects

Ionizing radiation, Chromosome aberration, Tumor prevalence, Non-targeted effect, Radiobiological model, Relative biological effectiveness, Environmental pollution, TD172-193.5, Environmental sciences, GE1-350

Abstract

There has been some controversy over the use of radiobiological models when modeling the dose-response curves of ionizing radiation (IR)-induced chromosome aberration and tumor prevalence, as those curves usually show obvious non-targeted effects (NTEs) at low doses of high linear energy transfer (LET) radiation. The lack of understanding the contribution of NTEs to IR-induced carcinogenesis can lead to distinct deviations of relative biological effectiveness (RBE) estimations of carcinogenic potential, which are widely used in radiation risk assessment and radiation protection. In this work, based on the initial pattern of two classes of IR-induced DNA double-strand breaks (DSBs) clustering in chromatin domains and the subsequent incorrect repair processes, we proposed a novel radiobiological model to describe the dose-response curves of two carcinogenic-related endpoints within the same theoretical framework. The representative experimental data was used to verify the consistency and validity of the present model. The fitting results indicated that, compared with targeted effect (TE) and NTE models, the current model has better fitting ability when dealing with the experimental data of chromosome aberration and tumor prevalence induced by multiple types of IR with different LETs. Notably, the present model without introducing an NTE term was adequate to describe the dose-response curves of IR-induced chromosome aberration and tumor prevalence with NTEs in low-dose regions. Based on the fitting parameters, the LET-dependent RBE values were calculated for three given low doses. Our results showed that the RBE values predicted by the current model gradually decrease with the increase of doses for the endpoints of chromosome aberration and tumor prevalence. In addition, the calculated RBE was also compared with those evaluated from other models. These analyses show that the proposed model can be used as an alternative tool to well describe dose-response curves of multiple carcinogenic-related endpoints and effectively estimate RBE in low-dose regions.

Published

2023

23. Monte Carlo-based evaluation of the relevant RBE values to produced low-energy X-rays by INTRABEAM and Axxent dedicated IORT facilities

Author

Shamsabadi, Reza, Baghani, Hamid Reza, and Azadegan, Behnam

Published

2024

24. A Mission to Mars: Prediction of GCR Doses and Comparison with Astronaut Dose Limits.

Author

Ramos, Ricardo L., Carante, Mario P., Ferrari, Alfredo, Sala, Paola, Vercesi, Valerio, and Ballarini, Francesca

Subjects

*HUMAN space flight, *CHROMOSOME abnormalities, *ASTRONAUTS, *MARS (Planet), *ABSORBED dose

Abstract

Long-term human space missions such as a future journey to Mars could be characterized by several hazards, among which radiation is one the highest-priority problems for astronaut health. In this work, exploiting a pre-existing interface between the BIANCA biophysical model and the FLUKA Monte Carlo transport code, a study was performed to calculate astronaut absorbed doses and equivalent doses following GCR exposure under different shielding conditions. More specifically, the interface with BIANCA allowed us to calculate both the RBE for cell survival, which is related to non-cancer effects, and that for chromosome aberrations, related to the induction of stochastic effects, including cancer. The results were then compared with cancer and non-cancer astronaut dose limits. Concerning the stochastic effects, the equivalent doses calculated by multiplying the absorbed dose by the RBE for chromosome aberrations ("high-dose method") were similar to those calculated using the Q-values recommended by ICRP. For a 650-day mission at solar minimum (representative of a possible Mars mission scenario), the obtained values are always lower than the career limit recommended by ICRP (1 Sv), but higher than the limit of 600 mSv recently adopted by NASA. The comparison with the JAXA limits is more complex, since they are age and sex dependent. Concerning the deterministic limits, even for a 650-day mission at solar minimum, the values obtained by multiplying the absorbed dose by the RBE for cell survival are largely below the limits established by the various space agencies. Following this work, BIANCA, interfaced with an MC transport code such as FLUKA, can now predict RBE values for cell death and chromosome aberrations following GCR exposure. More generally, both at solar minimum and at solar maximum, shielding of 10 g/cm2 Al seems to be a better choice than 20 g/cm2 for astronaut protection against GCR. [ABSTRACT FROM AUTHOR]

Published

2023

25. Monte Carlo-Based Radiobiological Investigation of the Most Optimal Ion Beam Forming SOBP for Particle Therapy.

Author

Kantemiris, Ioannis, Pappas, Eleftherios P., Lymperopoulou, Georgia, Thanasas, Dimitrios, and Karaiskos, Pantelis

Subjects

*ION beams, *PROTON beams, *STANDARD & Poor's 500 Index

Abstract

Proton (p) and carbon (C) ion beams are in clinical use for cancer treatment, although other particles such as He, Be, and B ions have more recently gained attention. Identification of the most optimal ion beam for radiotherapy is a challenging task involving, among others, radiobiological characterization of a beam, which is depth-, energy-, and cell type- dependent. This study uses the FLUKA and MCDS Monte Carlo codes in order to estimate the relative biological effectiveness (RBE) for several ions of potential clinical interest such as p, 4He, 7Li, 10Be, 10B, and 12C forming a spread-out Bragg peak (SOBP). More specifically, an energy spectrum of the projectiles corresponding to a 5-cm SOBP at a depth of 8 cm was used. All secondary particles produced by the projectiles were considered and RBE was determined based on radiation-induced Double Strand Breaks (DSBs), as calculated by MCDS. In an attempt to identify the most optimal ion beam, using the latter data, biological optimization was performed and the obtained depth–dose distributions were inter-compared. The results showed that 12C ions are more effective inside the SOBP region, which comes at the expense of higher dose values at the tail (i.e., after the SOBP). In contrast, p beams exhibit a higher D S O P B / D E n t r a n c e ratio, if physical doses are considered. By performing a biological optimization in order to obtain a homogeneous biological dose (i.e., dose × RBE) in the SOBP, the corresponding advantages of p and 12C ions are moderated. 7Li ions conveniently combine a considerably lower dose tail and a D S O P B / D E n t r a n c e ratio similar to 12C. This work contributes towards identification of the most optimal ion beam for cancer therapy. The overall results of this work suggest that 7Li ions are of potential interest, although more studies are needed to demonstrate the relevant advantages. Future work will focus on studying more complex beam configurations. [ABSTRACT FROM AUTHOR]

Published

2023

26. Treatment‐planning approaches to intensity modulated proton therapy and the impact on dose‐weighted linear energy transfer.

Author

Faught, Austin M., Wilson, Lydia J., Gargone, Melissa, Pirlepesov, Fakhriddin, Moskvin, Vadim P., and Hua, Chia‐Ho

Subjects

LINEAR energy transfer, PROTON therapy, PROTON beams, RADIOTHERAPY, BRAIN tumors

Abstract

Purpose: We quantified the effect of various forward‐based treatment‐planning strategies in proton therapy on dose‐weighted linear energy transfer (LETd). By maintaining the dosimetric quality at a clinically acceptable level, we aimed to evaluate the differences in LETd among various treatment‐planning approaches and their practicality in minimizing biologic uncertainties associated with LETd. Method: Eight treatment‐planning strategies that are achievable in commercial treatment‐planning systems were applied on a cylindrical water phantom and four pediatric brain tumor cases. Each planning strategy was compared to either an opposed lateral plan (phantom study) or original clinical plan (patient study). Deviations in mean and maximum LETd from clinically acceptable dose distributions were compared. Results: In the phantom study, using a range shifter and altering the robust scenarios during optimization had the largest effect on the mean clinical target volume LETd, which was reduced from 4.5 to 3.9 keV/μm in both cases. Variations in the intersection angle between beams had the largest effect on LETd in a ring defined 3 to 5 mm outside the target. When beam intersection angles were reduced from opposed laterals (180°) to 120°, 90°, and 60°, corresponding maximum LETd increased from 7.9 to 8.9, 10.9, and 12.2 keV/μm, respectively. A clear trend in mean and maximum LETd variations in the clinical cases could not be established, though spatial distribution of LETd suggested a strong dependence on patient anatomy and treatment geometry. Conclusion: Changes in LETd from treatment‐plan setup follow intuitive trends in a controlled phantom experiment. Anatomical and other patient‐specific considerations, however, can preclude generalizable strategies in clinical cases. For pediatric cranial radiation therapy, we recommend using opposed lateral treatment fields to treat midline targets. [ABSTRACT FROM AUTHOR]

Published

2023

27. Biological Effectiveness of Fast Neutrons and Accelerated Multicharged Ions for Derivation of a New Dependence of Space Radiation Quality Coefficients on Linear Energy Transfer.

Author

Shafirkin, A. V., Grigoriev, Yu. G., Ushakov, I. B., and Shurshakov, V. A.

Subjects

*LINEAR energy transfer, *FAST neutrons, *ASTROPHYSICAL radiation, *GALACTIC cosmic rays, *CELL transformation

Abstract

The authors present a review of new experimental data on the relative biological effectiveness (RBE) of the impact on the body of fast neutrons and accelerated multicharged ions (AMIs) in small, absorbed doses of 0.01–0.5 Gy, which are allowed by modern radiation safety standards for the career of astronauts to limit the risk of delayed adverse effects. According to new radiobiological data for low doses and their rates, the literature presents higher (2–3 times) maximum values of the RBE coefficients for cytogenetic disorders that persist in the long-term period; malignant transformation of cells and the risk of developing tumors of different tissues; reduction in life expectancy; disorders of neurons in the cerebral cortex and damage to individual organs; and the degree of clouding of the lens and the formation of cataracts. Based on the analysis performed, a new dependence of quality factors on linear energy transfer is presented, from which it follows that the estimated values of equivalent doses in relation to the effects of galactic cosmic rays and fast neutrons, as well as the calculated values of the total radiation risk during the life of astronauts, will increase significantly. [ABSTRACT FROM AUTHOR]

Published

2022

28. Effects of dose and dose-averaged linear energy transfer on pelvic insufficiency fractures after carbon-ion radiotherapy for uterine carcinoma.

Author

Mori, Yasumasa, Okonogi, Noriyuki, Matsumoto, Shinnosuke, Furuichi, Wataru, Fukahori, Mai, Miyasaka, Yuhei, Murata, Kazutoshi, Wakatsuki, Masaru, Imai, Reiko, Koto, Masashi, Yamada, Shigeru, Ishikawa, Hitoshi, Kanematsu, Nobuyuki, and Tsuji, Hiroshi

Subjects

*LINEAR energy transfer, *PELVIC fractures, *RECEIVER operating characteristic curves, *SACRAL fractures, *RADIOTHERAPY

Abstract

• We assessed the prognostic factors for sacrum insufficiency fractures (SIFs) in carbon-ion RT. • Median RBE-weighted dose to the sacrum was a risk factor for SIF. • Neither LET nor physical dose parameters were significant risk factors for SIF. The correlation between dose-averaged linear energy transfer (LETd) and its therapeutic or adverse effects, especially in carbon-ion radiotherapy (CIRT), remains controversial. This study aimed to investigate the effects of LETd and dose on pelvic insufficiency fractures after CIRT. Among patients who underwent CIRT for uterine carcinoma, 101 who were followed up for > 6 months without any other therapy were retrospectively analyzed. The sacrum insufficiency fractures (SIFs) were graded according to the Radiation Therapy Oncology Group/European Organization for Research and Treatment of Cancer toxicity criteria. The correlations between the relative biological effectiveness (RBE)-weighted dose, LETd, physical dose, clinical factors, and SIFs were evaluated. In addition, we analyzed the association of SIF with LETd, physical dose, and clinical factors in cases where the sacrum D50% RBE-weighted dose was above the median dose. At the last follow-up, 19 patients developed SIFs. Receiver operating characteristic curve analysis revealed that the sacrum D50% RBE-weighted dose was a valuable predictor of SIF. Univariate analyses suggested that LETd V10 keV/µm, physical dose V5 Gy, and smoking status were associated with SIF. Cox regression analysis in patients over 50 years of age validated that current smoking habit was the sole risk factor for SIF. Therefore, LETd or physical dose parameters were not associated with SIF prediction. The sacrum D50% RBE-weighted dose was identified as a risk factor for SIF. Additionally, neither LETd nor physical dose parameters were associated with SIF prediction. [ABSTRACT FROM AUTHOR]

Published

2022

29. Diamond energy-dispersive dosimeter for measuring linear energy deposition distributions in clinical carbon beam therapy.

Author

Matsumoto, Takumi, Aoki, Katsumi, Takei, Hideyuki, Makino, Takahiro, Yonai, Shunsuke, Weiss, Christina, Griesmayer, Erich, Ohshima, Takeshi, Sakai, Makoto, Matsumura, Akihiko, and Kada, Wataru

Subjects

*LINEAR energy transfer, *DOSIMETERS, *WIDE gap semiconductors, *BIOCOMPATIBILITY, *DIAMONDS, *DIAMOND crystals, *NANODIAMONDS

Abstract

A thin diamond membrane energy-dispersive dosimeter 50 μm thick was fabricated for estimating clinical dose distribution. In contrast to conventional semiconductors, diamond wide-bandgap semiconductors are expected to have excellent radiation tolerance and biological compatibility based on the linear relationship of stopping power ratio for clinical carbon particles. Linear energy transfer (LET) spectra were obtained along with the Bragg curve for a clinical carbon beam generated at Gunma University Heavy Ion Medical Center. The relative biological effectiveness (RBE) distributions were estimated from the LET spectra for both the mono-energy and spread-out Bragg peak irradiation configurations. The diamond detector was also used as a solid ionization chamber to obtain the radiation-induced current (RIC) distribution, which represents the physical dose distribution. The clinical dose distribution was estimated from the RIC and RBE distributions as proof of concept for the clinical carbon beam therapy field with a single-chip diamond energy-dispersive dosimeter. [ABSTRACT FROM AUTHOR]

Published

2024

30. The history of ion beam therapy in Germany

Author

Oliver Jäkel, Gerhard Kraft, and Christian P. Karger

Subjects

Light ion beam therapy, Carbon ion therapy, Relative biological effectiveness, Beam scanning, Medical physics. Medical radiology. Nuclear medicine, R895-920

Abstract

The advantageous depth dose profile of ion beams together with state of the art beam delivery and treatment planning systems allow for highly conformal tumor treatments in patients. First treatments date back to 1954 at the Lawrence Berkeley Laboratory (LBL) and in Europe, ion beam therapy started in the mid-1990s at the Paul-Scherrer Institute (PSI) with protons and at the Helmholtz Center for Heavy Ion Research (GSI) with carbon ions, followed by the Heidelberg Ion Therapy Center (HIT) in Heidelberg. This review describes the historical development of ion beam therapy in Germany based on the pioneering work at LBL and in the context of simultaneous developments in other countries as well as recent developments.

Published

2022

31. Comparison of AUA and phoenix definitions of biochemical failure following permanent brachytherapy for prostate cancer.

Author

Gul, Zeynep G., Say, Rollin, Skouteris, Vassilios M., Stock, Richard G., and Stone, Nelson N.

Subjects

*RADIOISOTOPE brachytherapy, *PROSTATE-specific antigen, *EXTERNAL beam radiotherapy, *PROSTATE cancer, *PROSTATE cancer patients

Abstract

To compare biochemical recurrence free survival (BCRFS) and cancer-specific survival (CSS) after brachytherapy using the AUA and the Phoenix definitions. 2634 men with T1-T4N0M0 prostate cancer were treated with brachytherapy with or without neoadjuvant hormonal therapy or external beam radiation therapy. Five, 10, and 15- year BCRFS and CSS were estimated with Kaplan-Meier estimates with log rank. Multivariate analysis of survival was performed with Cox regression analysis. Median age was 66, follow-up was 8.6 years, and prostate specific antigen was 6.9. Overall, 11.1% (n = 293) of patients experienced Phoenix BCR and 17.48% (n = 457) experienced AUA BCR. The rates of AUA BCR and Phoenix BCR were significantly different at 5 and 10-years but not at 15 years. Patients treated with BED ≤ 200 Gy were more likely to experience AUA BCR (22.5% vs. 12.4%, OR 1.44, p < 0.001) and Phoenix BCR (14.3% and 8.3%, OR 1.37, p < 0.001) than patients treated with a BED > 200 Gy. Compared to the Phoenix definition, the AUA definition of BCR after brachytherapy is associated with significantly worse BCRFS for the first 15 years after treatment. Receiving a BED > 200, which cannot be achieved without the addition of brachytherapy, is associated with better BCRFS and CSS. Our findings reaffirm the importance of dose in the management of prostate cancer [ABSTRACT FROM AUTHOR]

Published

2022

32. A matter of space: how the spatial heterogeneity in energy deposition determines the biological outcome of radiation exposure.

Author

Baiocco, Giorgio, Bartzsch, Stefan, Conte, Valeria, Friedrich, Thomas, Jakob, Burkhard, Tartas, Adrianna, Villagrasa, Carmen, and Prise, Kevin M.

Abstract

The outcome of the exposure of living organisms to ionizing radiation is determined by the distribution of the associated energy deposition at different spatial scales. Radiation proceeds through ionizations and excitations of hit molecules with an ~ nm spacing. Approaches such as nanodosimetry/microdosimetry and Monte Carlo track-structure simulations have been successfully adopted to investigate radiation quality effects: they allow to explore correlations between the spatial clustering of such energy depositions at the scales of DNA or chromosome domains and their biological consequences at the cellular level. Physical features alone, however, are not enough to assess the entity and complexity of radiation-induced DNA damage: this latter is the result of an interplay between radiation track structure and the spatial architecture of chromatin, and further depends on the chromatin dynamic response, affecting the activation and efficiency of the repair machinery. The heterogeneity of radiation energy depositions at the single-cell level affects the trade-off between cell inactivation and induction of viable mutations and hence influences radiation-induced carcinogenesis. In radiation therapy, where the goal is cancer cell inactivation, the delivery of a homogenous dose to the tumour has been the traditional approach in clinical practice. However, evidence is accumulating that introducing heterogeneity with spatially fractionated beams (mini- and microbeam therapy) can lead to significant advantages, particularly in sparing normal tissues. Such findings cannot be explained in merely physical terms, and their interpretation requires considering the scales at play in the underlying biological mechanisms, suggesting a systemic response to radiation. [ABSTRACT FROM AUTHOR]

Published

2022

33. The Mayo Clinic Florida Microdosimetric Kinetic Model of Clonogenic Survival: Application to Various Repair-Competent Rodent and Human Cell Lines.

Author

Parisi, Alessio, Beltran, Chris J., and Furutani, Keith M.

Subjects

*CELL lines, *RODENTS, *NUMBERS of species, *ANIMAL species

Abstract

The relative biological effectiveness (RBE) calculations used during the planning of ion therapy treatments are generally based on the microdosimetric kinetic model (MKM) and the local effect model (LEM). The Mayo Clinic Florida MKM (MCF MKM) was recently developed to overcome the limitations of previous MKMs in reproducing the biological data and to eliminate the need for ion-exposed in vitro data as input for the model calculations. Since we are considering to implement the MCF MKM in clinic, this article presents (a) an extensive benchmark of the MCF MKM predictions against corresponding in vitro clonogenic survival data for 4 rodent and 10 cell lines exposed to ions from 1H to 238U, and (b) a systematic comparison with published results of the latest version of the LEM (LEM IV). Additionally, we introduce a novel approach to derive an approximate value of the MCF MKM model parameters by knowing only the animal species and the mean number of chromosomes. The overall good agreement between MCF MKM predictions and in vitro data suggests the MCF MKM can be reliably used for the RBE calculations. In most cases, a reasonable agreement was found between the MCF MKM and the LEM IV. [ABSTRACT FROM AUTHOR]

Published

2022

34. Assessing the DNA Damaging Effectiveness of Ionizing Radiation Using Plasmid DNA.

Author

Maayah, Yara, Nusrat, Humza, Pang, Geordi, and Tambasco, Mauro

Subjects

*IONIZING radiation, *SINGLE-strand DNA breaks, *DNA damage, *RADIATION damage, *LINEAR energy transfer

Abstract

Plasmid DNA is useful for investigating the DNA damaging effects of ionizing radiation. In this study, we have explored the feasibility of plasmid DNA-based detectors to assess the DNA damaging effectiveness of two radiotherapy X-ray beam qualities after undergoing return shipment of ~8000 km between two institutions. The detectors consisted of 18   μ L of pBR322 DNA enclosed with an aluminum seal in nine cylindrical cavities drilled into polycarbonate blocks. We shipped them to Toronto, Canada for irradiation with either 100   kVp   or 6   MV   X-ray beams to doses of 10, 20, and 30 Gy in triplicate before being shipped back to San Diego, USA. The Toronto return shipment also included non-irradiated controls and we kept a separate set of controls in San Diego. In San Diego, we quantified DNA single strand breaks (SSBs), double strand breaks (DSBs), and applied Nth and Fpg enzymes to quantify oxidized base damage. The rate of DSBs/Gy/plasmid was 2.8 ± 0.7   greater for the 100 kVp than the 6 MV irradiation. The 100   kVp irradiation also resulted in 5 ± 2 times more DSBs/SSB than the 6   MV beam, demonstrating that the detector is sensitive enough to quantify relative DNA damage effectiveness, even after shipment over thousands of kilometers. [ABSTRACT FROM AUTHOR]

Published

2022

35. Organs at risk dose constraints in carbon ion radiotherapy at MedAustron: Translations between LEM and MKM RBE models and preliminary clinical results.

Author

Grosshagauer, Sarah, Fossati, Piero, Schafasand, Mansure, Carlino, Antonio, Poljanc, Karin, Radakovits, Tobias, Stock, Markus, Hug, Eugen, Georg, Petra, Pelak, Maciej, and Góra, Joanna

Subjects

*RADIOTHERAPY, *CURVE fitting, *TRANSLATING & interpreting, *CARBON, *DECISION making

Abstract

• Translation between European and Japanese RBE modelling for constraint validation. • Potential pitfalls for constraint definition in carbon ion radiotherapy of CNS. • RBE model translation trend outliers and their association with clinical toxicities. • Decision making process based on two RBE models, triggered by CNS toxicities. Carbon ion radiotherapy (CIRT) treatment planning is based on relative biological effectiveness (RBE) weighted dose calculations. A large amount of clinical evidence for CIRT was collected in Japan with RBE estimated by the modified microdosimetric kinetic model (MKM) while all European centres apply the first version of the local effect model (LEM). Japanese schedules have been used in Europe with adapted prescription dose and organs at risk (OAR) dose constraints. Recently, less conservative adapted LEM constraints have been implemented in clinical practice. The aim of this study was to analyse the new set of LEM dose constraints for brain parenchyma, brainstem and optic system considering both RBE models and evaluating early clinical data. 31 patients receiving CIRT at MedAustron were analysed using the RayStation v9A planning system by recalculating clinical LEM-based plans in MKM. Dose statistics (D1cm3, D5cm3, D0.1cm3, D0.7cm3, D10%, D20%) were extracted for relevant critical OARs. Curve fitting for those values was performed, resulting in linear quadratic translation models. Clinical and radiological toxicity was evaluated. Based on derived fits, currently applied LEM constraints matched recommended MKM constraints with deviations between −8% and +3.9%. For particular cases, data did not follow the expected LEM vs MKM trends resulting in outliers. Radiological (asymptomatic) toxicity was detected in two outlier cases. Respecting LEM constraints does not automatically ensure that MKM constraints are met. Constraints for both RBE models need to be fulfilled for future CIRT patients at MedAustron. Careful selection of planning strategies is essential. [ABSTRACT FROM AUTHOR]

Published

2022

36. Microdosimetry Study of Proton Quality Factor Using Analytic Model Calculations.

Author

Papadopoulos, Alexis, Kyriakou, Ioanna, Matsuya, Yusuke, Incerti, Sébastien, Daglis, Ioannis A., and Emfietzoglou, Dimitris

Subjects

QUALITY factor, IONIZING radiation, MICRODOSIMETRY, PROTONS, LINEAR energy transfer, RADIATION dosimetry, PHYSICAL constants

Abstract

The quality factor (Q) is formally linked to the stochastic (e.g., carcinogenic) risk of diverse ionizing radiations at low doses and/or low dose rates. Q can be a function of the non-stochastic physical quantity Linear Energy Transfer (LET) or the microdosimetric parameter lineal energy (y). These two physical quantities can be calculated either by Monte Carlo (MC) track-structure simulations or by analytic models. In this work, various generalized analytical models were utilized and combined to determine the proton lineal energy spectra in liquid water spheres of various sizes (i.e., 10–3000 nm diameter) over the proton energy range of 1–250 MeV. The calculated spectra were subsequently used within the Theory of Dual Radiation Action (TDRA) and the ICRU Report 40 microdosimetric methodologies to determine the variation of Q ¯ with proton energy. The results revealed that the LET-based Q values underestimated the microdosimetric-based Q ¯ values for protons with energy below ~100 MeV. At energies relevant to the Bragg peak region (<20–30 MeV), the differences were larger than 20–50%, while reaching 200–500% at ~5 MeV. It was further shown that the microdosimetric-based Q ¯ values for protons below ~100 MeV were sensitive to the sphere size. Finally, condensed-phase effects had a very small (<5%) influence on the calculated microdosimetric-based Q ¯ over the proton energy range considered here. [ABSTRACT FROM AUTHOR]

Published

2022

37. In vitro dose effect relationships of actinium-225- and lutetium-177-labeled PSMA-I&T.

Author

Ruigrok, Eline A. M., Tamborino, Giulia, de Blois, Erik, Roobol, Stefan J., Verkaik, Nicole, De Saint-Hubert, Marijke, Konijnenberg, Mark W., van Weerden, Wytske M., de Jong, Marion, and Nonnekens, Julie

Subjects

*DOUBLE-strand DNA breaks, *LINEAR energy transfer, *DNA repair, *BINDING site assay, *TREATMENT effectiveness

Abstract

Purpose: Targeting the prostate-specific membrane antigen (PSMA) using lutetium-177-labeled PSMA-specific tracers has become a very promising novel therapy option for prostate cancer (PCa). The efficacy of this therapy might be further improved by replacing the β-emitting lutetium-177 with the α-emitting actinium-225. Actinium-225 is thought to have a higher therapeutic efficacy due to the high linear energy transfer (LET) of the emitted α-particles, which can increase the amount and complexity of the therapy induced DNA double strand breaks (DSBs). Here we evaluated the relative biological effectiveness of [225Ac]Ac-PSMA-I&T and [177Lu]Lu-PSMA-I&T by assessing in vitro binding characteristics, dosimetry, and therapeutic efficacy. Methods and results: The PSMA-expressing PCa cell line PC3-PIP was used for all in vitro assays. First, binding and displacement assays were performed, which revealed similar binding characteristics between [225Ac]Ac-PSMA-I&T and [177Lu]Lu-PSMA-I&T. Next, the assessment of the number of 53BP1 foci, a marker for the number of DNA double strand breaks (DSBs), showed that cells treated with [225Ac]Ac-PSMA-I&T had slower DSB repair kinetics compared to cells treated with [177Lu]Lu-PSMA-I&T. Additionally, clonogenic survival assays showed that specific targeting with [225Ac]Ac-PSMA-I&T and [177Lu]Lu-PSMA-I&T caused a dose-dependent decrease in survival. Lastly, after dosimetric assessment, the relative biological effectiveness (RBE) of [225Ac]Ac-PSMA-I&T was found to be 4.2 times higher compared to [177Lu]Lu-PSMA-I&T. Conclusion: We found that labeling of PSMA-I&T with lutetium-177 or actinium-225 resulted in similar in vitro binding characteristics, indicating that the distinct biological effects observed in this study are not caused by a difference in uptake of the two tracers. The slower repair kinetics of [225Ac]Ac-PSMA-I&T compared to [177Lu]Lu-PSMA-I&T correlates to the assumption that irradiation with actinium-225 causes more complex, more difficult to repair DSBs compared to lutetium-177 irradiation. Furthermore, the higher RBE of [225Ac]Ac-PSMA-I&T compared to [177Lu]Lu-PSMA-I&T underlines the therapeutic potential for the treatment of PCa. [ABSTRACT FROM AUTHOR]

Published

2022

38. An empirical model of proton RBE based on the linear correlation between x‐ray and proton radiosensitivity.

Author

Flint, David B., Ruff, Chase E., Bright, Scott J., Yepes, Pablo, Wang, Qianxia, Manandhar, Mandira, Kacem, Mariam Ben, Turner, Broderick X., Martinus, David K. J., Shaitelman, Simona F., and Sawakuchi, Gabriel O.

Subjects

*PROTON beams, *LINEAR energy transfer, *RADIATION tolerance, *PROTONS, *DNA repair, *X-rays

Abstract

Background: Proton relative biological effectiveness (RBE) is known to depend on physical factors of the proton beam, such as its linear energy transfer (LET), as well as on cell‐line specific biological factors, such as their ability to repair DNA damage. However, in a clinical setting, proton RBE is still considered to have a fixed value of 1.1 despite the existence of several empirical models that can predict proton RBE based on how a cell's survival curve (linear‐quadratic model [LQM]) parameters α and β vary with the LET of the proton beam. Part of the hesitation to incorporate variable RBE models in the clinic is due to the great noise in the biological datasets on which these models are trained, often making it unclear which model, if any, provides sufficiently accurate RBE predictions to warrant a departure from RBE = 1.1. Purpose: Here, we introduce a novel model of proton RBE based on how a cell's intrinsic radiosensitivity varies with LET, rather than its LQM parameters. Methods and materials: We performed clonogenic cell survival assays for eight cell lines exposed to 6 MV x‐rays and 1.2, 2.6, or 9.9 keV/µm protons, and combined our measurements with published survival data (n = 397 total cell line/LET combinations). We characterized how radiosensitivity metrics of the form DSF%, (the dose required to achieve survival fraction [SF], e.g., D10%) varied with proton LET, and calculated the Bayesian information criteria associated with different LET‐dependent functions to determine which functions best described the underlying trends. This allowed us to construct a six‐parameter model that predicts cells' proton survival curves based on the LET dependence of their radiosensitivity, rather than the LET dependence of the LQM parameters themselves. We compared the accuracy of our model to previously established empirical proton RBE models, and implemented our model within a clinical treatment plan evaluation workflow to demonstrate its feasibility in a clinical setting. Results: Our analyses of the trends in the data show that DSF% is linearly correlated between x‐rays and protons, regardless of the choice of the survival level (e.g., D10%, D37%, or D50% are similarly correlated), and that the slope and intercept of these correlations vary with proton LET. The model we constructed based on these trends predicts proton RBE within 15%–30% at the 68.3% confidence level and offers a more accurate general description of the experimental data than previously published empirical models. In the context of a clinical treatment plan, our model generally predicted higher RBE‐weighted doses than the other empirical models, with RBE‐weighted doses in the distal portion of the field being up to 50.7% higher than the planned RBE‐weighted doses (RBE = 1.1) to the tumor. Conclusions: We established a new empirical proton RBE model that is more accurate than previous empirical models, and that predicts much higher RBE values in the distal edge of clinical proton beams. [ABSTRACT FROM AUTHOR]

Published

2022

39. Effect of boron compounds on the biological effectiveness of proton therapy.

Author

Manandhar, Mandira, Bright, Scott J., Flint, David B., Martinus, David K. J., Kolachina, Rishab V., Kacem, Mariam B., Titt, Uwe, Martin, Tioga J., Lee, Chad L., Morrison, Kendall, Shaitelman, Simona F., and Sawakuchi, Gabriel O.

Subjects

*PROTON beams, *LINEAR energy transfer, *NUCLEAR reactions, *BORON compounds, *PROTON therapy, *ALPHA rays

Abstract

Purpose: We assessed whether adding sodium borocaptate (BSH) or 4‐borono‐l‐phenylalanine (BPA) to cells irradiated with proton beams influenced the biological effectiveness of those beams against prostate cancer cells to investigate if the alpha particles generated through proton–boron nuclear reactions would be sufficient to enhance the biological effectiveness of the proton beams. Methods: We measured clonogenic survival in DU145 cells treated with 80.4‐ppm BSH or 86.9‐ppm BPA, or their respective vehicles, after irradiation with 6‐MV X‐rays, 1.2‐keV/μm (low linear energy transfer [LET]) protons, or 9.9‐keV/μm (high‐LET) protons. We also measured γH2AX and 53BP1 foci in treated cells at 1 and 24 h after irradiation with the same conditions. Results: We found that BSH radiosensitized DU145 cells across all radiation types. However, no difference was found in relative radiosensitization, characterized by the sensitization enhancement ratio or the relative biological effectiveness, for vehicle‐ versus BSH‐treated cells. No differences were found in numbers of γH2AX or 53BP1 foci or γH2AX/53BP1 colocalized foci for vehicle‐ versus BSH‐treated cells across radiation types. BPA did not radiosensitize DU145 cells nor induced any significant differences when comparing vehicle‐ versus BPA‐treated cells for clonogenic cell survival or γH2AX and 53BP1 foci or γH2AX/53BP1 colocalized foci. Conclusions: Treatment with 11B, at concentrations of 80.4 ppm from BSH or 86.9 ppm from BPA, had no effect on the biological effectiveness of proton beams in DU145 prostate cancer cells. Our results agree with published theoretical calculations indicating that the contribution of alpha particles from such reactions to the total absorbed dose and biological effectiveness is negligible. We also found that BSH radiosensitized DU145 cells to X‐rays, low‐LET protons, and high‐LET protons but that the radiosensitization was not related to DNA damage. [ABSTRACT FROM AUTHOR]

Published

2022

40. A deep-learning-based surrogate model for Monte-Carlo simulations of the linear energy transfer in primary brain tumor patients treated with proton-beam radiotherapy

Author

(0000-0001-5007-1868) Starke, S., Kieslich, A. M., Palkowitsch, M., Hennings, F., (0000-0001-9550-9050) Troost, E. G. C., (0000-0003-1776-9556) Krause, M., Bensberg, J., Hahn, C., Heinzelmann, F., Bäumer, C., (0000-0002-9450-6859) Lühr, A., Timmermann, B., (0000-0002-7017-3738) Löck, S., (0000-0001-5007-1868) Starke, S., Kieslich, A. M., Palkowitsch, M., Hennings, F., (0000-0001-9550-9050) Troost, E. G. C., (0000-0003-1776-9556) Krause, M., Bensberg, J., Hahn, C., Heinzelmann, F., Bäumer, C., (0000-0002-9450-6859) Lühr, A., Timmermann, B., and (0000-0002-7017-3738) Löck, S.

Abstract

Objective: Neglecting variability in the relative biological effectiveness (RBE) in proton-beam therapy might result in unexpected side effects. Current research has indicated that the RBE is tightly associated with the dose-averaged linear energy transfer (LETd) of protons. Monte-Carlo (MC) simulations are currently considered the gold standard for LETd computations, but are computationally intensive and require exact models of the beam delivery device. We therefore explore whether neural networks (NNs) can serve as surrogate models of MC simulations for an accurate prediction of LETd based on the planned dose distribution and patient anatomy in the form of computed tomography (CT) images. Additionally, we evaluate the implications of using these NN models on established normal tissue complication probability (NTCP) models within a variable-RBE context. Approach: The predictive performance of three-dimensional NN architectures was evaluated using five-fold cross-validation on a large cohort of brain tumor patients (n=151). The best-performing model was identified and externally validated on patients from a different center (n=107). LETd predictions were compared to MC-simulated results in various clinically relevant regions of interest. Furthermore, we assessed the impact on normal tissue complication probability (NTCP) models by leveraging LETd predictions to derive RBE-weighted doses, using an established variable-RBE model (Wedenberg). Main results: We externally validated that NNs are able to approximate MC-based LETd maps solely based on the planned dose profile. Voxelwise root-mean-squared errors (RMSE) for the median LETd within the brain, brainstem, CTV, chiasm, lacrimal glands (ipsilateral/contralateral) and optic nerves (ipsilateral/contralateral) were 0.32, 0.83, 0.31, 0.71, 0.67, 1.00, 0.86 and 1.19 keV/µm, respectively. Although model predictions showed statistically significant differences from MC outputs, these did not translate to substantial change

Published

2024

41. Data publication: A deep-learning-based surrogate model for Monte-Carlo simulations of the linear energy transfer in primary brain tumor patients treated with proton-beam radiotherapy

Author

(0000-0001-5007-1868) Starke, S., Kieslich, A. M., Palkowitsch, M., Hennings, F., (0000-0001-9550-9050) Troost, E. G. C., (0000-0003-1776-9556) Krause, M., Bensberg, J., Hahn, C., Heinzelmann, F., Bäumer, C., (0000-0002-9450-6859) Lühr, A., Timmermann, B., (0000-0002-7017-3738) Löck, S., (0000-0001-5007-1868) Starke, S., Kieslich, A. M., Palkowitsch, M., Hennings, F., (0000-0001-9550-9050) Troost, E. G. C., (0000-0003-1776-9556) Krause, M., Bensberg, J., Hahn, C., Heinzelmann, F., Bäumer, C., (0000-0002-9450-6859) Lühr, A., Timmermann, B., and (0000-0002-7017-3738) Löck, S.

Abstract

This repository contains the outputs and result data of our deep-learning-based experiments for the approximation of Monte-Carlo-simulated linear energy transfer distributions, which build the foundation for the corresponding article. The Pytorch checkpoint of our finally chosen SegResNet architecture trained on the UPTD dose distributions is located at dd_pbs/Dose-LETd/clip_let_below_0.04/segresnet/all_trainvalid_data/training/lightning_logs/version_6358843/checkpoints/last.ckpt. Moreover, we provide an exemplary data sample from a water phantom for trying our analysis pipeline. Update: In this new version we added results of the gamma analyses and the results obtained when trained on the same data as the above model with the difference that we did not clip Monte-Carlo-simulated LET maps as requested during the review process.

Published

2024

42. Increased cell killing effect in neutron capture enhanced proton beam therapy.

Author

Shiba S, Shimo T, Yamanaka M, Yagihashi T, Sakai M, Ohno T, Tokuuye K, and Omura M

Subjects

Humans, Cell Line, Tumor, Monte Carlo Method, Neutrons, Relative Biological Effectiveness, Cell Survival radiation effects, Cell Survival drug effects, Boron pharmacology, Proton Therapy methods, Boron Neutron Capture Therapy methods

Abstract

Thermal neutrons generated in the body during proton beam therapy (PBT) can be used to cause boron neutron capture reactions and have recently been proposed as neutron capture enhanced PBT (NCEPBT). However, the cell killing effect of NCEPBT remains underexplored. Here, we show an increase in the cell killing effect of NCEPBT. Using Monte Carlo simulations, we showed that neutrons generated by proton beam irradiation are uniformly spread on tissue culture plates. Human salivary gland tumor cell line (HSG), human osteosarcoma cell line (MG63), human tongue squamous cell carcinoma cell line (SAS), and human malignant melanoma cell line (G-361) were irradiated with X-rays, proton beams, and proton beams with 10 B-enriched boronophenylalanine (boron concentration of 20 and 80 ppm). The relative biological effectiveness (RBE) values of proton beams alone, proton beams with 20 ppm boron, and proton beams with 80 ppm boron for HSG, MG63, SAS, and G-361 were 1.02, 1.07, and 1.23; 1.01, 1.08, and 1.44; 1.05, 1.09, and 1.46; and 1.04, 1.13, and 1.63, respectively. NCEPBT with high boron concentration showed high RBE and a high sensitizing effect. Our results confirm an increase in the cell killing effect of NCEPBT, should aid in its clinical use, and warrant its further investigation., Competing Interests: Declarations Competing interests Boronophenylalanine used in this study was provided by Stella Pharma Corporation (Japan). Tatsuya Ohno received research funding from Hitachi. All other authors declare no conflict of interest., (© 2024. The Author(s).)

Published

2024

43. MIMC- β : microdosimetric assessment method for internal exposure of β -emitters based on mesh-type cell cluster model.

Author

Wang Y, Tang B, Li X, Kong X, Wang X, Yan K, Tu Y, and Sun L

Subjects

Humans, Beta Particles, Radiometry instrumentation, Radiometry methods, Models, Biological, Cell Line, Relative Biological Effectiveness, Monte Carlo Method

Abstract

The method combining Monte Carlo (MC) simulation and mesh-type cell models provides a way to accurately assess the cellular dose induced by β -emitters. Although this approach allows for a specific evaluation of various nuclides and cell type combinations, the associated time cost for obtaining results is relatively high. In this work, we propose a Microdosimetric assessment method for Internal exposure of β -emitters based on Mesh-type Cell cluster models (abbreviated as MIMC- β ). This approach is applied to evaluate the dose in various types of cells (human bronchial epithelial cells, BEAS-2B; normal human liver cells, L-O2; and normal human small intestine epithelial cells, FHs74Int) exposed to β -emitters. Furthermore, microdosimetric quantity based on the cell cluster model are employed to estimate the relative biological effectiveness (RBE) of β -emitters. The results indicate that this method can accurately and rapidly predict cellular doses caused by different types of β -emitters, significantly mitigating the efficiency challenges associated with directly employing MC to estimate the overall dose of the mesh-type cell cluster model. In comparison with results obtained from direct simulations of uniform administration of β - sources using PHITS for validation, the cellular cluster overall S -values obtained through MIMC- β show discrepancies mostly below 5%, with the minimum deviation reaching 1.35%. Small sampling sizes within the cell nucleus led to larger average lineal energies. In comparison to C-14, the differences in cellular cluster average lineal energy for Cs-134, Cs-137, and I-131 are negligible, resulting in close numerical estimations of RBE based on lineal energy. The MIMC- β can be extended to diverse cell types and β -emitters. Additionally, the RBE assessment based on the cell cluster model offers valuable insights for predicting radiobiological damage resulting from internal exposure by β -emitters. This method is expected to find applicability in various realistic scenarios, including radiation protection and radioligand therapy., (© 2024 Institute of Physics and Engineering in Medicine. All rights, including for text and data mining, AI training, and similar technologies, are reserved.)

Published

2024

44. Beyond a constant proton relative biological effectiveness: A survey of clinical and research perspectives among proton institutions in Europe and the United States.

Author

Ödén J, Eriksson K, Kaushik S, and Traneus E

Abstract

Purpose: Although proton relative biological effectiveness (RBE) depends on factors like linear energy transfer (LET), tissue properties, dose, and biological endpoint, a constant RBE of 1.1 is recommended in clinical practice. This study surveys proton institutions to explore activities using functionalities beyond a constant proton RBE., Methods: Research versions of RayStation integrate functionalities considering variable proton RBE, LET, proton track-ends, and dirty dose. A survey of 19 institutions in Europe and the United States, with these functionalities available, investigated clinical adoption and research prospects using a 25-question online questionnaire., Results: Of the 16 institutions that responded (84% response rate), 13 were clinically active. These clinical institutions prescribe RBE = 1.1 but also employ planning strategies centered around special beam arrangements to address potentially enhanced RBE effects in serially structured organs at risk (OARs). Clinical plan evaluation encompassed beam angles/spot position (69%), dose-averaged LET (LET d ) (46%), and variable RBE distributions (38%). High ratings (discrete scale: 1-5) were reported for the research functionalities using linear LET d -RBE models, LET d , track-end frequency and dirty dose (averages: 4.0-4.8), while LQ-based phenomenological RBE models dependent on LET d scored lower for optimization (average: 2.2) but congruent for evaluation (average: 4.1). The institutions preferred LET reported as LET d (94%), computed in unit-density water (56%), for all protons (63%), and lean toward LET d -based phenomenological RBE models for clinical use (> 50%)., Conclusions: Proton institutions recognize RBE variability but adhere to a constant RBE while actively mitigating potential enhancements, particularly in serially structured OARs. Research efforts focus on planning techniques that utilize functionalities beyond a constant RBE, emphasizing standardized LET and RBE calculations to facilitate their adoption in clinical practice and improve clinical data collection. LET d calculated in unit-density water for all protons as input to adaptable phenomenological RBE models was the most suggested approach, aligning with predominant clinical LET and variable RBE reporting., (© 2024 The Author(s). Journal of Applied Clinical Medical Physics published by Wiley Periodicals LLC on behalf of American Association of Physicists in Medicine.)

Published

2024

45. Biological effective dose as a predictor of local tumor control in stereotactic radiosurgery treated parasellar meningioma patients.

Author

Shaaban A, Pham D, Tos SM, Mantziaris G, Schlesinger D, and Sheehan JP

Subjects

Humans, Female, Male, Middle Aged, Retrospective Studies, Aged, Follow-Up Studies, Relative Biological Effectiveness, Treatment Outcome, Prognosis, Meningioma surgery, Meningioma radiotherapy, Meningioma pathology, Radiosurgery methods, Meningeal Neoplasms surgery, Meningeal Neoplasms radiotherapy, Meningeal Neoplasms pathology

Abstract

Introduction: The radio-surgical literature increasingly uses biological effective dose (BED) as a replacement for absorbed dose to analyze outcome of stereotactic radiosurgery (SRS). There are as yet no studies which specifically investigate the association of BED to local tumor control in para-sellar meningioma., Methods: we did a retrospective analysis of patients underwent stereotactic radiosurgery (SRS) for para-sellar meningioma during the period of 1995-2022. Demographic, clinical, SRS parameters, and outcome data were collected. The target margin BED with and without a model for sub-lethal repair was calculated, as well as a ratio of BED at the target margin to the absorbed dose at the target margin. Factors related to local control were further analyzed., Results: The study was comprised of 91 patients, 20 (22.0%) and 71 (78.0%) of whom were male and female, respectively. The median age was 55.0 (interquartile range Q1, Q3:47.5,65.5years). 34 (37%) patients had a resection of their meningioma prior to SRS. The median interval from SRS to last clinical follow up or progression was 89 months. 13 (14.3%) patients were found to have progression. 3-, 5- and 10-years local tumor control were 98%, 92% and 77%, respectively. In cox univariate analysis, the following factors were significant: Number of prior surgical resections (Hazard Ratio [HR] = 1.82, 95% CI = 1.08-3.05, p = 0.024), BED (HR = 0.96, 95% CI = 0.92-1.00, p = 0.03), and BED/margin (HR = 0.44, 95% CI = 0.21-0.92, p = 0.028). A BED threshold above 68 Gy was associated significantly with tumor control (P = 0.04)., Conclusion: BED and BED /margin absorbed dose ratio can be predictors of local control after SRS in parasellar meningioma. Optimizing the BED above 68Gy 2.47 may afford better long-term tumor control., (© 2024. The Author(s).)

Published

2024

46. Biological effectiveness of uniform and nonuniform dose distributions in radiotherapy for tumors with intermediate oxygen levels.

Author

Chvetsov AV and Pugachev A

Subjects

Humans, Neoplasms radiotherapy, Models, Biological, Relative Biological Effectiveness, Tumor Hypoxia radiation effects, Dose-Response Relationship, Radiation, Cell Hypoxia, Computer Simulation, Cell Survival radiation effects, Oxygen metabolism, Carcinoma, Non-Small-Cell Lung radiotherapy, Radiotherapy Dosage, Lung Neoplasms radiotherapy

Abstract

Objective . We propose a criterion of biological effectiveness of nonuniform hypoxia-targeted dose distributions in heterogeneous hypoxic tumors based on equivalent uniform aerobic dose (EUAD). We demonstrate the utility of this criterion by applying it to the model problems in radiotherapy for tumors with different levels of oxygen enhancement ratio (OER) and different degrees of dose nonuniformity. Approach . The EUAD is defined as the uniform dose that, under well-oxygenated conditions, produces equal integrated survival of clonogenic cells in radiotherapy for heterogeneous hypoxic tumors with a non-uniform dose distribution. We define the dose nonuniformity effectiveness (DNE) in heterogeneous tumors as the ratio of the EUAD( D N ) for a non-uniform distribution D N and the reference EUAD( D U ) for the uniform dose distribution D U with equal integral tumor dose. The DNE concept is illustrated in a radiotherapy model problem for non-small cell lung cancer treated with hypoxia targeted dose escalation. A two-level cell population tumor model was used to consider the hypoxic and oxygenated tumor cells. Results . Theoretical analysis of the DNE shows that the entire region of the OER can be separated in two regions by a threshold OER th : (1) OER > OER th where DNE > 1 indicating higher effectiveness of nonuniform dose distributions and (2) OER < OER th where DNE < 1 indicating higher effectiveness of uniform dose distributions. Our simulations show that the value of the threshold OER th in radiotherapy with conventional fractionation is significant in the range of about 1.2-1.6 depending on selected radiotherapy parameters. In general, the OER th increases with reoxygenation rate, relative hypoxic volume and dose escalation factor. The threshold value of OER th is smaller of about 1.1 for hypofractionated radiotherapy. Significance . The analysis of dose distributions using the DNE shows that the uniform dose distributions may improve biological cell killing effect in heterogeneous tumors with intermediate oxygen levels compared to targeted nonuniform dose distribution., (© 2024 IOP Publishing Ltd. All rights, including for text and data mining, AI training, and similar technologies, are reserved.)

Published

2024

47. Interpreting the biological effects of protons as a function of physical quantity: linear energy transfer or microdosimetric lineal energy spectrum?

Author

Guan F, Bronk L, Kerr M, Li Y, Braby LA, Sobieski M, Wang X, Zhang X, Stephan C, Grosshans DR, and Mohan R

Subjects

Humans, Radiometry methods, Cell Line, Tumor, Dose-Response Relationship, Radiation, DNA Damage, Linear Energy Transfer, Protons, Relative Biological Effectiveness

Abstract

The choice of appropriate physical quantities to characterize the biological effects of ionizing radiation has evolved over time coupled with advances in scientific understanding. The basic hypothesis in radiation dosimetry is that the energy deposited by ionizing radiation initiates all the consequences of exposure in a biological sample (e.g., DNA damage, reproductive cell death). Physical quantities defined to characterize energy deposition have included dose, a measure of the mean energy imparted per unit mass of the target, and linear energy transfer (LET), a measure of the mean energy deposition per unit distance that charged particles traverse in a medium. The primary advantage of using the "dose and LET" physical system is its relative simplicity, especially for presenting and recording results. Inclusion of additional information such as the energy spectrum of charged particles renders this approach adequate to describe the biological effects of large dose levels from homogeneous sources. The primary disadvantage of this system is that it does not provide a unique description of the stochastic nature of radiation interactions. We and others have used dose-averaged LET (LET d ) as a correlative physical quantity to the relative biological effectiveness (RBE) of proton beams. This approach is based on established experimental findings that proton RBE increases with LET d . However, this approach might not be applicable to intensity-modulated proton therapy or other applications in which the proton energy spectrum is highly heterogeneous. In the current study, we irradiated cancer cells with scanning proton beams with identical LET d (3.4 keV/µm) but arising from two different proton energy/LET spectra (a narrow spectrum in group 1 and a widespread heterogeneous spectrum in group 2). Clonogenic survival after irradiation revealed significant differences in RBE at any cell surviving fraction: e.g., at a surviving fraction of 0.1, the RBE was 0.97 ± 0.03 in group 1 and 1.16 ± 0.04 in group 2 (p≤0.01), validating our hypothesis that LET d alone may not adequately indicate proton RBE. Further analysis showed that microdosimetric spectrum (the probability density function of the stochastic physical quantity lineal energy y) was helpful for interpreting observed differences in biological effects. However, more accurate use of microdosimetric spectrum to quantify RBE requires a cell line-specific mechanistic model., (© 2024. The Author(s).)

Published

2024

48. A model-based risk-minimizing proton treatment planning concept for brain injury prevention in low-grade glioma patients.

Author

Sallem H, Harrabi S, Traneus E, Herfarth K, Debus J, and Bauer J

Abstract

Purpose: Late-occurring contrast-enhancing brain lesions (CEBLs) have been observed on MRI follow-up in low-grade glioma (LGG) patients post-proton therapy. Predictive risk-models for this endpoint identified a dose-averaged linear energy transfer (LET d )-dependent proton relative biological effectiveness (RBE) effect on CEBL occurrence and increased radiosensitivity of the cerebral periventricular region (VP 4mm ). This work aimed to design a stable risk-minimizing treatment planning (TP) concept addressing these intertwined risk factors through a classically formulated optimization problem., Material and Methods: The concept was developed in RayStation-research 11B IonPG featuring a variable-RBE-based optimizer involving 20 LGG patients with varying target volume localizations and risk-factor contributions. Classical cost functions penalizing dose, dose-volume-histogram points, and equivalent uniform dose were used to formulate the optimization problem, and a new set of structures was introduced to actively spare the VP 4mm , control high LET d regions, and de-escalate the dose outside the gross tumor volume. Target volume coverage and organ-at-risk sparing were robustly evaluated, and Normal Tissue Complication Probabilities (NTCP) for CEBL occurrence were quantified., Results: The concept yielded stable optimization outcomes for all considered subjects. Risk hot spots were successfully mitigated, and an NTCP reduction of up to 79 % was observed compared to conventional TP while maintaining target coverage, demonstrating the feasibility of the chosen model-based approach., Conclusion: With the proposed TP protocol, we close the gap between predictive risk-modeling and practical risk-mitigation in the clinic and provide a concept for CEBL avoidance with the potential to advance treatment precision for LGG patients., Competing Interests: Declaration of competing interest JD has received grants from RaySearch Laboratories AB; Vision RT Limited; Merck Serono GmbH; Siemens Healthcare GmbH; PTW-Freiburg Dr. Pychlau GmbH; Accuray Incorporated. HS, SH, ET, KH, JB have no known competing financial or personal relationships to declare., (Copyright © 2024 The Author(s). Published by Elsevier B.V. All rights reserved.)

Published

2024

49. Comparison of two biologically effective dose calculation models applied to single fraction stereotactic radiosurgery.

Author

Cotrutz C, Levivier M, and Tuleasca C

Subjects

Humans, Relative Biological Effectiveness, Tumor Burden, Neuroma, Acoustic radiotherapy, Neuroma, Acoustic surgery, Radiosurgery methods, Radiotherapy Planning, Computer-Assisted methods, Radiotherapy Dosage

Abstract

Background: Recent studies suggest strong correlations between Biologically Effective Doses (BED) and single fraction stereotactic radiosurgery treatment outcomes, as demonstrated for vestibular schwannomas (VS), arterio-venous malformations and pituitary adenomas. The BEDs calculated in these studies consider an uniform dose delivery where the spatio-temporal aspects of dose delivery were neglected., Purpose: The aim of the study is to quantify the discrepancies between the BED values calculated with a simplified model of uniform dose delivery against the more complex model that incorporates the temporo-spatial incrementation of dose delivery and the bi-exponential effect of the sub-lethal damage repair., Methods: A software tool that computes the BED distributions based on individual isocenter dose matrices extracted from the GammaPlan (Elekta) treatment planning was developed. Two cohorts 5 VS and 5 jugular foramen schwannoma cases of various tumor volumes and isocenter number were utilized to benchmark the method. Their BEDs covering 98% of tumor volumes were compared against those determined with the uniform delivery model., Results: The BEDs covering 98% of the tumor volumes as calculated with both models show an approximately linear dependency with the treatment time. For all studied cases, the uniform delivery model overestimates the BEDs calculated with the full spatio-temporal delivery model. This discrepancy seems to accentuate with the tumor volume and treatment complexity., Conclusions: Despite their resemblance, the BED distributions provide a plethora of BED measures more suitable to characterize clinical outcomes than the unique peripheral BED value calculated with the simplified model of uniform dose delivery., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Associazione Italiana di Fisica Medica e Sanitaria. Published by Elsevier Ltd. All rights reserved.)

Published

2024

50. LET-based approximation of the microdosimetric kinetic model for proton radiotherapy.

Author

Parisi A, Furutani KM, Sato T, and Beltran CJ

Subjects

Kinetics, Monte Carlo Method, Radiometry, Humans, Models, Biological, Animals, Radiotherapy Planning, Computer-Assisted methods, Linear Energy Transfer, Proton Therapy methods, Relative Biological Effectiveness

Abstract

Background: Phenomenological relative biological effectiveness (RBE) models for proton therapy, based on the dose-averaged linear energy transfer (LET), have been developed to address the apparent RBE increase towards the end of the proton range. The results of these phenomenological models substantially differ due to varying empirical assumptions and fitting functions. In contrast, more theory-based approaches are used in carbon ion radiotherapy, such as the microdosimetric kinetic model (MKM). However, implementing microdosimetry-based models in LET-based proton therapy treatment planning systems poses challenges., Purpose: This work presents a LET-based version of the MKM that is practical for clinical use in proton radiotherapy., Methods: At first, we derived an approximation of the Mayo Clinic Florida (MCF) MKM for relatively-sparsely ionizing radiation such as protons. The mathematical formalism of the proposed model is equivalent to the original MKM, but it maintains some key features of the MCF MKM, such as the determination of model parameters from measurable cell characteristics. Subsequently, we carried out Monte Carlo calculations with PHITS in different simulated scenarios to establish a heuristic correlation between microdosimetric quantities and the dose averaged LET of protons., Results: A simple allometric function was found able to describe the relationship between the dose-averaged LET of protons and the dose-mean lineal energy, which includes the contributions of secondary particles. The LET-based MKM was used to model the in vitro clonogenic survival RBE of five human and rodent cell lines (A549, AG01522, CHO, T98G, and U87) exposed to pristine and spread-out Bragg peak (SOBP) proton beams. The results of the LET-based MKM agree well with the biological data in a comparable or better way with respect to the other models included in the study. A sensitivity analysis on the model results was also performed., Conclusions: The LET-based MKM integrates the predictive theoretical framework of the MCF MKM with a straightforward mathematical description of the RBE based on the dose-averaged LET, a physical quantity readily available in modern treatment planning systems for proton therapy., (© 2024 American Association of Physicists in Medicine.)

Published

2024