Your search keyword '"Radiotherapy Dosage"' showing total 114,562 results

1. Simulation study of protoacoustics as a real‐time in‐line dosimetry tool for FLASH proton therapy

Author

Kim, Kaitlyn, Pandey, Prabodh Kumar, Gonzalez, Gilberto, Chen, Yong, and Xiang, Liangzhong

Subjects

Medical and Biological Physics, Physical Sciences, Bioengineering, Cancer, Radiation Oncology, Proton Therapy, Radiometry, Monte Carlo Method, Radiotherapy Dosage, Acoustics, Time Factors, Computer Simulation, Feasibility Studies, Humans, flash proton therapy, in vivo dosimetry, ionoacoustics, protoacoustics, Other Physical Sciences, Biomedical Engineering, Oncology and Carcinogenesis, Nuclear Medicine & Medical Imaging, Biomedical engineering, Medical and biological physics

Abstract

BackgroundApplying ultra-high dose rates to radiation therapy, otherwise known as FLASH, has been shown to be just as effective while sparing more normal tissue compared to conventional radiation therapy. However, there is a need for a dosimeter that is able to detect such high instantaneous dose, particularly in vivo. To fulfill this need, protoacoustics is introduced, which is an in vivo range verification method with submillimeter accuracy.PurposeThe purpose of this work is to demonstrate the feasibility of using protoacoustics as a method of in vivo real-time monitoring during FLASH proton therapy and investigating the resulting protoacoustic signal when dose per pulse and pulsewidth are varied through multiple simulation studies.MethodsThe dose distribution of a proton pencil beam was calculated through a Monte Carlo toolbox, TOPAS. Next, the k-Wave toolbox in MATLAB was used for performing protoacoustic simulations, where the initial proton dose deposition was inputted to model acoustic propagations, which were also used for reconstructions. Simulations involving the manipulation of the dose per pulse and pulsewidth were performed, and the temporal and spatial resolution for protoacoustic reconstructions were investigated as well. A 3D reconstruction was performed with a multiple beam spot profile to investigate the spatial resolution as well as determine the feasibility of 3D imaging with protoacoustics.ResultsOur results showed consistent linearity in the increasing dose-per-pulse, even up to rates considered for FLASH. The simulations and reconstructions were performed for a range of pulsewidths from 0.1 to 10 μs. The results show the characteristics of the proton beam after convolving the protoacoustic signal with the varying pulsewidths. 3D reconstruction was successfully performed with each beam being distinguishable using an 8 cm × 8 cm planar array. These simulation results show that measurements using protoacoustics has the potential for in vivo dosimetry in FLASH therapy during patient treatments in real time.ConclusionThrough this simulation study, the use of protoacoustics in FLASH therapy was verified and explored through observations of varying parameters, such as the dose per pulse and pulsewidth. 2D and 3D reconstructions were also completed. This study shows the significance of using protoacoustics and provides necessary information, which can further be explored in clinical settings.

Published

2024

2. MRI-only based material mass density and relative stopping power estimation via deep learning for proton therapy: a preliminary study.

Author

Goette, Matthew, Lei, Yang, Mao, Hui, Bradley, Jeffrey, Liu, Tian, Zhou, Jun, Sudhyadhom, Atchar, Yang, Xiaofeng, Gao, Yuan, Chang, Chih-Wei, Mandava, Sagar, Marants, Raanan, and Scholey, Jessica

Subjects

Magnetic Resonance Imaging, Deep Learning, Phantoms, Imaging, Proton Therapy, Humans, Animals, Swine, Radiotherapy Planning, Computer-Assisted, Tomography, X-Ray Computed, Radiotherapy Dosage

Abstract

Magnetic Resonance Imaging (MRI) is increasingly being used in treatment planning due to its superior soft tissue contrast, which is useful for tumor and soft tissue delineation compared to computed tomography (CT). However, MRI cannot directly provide mass density or relative stopping power (RSP) maps, which are required for calculating proton radiotherapy doses. Therefore, the integration of artificial intelligence (AI) into MRI-based treatment planning to estimate mass density and RSP directly from MRI has generated significant interest. A deep learning (DL) based framework was developed to establish a voxel-wise correlation between MR images and mass density as well as RSP. To facilitate the study, five tissue substitute phantoms were created, representing different tissues such as skin, muscle, adipose tissue, 45% hydroxyapatite (HA), and spongiosa bone. The composition of these phantoms was based on information from ICRP reports. Additionally, two animal tissue phantoms, simulating pig brain and liver, were prepared for DL training purposes. The phantom study involved the development of two DL models. The first model utilized clinical T1 and T2 MRI scans as input, while the second model incorporated zero echo time (ZTE) MRI scans. In the patient application study, two more DL models were trained: one using T1 and T2 MRI scans as input, and another model incorporating synthetic dual-energy computed tomography (sDECT) images to provide accurate bone tissue information. The DECT empirical model was used as a reference to evaluate the proposed models in both phantom and patient application studies. The DECT empirical model was selected as the reference for evaluating the proposed models in both phantom and patient application studies. In the phantom study, the DL model based on T1, and T2 MRI scans demonstrated higher accuracy in estimating mass density and RSP for skin, muscle, adipose tissue, brain, and liver. The mean absolute percentage errors (MAPE) were 0.42%, 0.14%, 0.19%, 0.78%, and 0.26% for mass density, and 0.30%, 0.11%, 0.16%, 0.61%, and 0.23% for RSP, respectively. The DL model incorporating ZTE MRI further improved the accuracy of mass density and RSP estimation for 45% HA and spongiosa bone, with MAPE values of 0.23% and 0.09% for mass density, and 0.19% and 0.07% for RSP, respectively. These results demonstrate the feasibility of using an MRI-only approach combined with DL methods for mass density and RSP estimation in proton therapy treatment planning. By employing this approach, it is possible to obtain the necessary information for proton radiotherapy directly from MRI scans, eliminating the need for additional imaging modalities.

Published

2024

3. A quantitative framework for patient-specific collision detection in proton therapy.

Author

Northway, Stephen, Vallejo, Bailey, Liu, Lawrence, Hansen, Emily, Tang, Shikui, Mah, Dennis, MacEwan, Iain, Chang, Chang, and Urbanic, James

Subjects

collision detection, lateral penumbra, proton therapy, Humans, Proton Therapy, Protons, Algorithms, Radiotherapy Planning, Computer-Assisted, Radiotherapy Dosage

Abstract

BACKGROUND: Beam modifying accessories for proton therapy often need to be placed in close proximity of the patient for optimal dosimetry. However, proton treatment units are larger in size and as a result the planned treatment geometry may not be achievable due to collisions with the patient. A framework that can accurately simulate proton treatment geometry is desired. PURPOSE: A quantitative framework was developed to model patient-specific proton treatment geometry, minimize air gap, and avoid collisions. METHODS: The patients external contour is converted into the International Electrotechnique Commission (IEC) gantry coordinates following the patients orientation and each beams gantry and table angles. All snout components are modeled by three-dimensional (3D) geometric shapes such as columns, cuboids, and frustums. Beam-specific parameters such as isocenter coordinates, snout type and extension are used to determine if any point on the external contour protrudes into the various snout components. A 3D graphical user interface is also provided to the planner to visualize the treatment geometry. In case of a collision, the frameworks analytic algorithm quantifies the maximum protrusion of the external contour into the snout components. Without a collision, the framework quantifies the minimum distance of the external contour from the snout components and renders a warning if such distance is less than 5 cm. RESULTS: Three different snout designs are modeled. Examples of potential collision and its aversion by snout retraction are demonstrated. Different patient orientations, including a sitting treatment position, as well as treatment plans with multiple isocenters, are successfully modeled in the framework. Finally, the dosimetric advantage of reduced air gap enabled by this framework is demonstrated by comparing plans with standard and reduced air gaps. CONCLUSION: Implementation of this framework reduces incidence of collisions in the treatment room. In addition, it enables the planners to minimize the air gap and achieve better plan dosimetry.

Published

2024

4. Antitumor Effect by Either FLASH or Conventional Dose Rate Irradiation Involves Equivalent Immune Responses.

Author

Almeida, Aymeric, Godfroid, Céline, Leavitt, Ron, Montay-Gruel, Pierre, Petit, Benoit, Romero, Jackeline, Ollivier, Jonathan, Meziani, Lydia, Sprengers, Kevin, Paisley, Ryan, Grilj, Veljko, Romero, Pedro, Vozenin, Marie-Catherine, and Limoli, Charles

Subjects

Animals, Mice, Neoplasms, Lung, Radiotherapy Dosage, Tumor Microenvironment

Abstract

PURPOSE: The capability of ultrahigh dose rate FLASH radiation therapy to generate the FLASH effect has opened the possibility to enhance the therapeutic index of radiation therapy. The contribution of the immune response has frequently been hypothesized to account for a certain fraction of the antitumor efficacy and tumor kill of FLASH but has yet to be rigorously evaluated. METHODS AND MATERIALS: To investigate the immune response as a potentially important mechanism of the antitumor effect of FLASH, various murine tumor models were grafted either subcutaneously or orthotopically into immunocompetent mice or in moderately and severely immunocompromised mice. Mice were locally irradiated with single dose (20 Gy) or hypofractionated regimens (3 × 8 or 2 × 6 Gy) using FLASH (≥2000 Gy/s) and conventional (CONV) dose rates (0.1 Gy/s), with/without anti-CTLA-4. Tumor growth was monitored over time and immune profiling performed. RESULTS: FLASH and CONV 20 Gy were isoeffective in delaying tumor growth in immunocompetent and moderately immunodeficient hosts and increased tumor doubling time to >14 days versus >7 days in control animals. Similar observations were obtained with a hypofractionated scheme, regardless of the microenvironment (subcutaneous flank vs ortho lungs). Interestingly, in profoundly immunocompromised mice, 20 Gy FLASH retained antitumor activity and significantly increased tumor doubling time to >14 days versus >8 days in control animals, suggesting a possible antitumor mechanism independent of the immune response. Analysis of the tumor microenvironment showed similar immune profiles after both irradiation modalities with significant decrease of lymphoid cells by ∼40% and a corresponding increase of myeloid cells. In addition, FLASH and CONV did not increase transforming growth factor-β1 levels in tumors compared with unirradiated control animals. Furthermore, when a complete and long-lasting antitumor response was obtained (>140 days), both modalities of irradiation were able to generate a long-term immunologic memory response. CONCLUSIONS: The present results clearly document that the tumor responses across multiple immunocompetent and immunodeficient mouse models are largely dose rate independent and simultaneously contradict a major role of the immune response in the antitumor efficacy of FLASH. Therefore, our study indicates that FLASH is as potent as CONV in modulating antitumor immune response and can be used as an immunomodulatory agent.

Published

2024

5. Evaluating the Hounsfield unit assignment and dose differences between CT-based standard and deep learning-based synthetic CT images for MRI-only radiation therapy of the head and neck.

Author

Singhrao, Kamal, Dugan, Catherine, Calvin, Christina, Pelayo, Luis, Singer, Lisa, Yom, Sue, Chan, Jason, and Scholey, Jessica

Subjects

AI in radiation therapy, MRI-only radiation therapy, synthetic CT, Humans, Retrospective Studies, Deep Learning, Radiotherapy Planning, Computer-Assisted, Tomography, X-Ray Computed, Radiotherapy Dosage, Magnetic Resonance Imaging

Abstract

BACKGROUND: Magnetic resonance image only (MRI-only) simulation for head and neck (H&N) radiotherapy (RT) could allow for single-image modality planning with excellent soft tissue contrast. In the MRI-only simulation workflow, synthetic computed tomography (sCT) is generated from MRI to provide electron density information for dose calculation. Bone/air regions produce little MRI signal which could lead to electron density misclassification in sCT. Establishing the dosimetric impact of this error could inform quality assurance (QA) procedures using MRI-only RT planning or compensatory methods for accurate dosimetric calculation. PURPOSE: The aim of this study was to investigate if Hounsfield unit (HU) voxel misassignments from sCT images result in dosimetric errors in clinical treatment plans. METHODS: Fourteen H&N cancer patients undergoing same-day CT and 3T MRI simulation were retrospectively identified. MRI was deformed to the CT using multimodal deformable image registration. sCTs were generated from T1w DIXON MRIs using a commercially available deep learning-based generator (MRIplanner, Spectronic Medical AB, Helsingborg, Sweden). Tissue voxel assignment was quantified by creating a CT-derived HU threshold contour. CT/sCT HU differences for anatomical/target contours and tissue classification regions including air (500 HU) were quantified. t-test was used to determine if sCT/CT HU differences were significant. The frequency of structures that had a HU difference > 80 HU (the CT window-width setting for intra-cranial structures) was computed to establish structure classification accuracy. Clinical intensity modulated radiation therapy (IMRT) treatment plans created on CT were retrospectively recalculated on sCT images and compared using the gamma metric. RESULTS: The mean ratio of sCT HUs relative to CT for air, adipose tissue, soft tissue, spongy and cortical bone were 1.7 ± 0.3, 1.1 ± 0.1, 1.0 ± 0.1, 0.9 ± 0.1 and 0.8 ± 0.1 (value of 1 indicates perfect agreement). T-tests (significance set at t = 0.05) identified differences in HU values for air, spongy and cortical bone in sCT images compared to CT. The structures with sCT/CT HU differences > 80 HU of note were the left and right (L/R) cochlea and mandible (>79% of the tested cohort), the oral cavity (for 57% of the tested cohort), the epiglottis (for 43% of the tested cohort) and the L/R TM joints (occurring > 29% of the cohort). In the case of the cochlea and TM joints, these structures contain dense bone/air interfaces. In the case of the oral cavity and mandible, these structures suffer the additional challenge of being positionally altered in CT versus MRI simulation (due to a non-MR safe immobilizing bite block requiring absence of bite block in MR). Finally, the epiglottis HU assignment suffers from its small size and unstable positionality. Plans recalculated on sCT yielded global/local gamma pass rates of 95.5% ± 2% (3 mm, 3%) and 92.7% ± 2.1% (2 mm, 2%). The largest mean differences in D95, Dmean , D50 dose volume histogram (DVH) metrics for organ-at-risk (OAR) and planning tumor volumes (PTVs) were 2.3% ± 3.0% and 0.7% ± 1.9% respectively. CONCLUSIONS: In this cohort, HU differences of CT and sCT were observed but did not translate into a reduction in gamma pass rates or differences in average PTV/OAR dose metrics greater than 3%. For sites such as the H&N where there are many tissue interfaces we did not observe large scale dose deviations but further studies using larger retrospective cohorts are merited to establish the variation in sCT dosimetric accuracy which could help to inform QA limits on clinical sCT usage.

Published

2024

6. A Novel Platform for Evaluating Dose Rate Effects on Oxidative Damage to Peptides: Toward a High-Throughput Method to Characterize the Mechanisms Underlying the FLASH Effect

Author

Gupta, Sayan, Inman, Jamie L, Chant, Jared De, Obst-Huebl, Lieselotte, Nakamura, Kei, Costello, Shawn M, Marqusee, Susan, Mao, Jian-Hua, Kunz, Louis, Paisley, Ryan, Vozenin, Marie-Catherine, Snijders, Antoine M, and Ralston, Corie Y

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Cancer, 1.1 Normal biological development and functioning, Generic health relevance, Animals, Neoplasms, Oxidative Stress, Peptides, Oxygen, Radiotherapy Dosage, Physical Sciences, Biological Sciences, Medical and Health Sciences, Oncology & Carcinogenesis, Oncology and carcinogenesis, Theoretical and computational chemistry, Epidemiology

Abstract

High dose rate radiation has gained considerable interest recently as a possible avenue for increasing the therapeutic window in cancer radiation treatment. The sparing of healthy tissue at high dose rates relative to conventional dose rates, while maintaining tumor control, has been termed the FLASH effect. Although the effect has been validated in animal models using multiple radiation sources, it is not yet well understood. Here, we demonstrate a new experimental platform for quantifying oxidative damage to protein sidechains in solution as a function of radiation dose rate and oxygen availability using liquid chromatography mass spectrometry. Using this reductionist approach, we show that for both X-ray and electron sources, isolated peptides in solution are oxidatively modified to different extents as a function of both dose rate and oxygen availability. Our method provides an experimental platform for exploring the parameter space of the dose rate effect on oxidative changes to proteins in solution.

Published

2023

7. Towards quantitative in vivo dosimetry using x‐ray acoustic computed tomography

Author

Sun, Leshan, Gonzalez, Gilberto, Pandey, Prabodh Kumar, Wang, Siqi, Kim, Kaitlyn, Limoli, Charles, Chen, Yong, and Xiang, Liangzhong

Subjects

Medical and Biological Physics, Physical Sciences, Bioengineering, Biomedical Imaging, Cancer, Clinical Research, Networking and Information Technology R&D (NITRD), Development of treatments and therapeutic interventions, 5.5 Radiotherapy and other non-invasive therapies, X-Rays, In Vivo Dosimetry, Tomography, X-Ray Computed, Radiometry, Phantoms, Imaging, Acoustics, Radiotherapy Dosage, in vivo dosimetry, model-based reconstruction, quantitative acoustic reconstruction, XACT, Other Physical Sciences, Biomedical Engineering, Oncology and Carcinogenesis, Nuclear Medicine & Medical Imaging, Biomedical engineering, Medical and biological physics

Abstract

BackgroundRadiation dosimetry is essential for radiation therapy (RT) to ensure that radiation dose is accurately delivered to the tumor. Despite its wide use in clinical intervention, the delivered radiation dose can only be planned and verified via simulation. This makes precision radiotherapy challenging while in-line verification of the delivered dose is still absent in the clinic. X-ray-induced acoustic computed tomography (XACT) has recently been proposed as an imaging tool for in vivo dosimetry.PurposeMost of the XACT studies focus on localizing the radiation beam. However, it has not been studied for its potential for quantitative dosimetry. The aim of this study was to investigate the feasibility of using XACT for quantitative in vivo dose reconstruction during radiotherapy.MethodsVarian Eclipse system was used to generate simulated uniform and wedged 3D radiation field with a size of 4 cm ×$ \times \ $ 4 cm. In order to use XACT for quantitative dosimetry measurements, we have deconvoluted the effects of both the x-ray pulse shape and the finite frequency response of the ultrasound detector. We developed a model-based image reconstruction algorithm to quantify radiation dose in vivo using XACT imaging, and universal back-projection (UBP) reconstruction is used as comparison. The reconstructed dose was calibrated before comparing it to the percent depth dose (PDD) profile. Structural similarity index matrix (SSIM) and root mean squared error (RMSE) are used for numeric evaluation. Experimental signals were acquired from 4 cm ×$ \times \ $ 4 cm radiation field created by Linear Accelerator (LINAC) at depths of 6, 8, and 10 cm beneath the water surface. The acquired signals were processed before reconstruction to achieve accurate results.ResultsApplying model-based reconstruction algorithm with non-negative constraints successfully reconstructed accurate radiation dose in 3D simulation study. The reconstructed dose matches well with the PDD profile after calibration in experiments. The SSIMs between the model-based reconstructions and initial doses are over 85%, and the RMSEs of model-based reconstructions are eight times lower than the UBP reconstructions. We have also shown that XACT images can be displayed as pseudo-color maps of acoustic intensity, which correspond to different radiation doses in the clinic.ConclusionOur results show that the XACT imaging by model-based reconstruction algorithm is considerably more accurate than the dose reconstructed by UBP algorithm. With proper calibration, XACT is potentially applicable to the clinic for quantitative in vivo dosimetry across a wide range of radiation modalities. In addition, XACT's capability of real-time, volumetric dose imaging seems well-suited for the emerging field of ultrahigh dose rate "FLASH" radiotherapy.

Published

2023

8. A study on inter-planner plan quality variability using a manual planning- or Lightning dose optimizer-approach for single brain lesions treated with the Gamma Knife® Icon™.

Author

Lee, Yongsook, Wieczorek, D, Chaswal, Vibha, Kotecha, Rupesh, Hall, Matthew, Tom, Martin, Mehta, Minesh, Gutierrez, Alonso, Tolakanahalli, Ranjini, and McDermott, Mike

Subjects

Gamma Knife® Icon™, Lightning, brain metastasis, fast inverse planning (FIP), manual forward planning, post-operative resection cavity, stereotactic radiosurgery, stereotactic radiotherapy, vestibular schwannoma, Humans, Radiosurgery, Lightning, Radiotherapy Planning, Computer-Assisted, Radiotherapy Dosage, Brain Neoplasms, Brain

Abstract

PURPOSE: The purpose of this study is to investigate inter-planner plan quality variability using a manual forward planning (MFP)- or fast inverse planning (FIP, Lightning)-approach for single brain lesions treated with the Gamma Knife® (GK) Icon™. METHODS: Thirty patients who were previously treated with GK stereotactic radiosurgery or radiotherapy were selected and divided into three groups (post-operative resection cavity, intact brain metastasis, and vestibular schwannoma [10 patients per group]). Clinical plans for the 30 patients were generated by multiple planners using FIP only (1), a combination of FIP and MFP (12), and MFP only (17). Three planners (Senior, Junior, and Novice) with varying experience levels re-planned the 30 patients using MFP and FIP (two plans per patient) with planning time limit of 60 min. Statistical analysis was performed to compare plan quality metrics (Paddick conformity index, gradient index, number of shots, prescription isodose line, target coverage, beam-on-time (BOT), and organs-at-risk doses) of MFP or FIP plans among three planners and to compare plan quality metrics between each planners MFP/FIP plans and clinical plans. Variability in FIP parameter settings (BOT, low dose, and target max dose) and in planning time among the planners was also evaluated. RESULTS: Variations in plan quality metrics of FIP plans among three planners were smaller than those of MFP plans for all three groups. Juniors MFP plans were the most comparable to the clinical plans, whereas Seniors and Novices MFP plans were superior and inferior, respectively. All three planners FIP plans were comparable or superior to the clinical plans. Differences in FIP parameter settings among the planners were observed. Planning time was shorter and variations in planning time among the planners were smaller for FIP plans in all three groups. CONCLUSIONS: The FIP approach is less planner dependent and more time-honored than the MFP approach.

Published

2023

9. 左侧乳腺癌保乳术后质子与光子放疗剂量学对比研究.

Author

龙腾飞, 闻妹, 马涛, 刘鹤飞, 柳璐, 李骁扬, and 张红雁

Abstract

Copyright of Chinese Journal of Clinical Healthcare is the property of Chinese Journal of Clinical Healthcare and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

10. Framework for Quality Assurance of Ultrahigh Dose Rate Clinical Trials Investigating FLASH Effects and Current Technology Gaps

Author

Zou, Wei, Zhang, Rongxiao, Schüler, Emil, Taylor, Paige A, Mascia, Anthony E, Diffenderfer, Eric S, Zhao, Tianyu, Ayan, Ahmet S, Sharma, Manju, Yu, Shu-Jung, Lu, Weiguo, Bosch, Walter R, Tsien, Christina, Surucu, Murat, Pollard-Larkin, Julianne M, Schuemann, Jan, Moros, Eduardo G, Bazalova-Carter, Magdalena, Gladstone, David J, Li, Heng, Simone, Charles B, Petersson, Kristoffer, Kry, Stephen F, Maity, Amit, Loo, Billy W, Dong, Lei, Maxim, Peter G, Xiao, Ying, and Buchsbaum, Jeffrey C

Subjects

Clinical Research, Cancer, Clinical Trials and Supportive Activities, Humans, Credentialing, Electrons, Health Facilities, Patient Positioning, Technology, Radiotherapy Dosage, Other Physical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Oncology & Carcinogenesis

Abstract

FLASH radiation therapy (FLASH-RT), delivered with ultrahigh dose rate (UHDR), may allow patients to be treated with less normal tissue toxicity for a given tumor dose compared with currently used conventional dose rate. Clinical trials are being carried out and are needed to test whether this improved therapeutic ratio can be achieved clinically. During the clinical trials, quality assurance and credentialing of equipment and participating sites, particularly pertaining to UHDR-specific aspects, will be crucial for the validity of the outcomes of such trials. This report represents an initial framework proposed by the NRG Oncology Center for Innovation in Radiation Oncology FLASH working group on quality assurance of potential UHDR clinical trials and reviews current technology gaps to overcome. An important but separate consideration is the appropriate design of trials to most effectively answer clinical and scientific questions about FLASH. This paper begins with an overview of UHDR RT delivery methods. UHDR beam delivery parameters are then covered, with a focus on electron and proton modalities. The definition and control of safe UHDR beam delivery and current and needed dosimetry technologies are reviewed and discussed. System and site credentialing for large, multi-institution trials are reviewed. Quality assurance is then discussed, and new requirements are presented for treatment system standard analysis, patient positioning, and treatment planning. The tables and figures in this paper are meant to serve as reference points as we move toward FLASH-RT clinical trial performance. Some major questions regarding FLASH-RT are discussed, and next steps in this field are proposed. FLASH-RT has potential but is associated with significant risks and complexities. We need to redefine optimization to focus not only on the dose but also on the dose rate in a manner that is robust and understandable and that can be prescribed, validated, and confirmed in real time. Robust patient safety systems and access to treatment data will be critical as FLASH-RT moves into the clinical trials.

Published

2023

11. Quality Assurance in Clinical Trials Requiring Radiation Therapy in Sub-Saharan Africa

Author

Lin, Lilie L, Ndlovu, Ntokozo, Lowenstein, Jessica, Wirth, Meg, Lee, Jeannette, Stier, Elizabeth A, Garg, Madhur, Kotzen, Jeffrey, Kadzatsa, Webster, Palefsky, Joel, Krown, Susan E, and Einstein, Mark H

Subjects

Medical and Biological Physics, Biomedical and Clinical Sciences, Clinical Sciences, Physical Sciences, Oncology and Carcinogenesis, Cancer, Clinical Research, Clinical Trials and Supportive Activities, HIV/AIDS, Female, Humans, Cisplatin, Acquired Immunodeficiency Syndrome, Brachytherapy, Radiotherapy Dosage, Africa South of the Sahara, Neoplasms, Uterine Cervical Neoplasms, Neoplasm Staging, Multicenter Studies as Topic, Other Physical Sciences, Oncology & Carcinogenesis, Oncology and carcinogenesis, Theoretical and computational chemistry, Medical and biological physics

Abstract

PurposeGiven the increasing availability of radiation therapy in sub-Saharan Africa, clinical trials that include radiation therapy are likely to grow. Ensuring appropriate delivery of radiation therapy through rigorous quality assurance is an important component of clinical trial execution. We reviewed the process for credentialing radiation therapy sites and radiation therapy quality assurance through the Imaging and Radiation Oncology Core (IROC) Houston Quality Assurance Center for AIDS Malignancy Consortium (AMC)-081, a multicenter study of cisplatin and radiation therapy for women with locally advanced cervical cancer living with HIV, conducted by the AIDS Malignancy Consortium at 2 sites in South Africa and Zimbabwe.Methods and materialsWomen living with HIV with newly diagnosed stage IB2, IIA (>4 cm), IIB-IVA cervical carcinoma (per the 2009 International Federation of Gynecology and Obstetrics [FIGO] staging classifications) were enrolled in AMC-081. They received 3-dimensional conformal external beam radiation therapy (EBRT) to the pelvis (41.4-45 Gy) using a linear accelerator, high-dose-rate brachytherapy (6-9 Gy to point A with each fraction and up to 4 fractions), and concurrent weekly cisplatin (40 mg/m2). IROC reviewed EBRT and brachytherapy quality assurance records after treatment.ResultsAll of the 38 women enrolled in AMC-081 received ±5% of the protocol-specified prescribed dose of EBRT. Geometry of brachytherapy applicator placement was scored as per protocol in all implants. Doses to points A and B, International Commission on Radiation Units and Measurements (ICRU) bladder, or ICRU rectum required correction by IROC in >50% of the implants. In the final evaluation, 58% of participants (n = 22) were treated per protocol, 40% (n = 15) had minor protocol deviations, and 3% (n = 1) had major protocol deviations. No records were received within 60 days of treatment completion as requested in the protocol.ConclusionsMajor radiation therapy deviations were low, but timely submission of radiation therapy data did not occur. Future studies, especially those that include specialized radiation therapy techniques such as stereotactic or intensity-modulated radiation therapy, will require pathways to ensure timely and adequate quality assurance.

Published

2023

12. OptImal Gamma kNife lIghTnIng sOlutioN (IGNITION) score to characterize the solution space of the Gamma Knife FIP optimizer for stereotactic radiosurgery

Author

Tolakanahalli, Ranjini, Wieczorek, D Jay J, Lee, Yongsook C, Tom, Martin C, Hall, Matthew D, McDermott, Michael W, Mehta, Minesh P, Kotecha, Rupesh, and Gutierrez, Alonso N

Subjects

Medical and Biological Physics, Biomedical and Clinical Sciences, Clinical Sciences, Physical Sciences, Oncology and Carcinogenesis, Cancer, Humans, Radiosurgery, Lightning, Brain Neoplasms, Radiotherapy Dosage, Arteriovenous Malformations, Radiotherapy Planning, Computer-Assisted, Gamma Knife, inverse optimizer, lightning, stereotactic radiosurgery, Other Physical Sciences, Medical Physiology, Nuclear Medicine & Medical Imaging, Medical physiology, Medical and biological physics

Abstract

ObjectivesThe objective of this study is to evaluate the user-defined optimization settings in the Fast Inverse Planning (FIP) optimizer in Leksell GammaPlan® and determine the parameters that result in the best stereotactic radiosurgery (SRS) plan quality for brain metastases, benign tumors, and arteriovenous malformations (AVMs).MethodsThirty patients with metastases and 30 with benign lesions-vestibular schwannoma, AVMs, pituitary adenoma, and meningioma-treated with SRS were evaluated. Each target was planned by varying the low dose (LD) and beam-on-time (BOT) penalties in increments of 0.1, from 0 to 1. The following plan quality metrics were recorded for each plan: Paddick conformity index (PCI), gradient index (GI), BOT, and maximum organ-at-risk (OAR) doses. A novel objective score matrix was calculated for each target using a linearly weighted combination of the aforementioned metrics. A histogram of optimal solutions containing the five best scores was extracted.ResultsA total of 7260 plans were analyzed with 121 plans per patient for the range of LD/BOT penalties. The ranges of PCI, GI, and BOT across all metastatic lesions were 0.58-0.97, 2.1-3.8, and 8.8-238 min, respectively, and were 0.13-0.97, 2.1-3.8, and 8.8-238 min, respectively, for benign lesions. The objective score matrix showed unique optimal solutions for metastatic lesions and benign lesions. Additionally, the plan metrics of the optimal solutions were significantly improved compared to the clinical plans for metastatic lesions with equivalent metrics for all other cases.ConclusionIn this study, FIP optimizer was evaluated to determine the optimal solution space to maximize PCI and minimize GI, BOT and OAR doses simultaneously for single metastatic/benign/non-neoplastic targets. The optimal solution chart was determined using a novel objective score which provides novice and expert planners a roadmap to generate the most optimal plans efficiently using FIP.

Published

2023

13. Elucidating the neurological mechanism of the FLASH effect in juvenile mice exposed to hypofractionated radiotherapy.

Author

Allen, Barrett D, Alaghband, Yasaman, Kramár, Eniko A, Ru, Ning, Petit, Benoit, Grilj, Veljko, Petronek, Michael S, Pulliam, Casey F, Kim, Rachel Y, Doan, Ngoc-Lien, Baulch, Janet E, Wood, Marcelo A, Bailat, Claude, Spitz, Douglas R, Vozenin, Marie-Catherine, and Limoli, Charles L

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Cancer, Pediatric, Brain Cancer, Neurosciences, Brain Disorders, Rare Diseases, Neurological, Humans, Child, Male, Female, Animals, Mice, Disease Models, Animal, Brain Neoplasms, Radiotherapy Dosage, Radiotherapy, FLASH radiotherapy, medulloblastoma, neurocognition, synaptic integrity, vascular sparing, Oncology & Carcinogenesis, Oncology and carcinogenesis

Abstract

BackgroundUltrahigh dose-rate radiotherapy (FLASH-RT) affords improvements in the therapeutic index by minimizing normal tissue toxicities without compromising antitumor efficacy compared to conventional dose-rate radiotherapy (CONV-RT). To investigate the translational potential of FLASH-RT to a human pediatric medulloblastoma brain tumor, we used a radiosensitive juvenile mouse model to assess adverse long-term neurological outcomes.MethodsCohorts of 3-week-old male and female C57Bl/6 mice exposed to hypofractionated (2 × 10 Gy, FLASH-RT or CONV-RT) whole brain irradiation and unirradiated controls underwent behavioral testing to ascertain cognitive status four months posttreatment. Animals were sacrificed 6 months post-irradiation and tissues were analyzed for neurological and cerebrovascular decrements.ResultsThe neurological impact of FLASH-RT was analyzed over a 6-month follow-up. FLASH-RT ameliorated neurocognitive decrements induced by CONV-RT and preserved synaptic plasticity and integrity at the electrophysiological (long-term potentiation), molecular (synaptophysin), and structural (Bassoon/Homer-1 bouton) levels in multiple brain regions. The benefits of FLASH-RT were also linked to reduced neuroinflammation (activated microglia) and the preservation of the cerebrovascular structure, by maintaining aquaporin-4 levels and minimizing microglia colocalized to vessels.ConclusionsHypofractionated FLASH-RT affords significant and long-term normal tissue protection in the radiosensitive juvenile mouse brain when compared to CONV-RT. The capability of FLASH-RT to preserve critical cognitive outcomes and electrophysiological properties over 6-months is noteworthy and highlights its potential for resolving long-standing complications faced by pediatric brain tumor survivors. While care must be exercised before clinical translation is realized, present findings document the marked benefits of FLASH-RT that extend from synapse to cognition and the microvasculature.

Published

2023

14. Automated treatment planning framework for brachytherapy of cervical cancer using 3D dose predictions.

Author

Kallis, Karoline, Moore, Lance, Cortes, Katherina, Mayadev, Jyoti, Moore, Kevin, Brown, Derek, and Meyers, Sandra

Subjects

automated planning, cervical cancer, dose prediction, gynecological brachytherapy, knowledge-based planning, Female, Humans, Uterine Cervical Neoplasms, Brachytherapy, Radiotherapy Dosage, Benchmarking, Radiotherapy Planning, Computer-Assisted

Abstract

Objective. To lay the foundation for automated knowledge-based brachytherapy treatment planning using 3D dose estimations, we describe an optimization framework to convert brachytherapy dose distributions directly into dwell times (DTs).Approach. A dose rate kernelḋ(r,θ,φ)was produced by exporting 3D dose for one dwell position from the treatment planning system and normalizing by DT. By translating and rotating this kernel to each dwell position, scaling by DT and summing over all dwell positions, dose was computed (Dcalc). We used a Python-coded COBYLA optimizer to iteratively determine the DTs that minimize the mean squared error betweenDcalcand reference doseDref, computed using voxels withDref80%-120% of prescription. As validation of the optimization, we showed that the optimizer replicates clinical plans whenDref= clinical dose in 40 patients treated with tandem-and-ovoid (T&O) or tandem-and-ring (T&R) and 0-3 needles. Then we demonstrated automated planning in 10 T&O usingDref= dose predicted from a convolutional neural network developed in past work. Validation and automated plans were compared to clinical plans using mean absolute differences (MAD=1N∑n=1Nabsxn-xn) over all voxels (xn= Dose,N= #voxels) and DTs (xn= DT,N= #dwell positions), mean differences (MD) in organD2ccand high-risk CTV D90 over all patients (where positive indicates higher clinical dose), and mean Dice similarity coefficients (DSC) for 100% isodose contours.Main results. Validation plans agreed well with clinical plans (MADdose= 1.1%, MADDT= 4 s or 0.8% of total plan time,D2ccMD = -0.2% to 0.2% and D90 MD = -0.6%, DSC = 0.99). For automated plans, MADdose= 6.5% and MADDT= 10.3 s (2.1%). The slightly higher clinical metrics in automated plans (D2ccMD = -3.8% to 1.3% and D90 MD = -5.1%) were due to higher neural network dose predictions. The overall shape of the automated dose distributions were similar to clinical doses (DSC = 0.91).Significance. Automated planning with 3D dose predictions could provide significant time savings and standardize treatment planning across practitioners, regardless of experience.

Published

2023

15. A Novel Treatment Planning Design for Intraoperative Electron Radiation Therapy (IOERT) using an Electronic Board

Author

Zahra Pouyanrad, Mojtaba Shamsaei Zafarghandi, and Saeed Setayeshi

Subjects

intraoperative radiotherapy, radiation therapy, radiosurgery, monte carlo method, radiotherapy dosage, Medical physics. Medical radiology. Nuclear medicine, R895-920

Abstract

Background: Intraoperative Irradiation Therapy (IORT) refers to the delivery of radiation during surgery and needs the computed- thickness of the target as one of the most significant factors.Objective: This paper aimed to compute target thickness and design a radiation pattern distributing the irradiation uniformly throughout the target.Material and Methods: The Monte Carlo code was used to simulate the experimental setup in this simulation study. The electron flux variations on an electronic board’s metallic layer were studied for different thicknesses of the target tissue and validated with experimental data of the electronic board.Results: Based on the electron number for different Poly Methyl Methacrylate (PMMA) phantom thicknesses at various energies, 6 MeV electrons are suitable to determine the target thickness. Uniformity in radiation and corresponding time for each target were investigated. The iso-dose and percentage depth dose curves show that higher energies are suitable for treatment and distribute uniform radiation throughout the target. Increasing the phantom thickness leads to rising radiation time based on the radiation time corresponding to these energies. The tissue thickness of each section is determined, and the radiation time is managed by scanning the target. Conclusion: Calculation of the thickness of the remaining tissue and irradiation time are needed after incomplete tumor removal in IORT for various remaining tissues. The patients should be protected from overexposure to uniform irradiation of tissues since the radiation dose is prescribed and checked by an oncologist.

Published

2024

16. Single pulse protoacoustic range verification using a clinical synchrocyclotron

Author

Caron, Joseph, Gonzalez, Gilberto, Pandey, Prabodh Kumar, Wang, Siqi, Prather, Kiana, Ahmad, Salahuddin, Xiang, Liangzhong, and Chen, Yong

Subjects

Medical and Biological Physics, Physical Sciences, Biomedical Imaging, Cancer, Bioengineering, Protons, Radiotherapy Dosage, Cyclotrons, Proton Therapy, Radiometry, Monte Carlo Method, proton therapy, range verification, protoacoustics, ionoacoustics, Other Physical Sciences, Biomedical Engineering, Clinical Sciences, Nuclear Medicine & Medical Imaging, Medical and biological physics

Abstract

Objective.Proton therapy as the next generation radiation-based cancer therapy offers dominant advantages over conventional radiation therapy due to the utilization of the Bragg peak; however, range uncertainty in beam delivery substantially mitigates the advantages of proton therapy. This work reports using protoacoustic measurements to determine the location of proton Bragg peak deposition within a water phantom in real time during beam delivery.Approach.In protoacoustics, proton beams have a definitive range, depositing a majority of the dose at the Bragg peak; this dose is then converted to heat. The resulting thermoelastic expansion generates a 3D acoustic wave, which can be detected by acoustic detectors to localize the Bragg peak.Main results.Protoacoustic measurements were performed with a synchrocyclotron proton machine over the exhaustive energy range from 45.5 to 227.15 MeV in clinic. It was found that the amplitude of the acoustic waves is proportional to proton dose deposition, and therefore encodes dosimetric information. With the guidance of protoacoustics, each individual proton beam (7 pC/pulse) can be directly visualized with sub-millimeter (

Published

2023

17. Use of focal radiotherapy boost for prostate cancer: radiation oncologists’ perspectives and perceived barriers to implementation

Author

Zhong, Allison Y, Lui, Asona J, Katz, Matthew S, Berlin, Alejandro, Kamran, Sophia C, Kishan, Amar U, Murthy, Vedang, Nagar, Himanshu, Seible, Daniel, Stish, Bradley J, Tree, Alison C, and Seibert, Tyler M

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Clinical Trials and Supportive Activities, Cancer, Clinical Research, Biomedical Imaging, Prostate Cancer, Urologic Diseases, Humans, Male, Magnetic Resonance Imaging, Prostate, Prostatic Neoplasms, Radiation Oncologists, Radiotherapy Dosage, United States, Prostate cancer, Radiotherapy, Focal boost, Tumor boost, Oncology & Carcinogenesis, Clinical sciences, Oncology and carcinogenesis

Abstract

BackgroundIn a recent phase III randomized control trial, delivering a focal radiotherapy (RT) boost to tumors visible on MRI was shown to improve disease-free survival and regional/distant metastasis-free survival for patients with prostate cancer-without increasing toxicity. The aim of this study was to assess how widely this technique is being applied in current practice, as well as physicians' perceived barriers toward its implementation.MethodsWe invited radiation oncologists to complete an online questionnaire assessing their use of intraprostatic focal boost in December 2022 and February 2023. To include perspectives from a broad range of practice settings, the invitation was distributed to radiation oncologists worldwide via email list, group text platform, and social media.Results263 radiation oncologist participants responded. The highest-represented countries were the United States (42%), Mexico (13%), and the United Kingdom (8%). The majority of participants worked at an academic medical center (52%) and considered their practice to be at least partially genitourinary (GU)-subspecialized (74%). Overall, 43% of participants reported routinely using intraprostatic focal boost. Complete GU-subspecialists were more likely to implement focal boost, with 61% reporting routine use. In both high-income and low-to-middle-income countries, less than half of participants routinely use focal boost. The most cited barriers were concerns about registration accuracy between MRI and CT (37%), concerns about risk of additional toxicity (35%), and challenges to accessing high-quality MRI (29%).ConclusionsTwo years following publication of a randomized trial of patient benefit without increased toxicity, almost half of the radiation oncologists surveyed are now routinely offering focal RT boost. Further adoption of this technique might be aided by increased access to high-quality MRI, better registration algorithms of MRI to CT simulation images, physician education on benefit-to-harm ratio, and training on contouring prostate lesions on MRI.

Published

2023

18. Clinical commissioning of an adaptive radiotherapy platform: Results and recommendations

Author

Kisling, Kelly, Keiper, Timothy D, Branco, Daniela, Kim, Grace Gwe‐Ya, Moore, Kevin L, and Ray, Xenia

Subjects

Medical and Biological Physics, Biomedical and Clinical Sciences, Clinical Sciences, Physical Sciences, Oncology and Carcinogenesis, Bioengineering, Cancer, Humans, Radiotherapy Dosage, Radiotherapy, Intensity-Modulated, Cone-Beam Computed Tomography, Tomography, X-Ray Computed, Radiometry, Radiotherapy Planning, Computer-Assisted, Phantoms, Imaging, adaptive radiotherapy, CBCT, ethos, on-table adaptation, quality assurance, synthetic CT, workflow, Other Physical Sciences, Medical Physiology, Nuclear Medicine & Medical Imaging, Medical physiology, Medical and biological physics

Abstract

Online adaptive radiotherapy platforms present a unique challenge for commissioning as guidance is lacking and specialized adaptive equipment, such as deformable phantoms, are rare. We designed a novel adaptive commissioning process consisting of end-to-end tests using standard clinical resources. These tests were designed to simulate anatomical changes regularly observed at patient treatments. The test results will inform users of the magnitude of uncertainty from on-treatment changes during the adaptive workflow and the limitations of their systems. We implemented these tests for the cone-beam computed tomography (CT)-based Varian Ethos online adaptive platform. Many adaptive platforms perform online dose calculation on a synthetic CT (synCT). To assess the impact of the synCT generation and online dose calculation on dosimetric accuracy, we conducted end-to-end tests using commonly available equipment: a CIRS IMRT Thorax phantom, PinPoint ionization chamber, Gafchromic film, and bolus. Four clinical scenarios were evaluated: weight gain and weight loss were simulated by adding and removing bolus, internal target shifts were simulated by editing the CTV during the adaptive workflow to displace it, and changes in gas were simulated by removing and reinserting rods in varying phantom locations. The effect of overriding gas pockets during planning was also assessed. All point dose measurements agreed within 2.7% of the calculated dose, with one exception: a scenario simulating gas present in the planning CT, not overridden during planning, and dissipating at treatment. Relative film measurements passed gamma analysis (3%/3 mm criteria) for all scenarios. Our process validated the Ethos dose calculation for online adapted treatment plans. Based on our results, we made several recommendations for our clinical adaptive workflow. This commissioning process used commonly available equipment and, therefore, can be applied in other clinics for their respective online adaptive platforms.

Published

2022

19. Safety of accelerated hypofractionated whole pelvis radiation therapy prior to high dose rate brachytherapy or stereotactic body radiation therapy prostate boost

Author

Phuong, Christina, Chan, Jason W, Ni, Lisa, Wall, Phillip, Mohamad, Osama, Wong, Anthony C, Hsu, I-Chow, and Chang, Albert J

Subjects

Digestive Diseases, Cancer, Clinical Research, Prostate Cancer, Urologic Diseases, Clinical Trials and Supportive Activities, Aging, Patient Safety, 6.5 Radiotherapy and other non-invasive therapies, Evaluation of treatments and therapeutic interventions, Aged, Brachytherapy, Humans, Male, Prostatic Neoplasms, Radiation Dose Hypofractionation, Radiosurgery, Radiotherapy Dosage, Retrospective Studies, Hypofractionation, Prostate cancer, Nodal radiotherapy, Pelvic radiotherapy, HDR brachytherapy, Oncology and Carcinogenesis, Oncology & Carcinogenesis

Abstract

BackgroundTo evaluate acute and late genitourinary and gastrointestinal toxicities and patient reported urinary and sexual function following accelerated, hypofractionated external beam radiotherapy to the prostate, seminal vesicles and pelvic lymph nodes and high dose rate (HDR) brachytherapy or stereotactic body radiation therapy (SBRT) prostate boost.MethodsPatients at a single institution with NCCN intermediate- and high-risk localized prostate cancer with logistical barriers to completing five weeks of whole pelvic radiotherapy (WPRT) were retrospectively reviewed for toxicity following accelerated, hypofractionated WPRT (41.25 Gy in 15 fractions of 2.75 Gy). Patients also received prostate boost radiotherapy with either HDR brachytherapy (1 fraction of 15 Gy) or SBRT (19 Gy in 2 fractions of 9.5 Gy). The duration of androgen deprivation therapy was at the discretion of the treating radiation oncologist. Toxicity was evaluated by NCI CTCAE v 5.0.ResultsBetween 2015 and 2017, 22 patients with a median age of 71 years completed accelerated, hypofractionated WPRT. Median follow-up from the end of radiotherapy was 32 months (range 2-57). 5%, 73%, and 23% of patients had clinical T1, T2, and T3 disease, respectively. 86% of tumors were Gleason grade 7 and 14% were Gleason grade 9. 68% and 32% of patients had NCCN intermediate- and high-risk disease, respectively. 91% and 9% of patients received HDR brachytherapy and SBRT prostate boost following WPRT, respectively. Crude rates of grade 2 or higher GI and GU toxicities were 23% and 23%, respectively. 3 patients (14%) had late or persistent grade 2 toxicities of urinary frequency and 1 patient (5%) had late or persistent GI toxicity of diarrhea. No patient experienced grade 3 or higher toxicity at any time. No difference in patient-reported urinary or sexual function was noted at 12 months.ConclusionsAccelerated, hypofractionated whole pelvis radiotherapy was associated with acceptable GU and GI toxicities and should be further validated for those at risk for harboring occult nodal disease.

Published

2022

20. A Novel Treatment Planning Design for Intraoperative Electron Radiation Therapy (IOERT) using an Electronic Board.

Author

Pouyanrad, Zahra, Zafarghandi, Mojtaba Shamsaei, and Setayeshi, Saeed

Subjects

INTRAOPERATIVE radiotherapy, POLYMETHYLMETHACRYLATE, MONTE Carlo method, IRRADIATION

Abstract

Background: Intraoperative Irradiation Therapy (IORT) refers to the delivery of radiation during surgery and needs the computed- thickness of the target as one of the most significant factors. Objective: This paper aimed to compute target thickness and design a radiation pattern distributing the irradiation uniformly throughout the target. Material and Methods: The Monte Carlo code was used to simulate the experimental setup in this simulation study. The electron flux variations on an electronic board's metallic layer were studied for different thicknesses of the target tissue and validated with experimental data of the electronic board. Results: Based on the electron number for different Poly Methyl Methacrylate (PMMA) phantom thicknesses at various energies, 6 MeV electrons are suitable to determine the target thickness. Uniformity in radiation and corresponding time for each target were investigated. The iso-dose and percentage depth dose curves show that higher energies are suitable for treatment and distribute uniform radiation throughout the target. Increasing the phantom thickness leads to rising radiation time based on the radiation time corresponding to these energies. The tissue thickness of each section is determined, and the radiation time is managed by scanning the target. Conclusion: Calculation of the thickness of the remaining tissue and irradiation time are needed after incomplete tumor removal in IORT for various remaining tissues. The patients should be protected from overexposure to uniform irradiation of tissues since the radiation dose is prescribed and checked by an oncologist. [ABSTRACT FROM AUTHOR]

Published

2024

21. Generation of synthetic megavoltage CT for MRI-only radiotherapy treatment planning using a 3D deep convolutional neural network.

Author

Rajagopal, Abhejit, Vasquez, Elena, Sudhyadhom, Atchar, Larson, Peder, and Scholey, Jessica

Subjects

dose calculation for radiotherapy, magnetic resonance imaging, quantitative imaging, Humans, Magnetic Resonance Imaging, Neural Networks, Computer, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Retrospective Studies, Tomography, X-Ray Computed

Abstract

BACKGROUND: Megavoltage computed tomography (MVCT) has been implemented on many radiotherapy treatment machines for on-board anatomical visualization, localization, and adaptive dose calculation. Implementing an MR-only workflow by synthesizing MVCT from magnetic resonance imaging (MRI) would offer numerous advantages for treatment planning and online adaptation. PURPOSE: In this work, we sought to synthesize MVCT (sMVCT) datasets from MRI using deep learning to demonstrate the feasibility of MRI-MVCT only treatment planning. METHODS: MVCTs and T1-weighted MRIs for 120 patients treated for head-and-neck cancer were retrospectively acquired and co-registered. A deep neural network based on a fully-convolutional 3D U-Net architecture was implemented to map MRI intensity to MVCT HU. Input to the model were volumetric patches generated from paired MRI and MVCT datasets. The U-Net was initialized with random parameters and trained on a mean absolute error (MAE) objective function. Model accuracy was evaluated on 18 withheld test exams. sMVCTs were compared to respective MVCTs. Intensity-modulated volumetric radiotherapy (IMRT) plans were generated on MVCTs of four different disease sites and compared to plans calculated onto corresponding sMVCTs using the gamma metric and dose-volume-histograms (DVHs). RESULTS: MAE values between sMVCT and MVCT datasets were 93.3 ± 27.5, 78.2 ± 27.5, and 138.0 ± 43.4 HU for whole body, soft tissue, and bone volumes, respectively. Overall, there was good agreement between sMVCT and MVCT, with bone and air posing the greatest challenges. The retrospective dataset introduced additional deviations due to sinus filling or tumor growth/shrinkage between scans, differences in external contours due to variability in patient positioning, or when immobilization devices were absent from diagnostic MRIs. Dose distributions of IMRT plans evaluated for four test cases showed close agreement between sMVCT and MVCT images when evaluated using DVHs and gamma dose metrics, which averaged to 98.9 ± 1.0% and 96.8 ± 2.6% analyzed at 3%/3 mm and 2%/2 mm, respectively. CONCLUSIONS: MVCT datasets can be generated from T1-weighted MRI using a 3D deep convolutional neural network with dose calculation on a sample sMVCT in close agreement with the MVCT. These results demonstrate the feasibility of using MRI-derived sMVCT in an MR-only treatment planning workflow.

Published

2022

22. OpenKBP-Opt: an international and reproducible evaluation of 76 knowledge-based planning pipelines.

Author

Babier, Aaron, Mahmood, Rafid, Zhang, Binghao, Alves, Victor, Barragán-Montero, Ana, Beaudry, Joel, Cardenas, Carlos, Chang, Yankui, Chen, Zijie, Chun, Jaehee, Diaz, Kelly, David Eraso, Harold, Faustmann, Erik, Gaj, Sibaji, Gay, Skylar, Gronberg, Mary, Guo, Bingqi, He, Junjun, Heilemann, Gerd, Hira, Sanchit, Huang, Yuliang, Ji, Fuxin, Jiang, Dashan, Carlo Jimenez Giraldo, Jean, Lee, Hoyeon, Lian, Jun, Liu, Shuolin, Liu, Keng-Chi, Marrugo, José, Miki, Kentaro, Nakamura, Kunio, Netherton, Tucker, Nguyen, Dan, Nourzadeh, Hamidreza, Osman, Alexander, Peng, Zhao, Darío Quinto Muñoz, José, Ramsl, Christian, Joo Rhee, Dong, David Rodriguez, Juan, Shan, Hongming, Siebers, Jeffrey, Soomro, Mumtaz, Sun, Kay, Usuga Hoyos, Andrés, Valderrama, Carlos, Verbeek, Rob, Wang, Enpei, Willems, Siri, Wu, Qi, Xu, Xuanang, Yang, Sen, Yuan, Lulin, Zhu, Simeng, Zimmermann, Lukas, Moore, Kevin, Purdie, Thomas, McNiven, Andrea, and Chan, Theodore

Subjects

automated planning, inverse optimization, inverse problem, knowledge-based planning, open data, optimization, radiotherapy, Humans, Knowledge Bases, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Intensity-Modulated, Reproducibility of Results

Abstract

Objective.To establish an open framework for developing plan optimization models for knowledge-based planning (KBP).Approach.Our framework includes radiotherapy treatment data (i.e. reference plans) for 100 patients with head-and-neck cancer who were treated with intensity-modulated radiotherapy. That data also includes high-quality dose predictions from 19 KBP models that were developed by different research groups using out-of-sample data during the OpenKBP Grand Challenge. The dose predictions were input to four fluence-based dose mimicking models to form 76 unique KBP pipelines that generated 7600 plans (76 pipelines × 100 patients). The predictions and KBP-generated plans were compared to the reference plans via: the dose score, which is the average mean absolute voxel-by-voxel difference in dose; the deviation in dose-volume histogram (DVH) points; and the frequency of clinical planning criteria satisfaction. We also performed a theoretical investigation to justify our dose mimicking models.Main results.The range in rank order correlation of the dose score between predictions and their KBP pipelines was 0.50-0.62, which indicates that the quality of the predictions was generally positively correlated with the quality of the plans. Additionally, compared to the input predictions, the KBP-generated plans performed significantly better (P< 0.05; one-sided Wilcoxon test) on 18 of 23 DVH points. Similarly, each optimization model generated plans that satisfied a higher percentage of criteria than the reference plans, which satisfied 3.5% more criteria than the set of all dose predictions. Lastly, our theoretical investigation demonstrated that the dose mimicking models generated plans that are also optimal for an inverse planning model.Significance.This was the largest international effort to date for evaluating the combination of KBP prediction and optimization models. We found that the best performing models significantly outperformed the reference dose and dose predictions. In the interest of reproducibility, our data and code is freely available.

Published

2022

23. Dose and volume limiting late toxicity of FLASH radiotherapy in cats with squamous cell carcinoma of the nasal planum and in mini-pigsExploring the limits of FLASH radiotherapy: late toxicity

Author

Bley, Carla Rohrer, Wolf, Friederike, Jorge, Partrik Gonçalves, Grilj, Veljko, Petridis, Ioannis, Petit, Benoit, Böhlen, Till T, Moeckli, Raphael, Limoli, Charles, Bourhis, Jean, Meier, Valeria, and Vozenin, Marie-Catherine

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Cancer, Clinical Trials and Supportive Activities, Clinical Research, Rare Diseases, 6.5 Radiotherapy and other non-invasive therapies, Evaluation of treatments and therapeutic interventions, Animals, Carcinoma, Squamous Cell, Cats, Necrosis, Nose Neoplasms, Radiotherapy Dosage, Swine, Swine, Miniature, Oncology & Carcinogenesis, Clinical sciences, Oncology and carcinogenesis

Abstract

PurposeThe FLASH effect is characterized by normal tissue sparing without compromising tumor control. Although demonstrated in various preclinical models, safe translation of FLASH-radiotherapy stands to benefit from larger vertebrate animal models. Based on prior results, we designed a randomized phase III trial to investigate the FLASH effect in cat patients with spontaneous tumors. In parallel, the sparing capacity of FLASH-radiotherapy was studied on mini pigs by using large field irradiation.Experimental designCats with T1-T2, N0 carcinomas of the nasal planum were randomly assigned to two arms of electron irradiation: arm 1 was the standard of care (SoC) and used 10 × 4.8 Gy (90% isodose); arm 2 used 1 × 30 Gy (90% isodose) FLASH. Mini pigs were irradiated using applicators of increasing size and a single surface dose of 31 Gy FLASH.ResultsIn cats, acute side effects were mild and similar in both arms. The trial was prematurely interrupted due to maxillary bone necrosis, which occurred 9 to 15 months after radiotherapy in 3 of 7 cats treated with FLASH-radiotherapy (43%), as compared with 0 of 9 cats treated with SoC. All cats were tumor-free at 1 year in both arms, with one cat progressing later in each arm. In pigs, no acute toxicity was recorded, but severe late skin necrosis occurred in a volume-dependent manner (7-9 months), which later resolved.ConclusionsThe reported outcomes point to the caveats of translating single-high-dose FLASH-radiotherapy and emphasizes the need for caution and further investigations. See related commentary by Maity and Koumenis, p. 3636.

Published

2022

24. RISK FACTORS FOR NEUTROPENIA DURING POSTOPERATIVE ADJUVANT RADIOTHERAPY FOR BREAST CANCER

Author

JIN Long, CAO Fei, ZHANG Li, MA Shaojun

Subjects

breast neoplasms, radiotherapy, adjuvant, neutropenia, radiotherapy dosage, planning target volume, risk factors, Medicine

Abstract

Objective To explore the risk factors for neutropenia (grade 2 or higher) during postoperative adjuvant radiotherapy for breast cancer. Methods A total of 93 patients with breast cancer treated by postoperative adjuvant radiotherapy in Shaanxi Provincial People’s Hospital from January 2018 to December 2020 were assigned to a control group (no neutropenia or grade 1 neutropenia, n=62) and an observation group (grade 2 or higher neutropenia, n=31). The clinical data of the two groups were analyzed by univariate and logistic regression analyses to determine the independent risk factors for grade 2 or higher neutropenia, and the predictive efficacy of risk factors was established by the receiver operating characteristic (ROC) curve. Results The univariate analysis results showed that there were significant differences between the two groups in molecular types of breast cancer, white blood cell count and absolute neutrophil count at the first visit, proportion of patients with grade 4 myelosuppression during chemotherapy, white blood cell count, absolute neutrophil count, hemoglobin before radiotherapy, planning target volume (PTV), mean radiotherapy dose to the sternum (Dmean), and ratio of volume exposed to radiation greater than 20 Gy to total vo-lume and ratio of volume exposed to radiation greater than 30 Gy to total volume in the sternum (χ2=4.511,9.900,t=2.286-9.900,P733.28 mL and sternum Dmean >2 213.5 cGy are independent risk factors for grade 2 or higher neutropenia during postoperative adjuvant radiotherapy for breast cancer, and the combination of the two indices can improve the predictive efficacy for the occurrence of neutropenia.

Published

2023

25. Treatment planning system commissioning of the first clinical biology‐guided radiotherapy machine

Author

Simiele, Eric, Capaldi, Dante, Breitkreutz, Dylan, Han, Bin, Yeung, Timothy, White, John, Zaks, Daniel, Owens, Michael, Maganti, Srinath, Xing, Lei, Surucu, Murat, and Kovalchuk, Nataliya

Subjects

Medical and Biological Physics, Biomedical and Clinical Sciences, Clinical Sciences, Physical Sciences, Oncology and Carcinogenesis, Cancer, Biology, Humans, Phantoms, Imaging, Radiometry, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Intensity-Modulated, BgRT, RefleXion, TPS commissioning, Other Physical Sciences, Medical Physiology, Nuclear Medicine & Medical Imaging, Medical physiology, Medical and biological physics

Abstract

PurposeThe RefleXion X1 is a novel radiotherapy machine designed for image-guided radiotherapy (IGRT) and biology-guided radiotherapy (BgRT). Its treatment planning system (TPS) generates IMRT and SBRT plans for a 6MV-FFF beam delivered axially via 50 firing positions with the couch advancing every 2.1 mm. The purpose of this work is to report the TPS commissioning results for the first clinical installation of RefleXion™ X1.MethodsCT images of multiple phantoms were imported into the RefleXion TPS to evaluate the accuracy of data transfer, anatomical modeling, plan evaluation, and dose calculation. Comparisons were made between the X1, Eclipse™, and MIM™. Dosimetric parameters for open static fields were evaluated in water and heterogeneous slab phantoms. Representative clinical IMRT and SBRT cases were planned and verified with ion chamber, film, and ArcCHECK@ measurements. The agreement between TPS and measurements for various clinical plans was evaluated using Gamma analysis with a criterion of 3%/2 mm for ArcCHECK@ and film. End-to-end (E2E) testing was performed using anthropomorphic head and lung phantoms.ResultsThe average difference between the TPS-reported and known HU values was -1.4 ± 6.0 HU. For static fields, the agreements between the TPS-calculated and measured PDD10 , crossline profiles, and inline profiles (FWHM) were within 1.5%, 1.3%, and 0.5 mm, respectively. Measured output factors agreed with the TPS within 1.3%. Measured and calculated dose for static fields in heterogeneous phantoms agreed within 2.5%. The ArcCHECK@ mean absolute Gamma passing rate was 96.4% ± 3.4% for TG 119 and TG 244 plans and 97.8% ± 3.6% for the 21 clinical plans. E2E film analysis showed 0.8 mm total targeting error for isocentric and 1.1 mm for off-axis treatments.ConclusionsThe TPS commissioning results of the RefleXion X1 TPS were within the tolerances specified by AAPM TG 53, MPPG 5.a, TG 119, and TG 148. A subset of the commissioning tests has been identified as baseline data for an ongoing QA program.

Published

2022

26. Knowledge-based three-dimensional dose prediction for tandem-and-ovoid brachytherapy.

Author

Cortes, Katherina G, Kallis, Karoline, Simon, Aaron, Mayadev, Jyoti, Meyers, Sandra M, and Moore, Kevin L

Subjects

Humans, Tomography, X-Ray Computed, Brachytherapy, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Uterine Cervical Neoplasms, Female, Organs at Risk, Cervical cancer, Convolutional neural network, Deep learning, Knowledge-based dose estimation, Knowledge-based planning, Tandem and ovoids, Knowledge -based plan, Clinical Sciences, Oncology & Carcinogenesis

Abstract

PurposeThe purpose of this work was to develop a knowledge-based dose prediction system using a convolution neural network (CNN) for cervical brachytherapy treatments with a tandem-and-ovoid applicator.MethodsA 3D U-NET CNN was utilized to make voxel-wise dose predictions based on organ-at-risk (OAR), high-risk clinical target volume (HRCTV), and possible source location geometry. The model comprised 395 previously treated cases: training (273), validation (61), test (61). To assess voxel prediction accuracy, we evaluated dose differences in all cohorts across the dose range of 20-130% of prescription, mean (SD) and standard deviation (σ), as well as isodose dice similarity coefficients for clinical and/or predicted dose distributions. We examined discrete Dose-Volume Histogram (DVH) metrics utilized for brachytherapy plan quality assessment (HRCTV D90%; bladder, rectum, and sigmoid D2cc) with ΔDx=Dx,actual-Dx,predicted mean, standard deviation, and Pearson correlation coefficient further quantifying model performance.ResultsRanges of voxel-wise dose difference accuracy (δD¯±σ) for 20-130% dose interval in training (test) sets ranged from [-0.5% ± 2.0% to +2.0% ± 14.0%] ([-0.1% ± 4.0% to +4.0% ± 26.0%]) in all voxels, [-1.7% ± 5.1% to -3.5% ± 12.8%] ([-2.9% ± 4.8% to -2.6% ± 18.9%]) in HRCTV, [-0.02% ± 2.40% to +3.2% ± 12.0%] ([-2.5% ± 3.6% to +0.8% ± 12.7%]) in bladder, [-0.7% ± 2.4% to +15.5% ± 11.0%] ([-0.9% ± 3.2% to +27.8% ± 11.6%]) in rectum, and [-0.7% ± 2.3% to +10.7% ± 15.0%] ([-0.4% ± 3.0% to +18.4% ± 11.4%]) in sigmoid. Isodose dice similarity coefficients ranged from [0.96,0.91] for training and [0.94,0.87] for test cohorts. Relative DVH metric prediction in the training (test) set were HRCTV ΔD¯90±σΔD = -0.19 ± 0.55Gy (-0.09 ± 0.67 Gy), bladder ΔD¯2cc±σΔD = -0.06 ± 0.54Gy (-0.17 ± 0.67 Gy), rectum ΔD¯2cc±σΔD= -0.03 ± 0.36Gy (-0.04 ± 0.46 Gy), and sigmoid ΔD¯2cc±σΔD = -0.01 ± 0.34Gy (0.00 ± 0.44 Gy).ConclusionsA 3D knowledge-based dose predictions provide voxel-level and DVH metric estimates that could be used for treatment plan quality control and data-driven plan guidance.

Published

2022

27. Adaptive replanning using cone beam CT for deformation of original CT simulation

Author

Bojechko, Casey, Hua, Patricia, Sumner, Whitney, Guram, Kripa, Atwood, Todd, and Sharabi, Andrew

Subjects

Medical and Biological Physics, Biomedical and Clinical Sciences, Clinical Sciences, Physical Sciences, Oncology and Carcinogenesis, Dental/Oral and Craniofacial Disease, Cancer, Rare Diseases, Biomedical Imaging, 4.2 Evaluation of markers and technologies, Detection, screening and diagnosis, Cone-Beam Computed Tomography, Head and Neck Neoplasms, Humans, Male, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Intensity-Modulated, Tomography, X-Ray Computed, Adaptive radiotherapy (ART) < radiation therapy, deformable registration < radiation therapy, general < discipline, head and neck < clinical site, medical imaging < general, palliative < general, radiotherapy (radiation therapy) < discipline, Clinical sciences, Oncology and carcinogenesis

Abstract

BackgroundDuring a course of radiation therapy, anatomical changes such as a decrease in tumour size or weight loss can trigger the need for repeating a computed tomography (CT) simulation scan in order to generate a new treatment plan. This adaptive approach requires a separate appointment for an additional CT scan which generates additional burden, cost, and radiation exposure for patients.Case presentationHere, we present a case of a head and neck cancer patient who required palliative radiation for a large neck mass. During treatment, he had a remarkable response which required a replan due to rapid tumour downsizing. In this case, we used a novel technique to avoid repeating the planning CT simulation by using a mid-treatment high-quality cone beam CT (CBCT) to deform the secondary image (plan CT) of the original planning CT and generate a new adapted treatment plan.ConclusionThis is the first report to our knowledge using a Halcyon CBCT to deform the original planning CT in order to generate a new radiation treatment plan, and this novel technique represents a new potential method of adaptive replanning for select patients.

Published

2022

28. Beam commissioning of the first clinical biology‐guided radiotherapy system

Author

Han, Bin, Capaldi, Dante, Kovalchuk, Nataliya, Simiele, Eric, White, John, Zaks, Daniel, Xing, Lei, and Surucu, Murat

Subjects

Medical and Biological Physics, Biomedical and Clinical Sciences, Clinical Sciences, Physical Sciences, Oncology and Carcinogenesis, Bioengineering, Biology, Humans, Particle Accelerators, Radiometry, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Water, BGRT, RefleXion, commissioning, Other Physical Sciences, Medical Physiology, Nuclear Medicine & Medical Imaging, Medical physiology, Medical and biological physics

Abstract

This study reports the beam commissioning results for the first clinical RefleXion Linac.MethodsThe X1 produces a 6 MV photon beam and the maximum clinical field size is 40 × 2 cm2 at source-to-axis distance of 85 cm. Treatment fields are collimated by a binary multileaf collimator (MLC) system with 64 leaves with width of 0.625 cm and y-jaw pairs to provide either a 1 or 2 cm opening. The mechanical alignment of the radiation source, the y-jaw, and MLC were checked with film and ion chambers. The beam parameters were characterized using a diode detector in a compact water tank. In-air lateral profiles and in-water percentage depth dose (PDD) were measured for beam modeling of the treatment planning system (TPS). The lateral profiles, PDDs, and output factors were acquired for field sizes from 1.25 × 1 to 40 × 2 cm2 field to verify the beam modeling. The rotational output variation and synchronicity were tested to check the gantry angle, couch motion, and gantry rotation.ResultsThe source misalignments were 0.049 mm in y-direction, 0.66% out-of-focus in x-direction. The divergence of the beam axis was 0.36 mm with a y-jaw twist of 0.03°. Clinical off-axis treatment fields shared a common center in y-direction were within 0.03 mm. The MLC misalignment and twist were 0.57 mm and 0.15°. For all measured fields ranging from the size from 1.25 × 1 to 40 × 2 cm2 , the mean difference between measured and TPS modeled PDD at 10 cm depth was -0.3%. The mean transverse profile difference in the field core was -0.3% ± 1.1%. The full-width half maximum (FWHM) modeling was within 0.5 mm. The measured output factors agreed with TPS within 0.8%.ConclusionsThis study summarizes our specific experience commissioning the first novel RefleXion linac, which may assist future users of this technology when implementing it into their own clinics.

Published

2022

29. Treatment of cervical cancer: overcoming challenges in access to brachytherapy

Author

Lichter, Katie, Akinfenwa, Chidinma Anakwenze, MacDuffie, Emily, Bhatia, Rohini, Small, Christina, Croke, Jennifer, Small, William, Chino, Junzo, Petereit, Daniel, and Grover, Surbhi

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Cancer, Clinical Research, Cervical Cancer, Brachytherapy, Female, Humans, Radiotherapy Dosage, Uterine Cervical Neoplasms, Cervix Cancer, global health, global oncology, health disparities, gynecologic cancer, medication education, radiotherapy, radiation oncology, Oncology & Carcinogenesis, Oncology and carcinogenesis

Abstract

IntroductionBrachytherapy is an essential component of the cervical cancer treatment paradigm as it contributes to improved clinical outcomes and overall survival. Yet brachytherapy remains globally underutilized, with disparities in access at both national and international levels.Areas coveredThe review explores current brachytherapy utilization practices and efforts being undertaken to address barriers to implementation in low-, middle-, and high-income countries, and how these efforts are projected to impact future brachytherapy access. The content presented is based on a review of published literature and the authors' collective clinical experiences.Expert opinionThere exists a tremendous opportunity to expand access to essential brachytherapy services for women with cervical cancer. Many national and international brachytherapy efforts exist; yet it remains imperative that such focused efforts continue to grow and provide further access to this critical treatment modality for women in need worldwide.

Published

2022

30. AAPM task group report 302: Surface-guided radiotherapy.

Author

Al-Hallaq, Hania, Cerviño, Laura, Gutierrez, Alonso, Havnen-Smith, Amanda, Higgins, Susan, Kügele, Malin, Padilla, Laura, Pawlicki, Todd, Remmes, Nicholas, Smith, Koren, Tang, Xiaoli, and Tomé, Wolfgang

Subjects

deep inspiration breath hold, frameless radiosurgery, risk assessment, surface guided radiotherapy, Brachytherapy, Humans, Radiosurgery, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Image-Guided, Research Report, United States

Abstract

The clinical use of surface imaging has increased dramatically, with demonstrated utility for initial patient positioning, real-time motion monitoring, and beam gating in a variety of anatomical sites. The Therapy Physics Subcommittee and the Imaging for Treatment Verification Working Group of the American Association of Physicists in Medicine commissioned Task Group 302 to review the current clinical uses of surface imaging and emerging clinical applications. The specific charge of this task group was to provide technical guidelines for clinical indications of use for general positioning, breast deep-inspiration breath hold treatment, and frameless stereotactic radiosurgery. Additionally, the task group was charged with providing commissioning and on-going quality assurance (QA) requirements for surface-guided radiation therapy (SGRT) as part of a comprehensive QA program including risk assessment. Workflow considerations for other anatomic sites and for computed tomography simulation, including motion management, are also discussed. Finally, developing clinical applications, such as stereotactic body radiotherapy (SBRT) or proton radiotherapy, are presented. The recommendations made in this report, which are summarized at the end of the report, are applicable to all video-based SGRT systems available at the time of writing.

Published

2022

31. 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

32. Three discipline collaborative radiation therapy (3DCRT) special debate: FLASH radiotherapy needs ongoing basic and animal research before implementing it to a large clinical scale

Author

Guerrieri, Patrizia, Jacob, Naduparambil K, Maxim, Peter G, Sawant, Amit, Van Nest, Samantha J, Mohindra, Pranshu, Dominello, Michael M, Burmeister, Jay W, and Joiner, Michael C

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Animal Experimentation, Animals, Humans, Longitudinal Studies, Radiation Oncology, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Conformal, Radiotherapy, Intensity-Modulated, Treatment Outcome, Other Physical Sciences, Clinical Sciences, Medical Physiology, Nuclear Medicine & Medical Imaging, Medical physiology, Medical and biological physics

Published

2022

33. Pre‐clinical and clinical evaluation of the HYPERSCINT plastic scintillation dosimetry research platform for in vivo dosimetry during radiotherapy

Author

Schoepper, Imke, Dieterich, Sonja, Trestrail, Earl Alonzo, and Kent, Michael Sean

Subjects

Medical and Biological Physics, Biomedical and Clinical Sciences, Clinical Sciences, Physical Sciences, Oncology and Carcinogenesis, Cancer, Bioengineering, Animals, Cadaver, Dogs, Humans, In Vivo Dosimetry, Plastics, Radiometry, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Scintillation Counting, In vivo dosimetry, plastic scintillators, Other Physical Sciences, Medical Physiology, Nuclear Medicine & Medical Imaging, Medical physiology, Medical and biological physics

Abstract

PurposeThe purpose of this work is to evaluate the Hyperscint-RP100 scintillation dosimetry research platform (Hyperscint-RP100, Medscint Inc., Quebec, QC, Canada) designed for clinical quality assurance (QA) for use in in vivo dosimetry measurements.MethodsThe pre-clinical evaluation of the scintillator was performed using a Varian TrueBeam linear accelerator. Dependency on field size, depth, dose, dose rate, and temperature were evaluated in a water tank and compared to calibration data from commissioning and annual QA. Angularity was evaluated with a 3D printed phantom. The clinical evaluation was first performed in two cadaver dogs, and then in three companion animal dogs receiving radiation therapy for nasal tumors. A treatment planning CT scan was performed for cadavers and clinical patients. Prior to treatment, the probe was inserted into the radiation field. Radiation was then delivered and measured with the scintillator. For cadavers, the treatment was repeated after making an intentional shift in patient position to simulate a treatment error.ResultsIn the preclinical measurements the dose differed from annual measurements as follows: field size -0.77 to 0.43%, depth dose -0.36 to 1.14%, dose -0.54 to 2.93%, dose rate 0.3 to 3.6%, and angularity -1.18 to 0.01%. Temperature dependency required a correction factor of 0.11%/°C. In the two cadavers, the dose differed by -1.17 to 0.91%. The device correctly detected the treatment error when the heads were intentionally laterally shifted. In three canine clinical patients treated in multiple fractions, the detected dose ranged from 98.33 to 103.15%.ConclusionResults of this new device are promising although more work is necessary to fully validate it for clinical dosimetry.

Published

2022

34. Model studies of the role of oxygen in the FLASH effect

Author

Favaudon, Vincent, Labarbe, Rudi, and Limoli, Charles L

Subjects

Electrons, Oxygen, Radiation Oncology, Radiotherapy Dosage, FLASH radiotherapy, oxygen, peroxyl radicals, radical recombination, Other Physical Sciences, Biomedical Engineering, Oncology and Carcinogenesis, Nuclear Medicine & Medical Imaging

Abstract

Current radiotherapy facilities are standardized to deliver dose rates around 0.1-0.4 Gy/s in 2 Gy daily fractions, designed to deliver total accumulated doses to reach the tolerance limit of normal tissues undergoing irradiation. FLASH radiotherapy (FLASH-RT), on the other hand, relies on facilities capable of delivering ultrahigh dose rates in large doses in a single microsecond pulse, or in a few pulses given over a very short time sequence. For example, most studies to date have implemented 4-6 MeV electrons with intra-pulse dose rates in the range 106 -107  Gy/s. The proposed dependence of the FLASH effect on oxygen tension has stimulated several theoretical models based on three different hypotheses: (i) Radiation-induced transient oxygen depletion; (ii) cell-specific differences in the ability to detoxify and/or recover from injury caused by reactive oxygen species; (iii) self-annihilation of radicals by bimolecular recombination. This article focuses on the observations supporting or refuting these models in the frame of the chemical-biological bases of the impact of oxygen on the radiation response of cell free, in vitro and in vivo model systems.

Published

2022

35. Ultra‐high dose rate electron beams and the FLASH effect: From preclinical evidence to a new radiotherapy paradigm

Author

Schüler, Emil, Acharya, Munjal, Montay‐Gruel, Pierre, Loo, Billy W, Vozenin, Marie‐Catherine, and Maxim, Peter G

Subjects

Animals, Clinical Protocols, Electrons, Radiotherapy, Radiotherapy Dosage, biological effects, electron FLASH, FLASH effect, dosimetry, reporting system, Other Physical Sciences, Biomedical Engineering, Oncology and Carcinogenesis, Nuclear Medicine & Medical Imaging

Abstract

In their seminal paper from 2014, Fauvadon et al. coined the term FLASH irradiation to describe ultra-high-dose rate irradiation with dose rates greater than 40 Gy/s, which results in delivery times of fractions of a second. The experiments presented in that paper were performed with a high-dose-per-pulse 4.5 MeV electron beam, and the results served as the basis for the modern-day field of FLASH radiation therapy (RT). In this article, we review the studies that have been published after those early experiments, demonstrating the robust effects of FLASH RT on normal tissue sparing in preclinical models. We also outline the various irradiation parameters that have been used. Although the robustness of the biological response has been established, the mechanisms behind the FLASH effect are currently under investigation in a number of laboratories. However, differences in the magnitude of the FLASH effect between experiments in different labs have been reported. Reasons for these differences even within the same animal model are currently unknown, but likely has to do with the marked differences in irradiation parameter settings used. Here, we show that these parameters are often not reported, which complicates large multistudy comparisons. For this reason, we propose a new standard for beam parameter reporting and discuss a systematic path to the clinical translation of FLASH RT.

Published

2022

36. Durvalumab plus tremelimumab alone or in combination with low-dose or hypofractionated radiotherapy in metastatic non-small-cell lung cancer refractory to previous PD(L)-1 therapy: an open-label, multicentre, randomised, phase 2 trial

Author

Schoenfeld, Jonathan D, Giobbie-Hurder, Anita, Ranasinghe, Srinika, Kao, Katrina Z, Lako, Ana, Tsuji, Junko, Liu, Yang, Brennick, Ryan C, Gentzler, Ryan D, Lee, Carrie, Hubbard, Joleen, Arnold, Susanne M, Abbruzzese, James L, Jabbour, Salma K, Uboha, Nataliya V, Stephans, Kevin L, Johnson, Jennifer M, Park, Haeseong, Villaruz, Liza C, Sharon, Elad, Streicher, Howard, Ahmed, Mansoor M, Lyon, Hayley, Cibuskis, Carrie, Lennon, Niall, Jhaveri, Aashna, Yang, Lin, Altreuter, Jennifer, Gunasti, Lauren, Weirather, Jason L, Mak, Raymond H, Awad, Mark M, Rodig, Scott J, Chen, Helen X, Wu, Catherine J, Monjazeb, Arta M, and Hodi, F Stephen

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Cancer, Clinical Research, Lung, Lung Cancer, Clinical Trials and Supportive Activities, 6.1 Pharmaceuticals, Evaluation of treatments and therapeutic interventions, 6.5 Radiotherapy and other non-invasive therapies, Aged, Antibodies, Monoclonal, Antibodies, Monoclonal, Humanized, Antineoplastic Combined Chemotherapy Protocols, Carcinoma, Non-Small-Cell Lung, Combined Modality Therapy, Female, Humans, Immune Checkpoint Inhibitors, Lung Neoplasms, Male, Middle Aged, Neoplasm Metastasis, Radiation Dose Hypofractionation, Radiotherapy Dosage, Oncology & Carcinogenesis, Oncology and carcinogenesis

Abstract

BackgroundPatients with non-small-cell lung cancer (NSCLC) that is resistant to PD-1 and PD-L1 (PD[L]-1)-targeted therapy have poor outcomes. Studies suggest that radiotherapy could enhance antitumour immunity. Therefore, we investigated the potential benefit of PD-L1 (durvalumab) and CTLA-4 (tremelimumab) inhibition alone or combined with radiotherapy.MethodsThis open-label, multicentre, randomised, phase 2 trial was done by the National Cancer Institute Experimental Therapeutics Clinical Trials Network at 18 US sites. Patients aged 18 years or older with metastatic NSCLC, an Eastern Cooperative Oncology Group performance status of 0 or 1, and progression during previous PD(L)-1 therapy were eligible. They were randomly assigned (1:1:1) in a web-based system by the study statistician using a permuted block scheme (block sizes of three or six) without stratification to receive either durvalumab (1500 mg intravenously every 4 weeks for a maximum of 13 cycles) plus tremelimumab (75 mg intravenously every 4 weeks for a maximum of four cycles) alone or with low-dose (0·5 Gy delivered twice per day, repeated for 2 days during each of the first four cycles of therapy) or hypofractionated radiotherapy (24 Gy total delivered over three 8-Gy fractions during the first cycle only), 1 week after initial durvalumab-tremelimumab administration. Study treatment was continued until 1 year or until progression. The primary endpoint was overall response rate (best locally assessed confirmed response of a partial or complete response) and, along with safety, was analysed in patients who received at least one dose of study therapy. The trial is registered with ClinicalTrials.gov, NCT02888743, and is now complete.FindingsBetween Aug 24, 2017, and March 29, 2019, 90 patients were enrolled and randomly assigned, of whom 78 (26 per group) were treated. This trial was stopped due to futility assessed in an interim analysis. At a median follow-up of 12·4 months (IQR 7·8-15·1), there were no differences in overall response rates between the durvalumab-tremelimumab alone group (three [11·5%, 90% CI 1·2-21·8] of 26 patients) and the low-dose radiotherapy group (two [7·7%, 0·0-16·3] of 26 patients; p=0·64) or the hypofractionated radiotherapy group (three [11·5%, 1·2-21·8] of 26 patients; p=0·99). The most common grade 3-4 adverse events were dyspnoea (two [8%] in the durvalumab-tremelimumab alone group; three [12%] in the low-dose radiotherapy group; and three [12%] in the hypofractionated radiotherapy group) and hyponatraemia (one [4%] in the durvalumab-tremelimumab alone group vs two [8%] in the low-dose radiotherapy group vs three [12%] in the hypofractionated radiotherapy group). Treatment-related serious adverse events occurred in one (4%) patient in the durvalumab-tremelimumab alone group (maculopapular rash), five (19%) patients in the low-dose radiotherapy group (abdominal pain, diarrhoea, dyspnoea, hypokalemia, and respiratory failure), and four (15%) patients in the hypofractionated group (adrenal insufficiency, colitis, diarrhoea, and hyponatremia). In the low-dose radiotherapy group, there was one death from respiratory failure potentially related to study therapy.InterpretationRadiotherapy did not increase responses to combined PD-L1 plus CTLA-4 inhibition in patients with NSCLC resistant to PD(L)-1 therapy. However, PD-L1 plus CTLA-4 therapy could be a treatment option for some patients. Future studies should refine predictive biomarkers in this setting.FundingThe US National Institutes of Health and the Dana-Farber Cancer Institute.

Published

2022

37. IMRT and SBRT Treatment Planning Study for the First Clinical Biology-Guided Radiotherapy System

Author

Pham, Daniel, Simiele, Eric, Breitkreutz, Dylan, Capaldi, Dante, Han, Bin, Surucu, Murat, Oderinde, Seyi, Vitzthum, Lucas, Gensheimer, Michael, Bagshaw, Hilary, Chin, Alex, Xing, Lei, Chang, DT, and Kovalchuk, Natalyia

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Cancer, Biology, Humans, Male, Organs at Risk, Radiosurgery, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Intensity-Modulated, Retrospective Studies, Dosimetry, radiation dosimetry, stereotactic body radiation therapy, stereotactic radiosurgery, stereotactic radiotherapy, Oncology & Carcinogenesis, Oncology and carcinogenesis

Abstract

Purpose: The first clinical biology-guided radiation therapy (BgRT) system-RefleXionTM X1-was installed and commissioned for clinical use at our institution. This study aimed at evaluating the treatment plan quality and delivery efficiency for IMRT/SBRT cases without PET guidance. Methods: A total of 42 patient plans across 6 cancer sites (conventionally fractionated lung, head, and neck, anus, prostate, brain, and lung SBRT) planned with the EclipseTM treatment planning system (TPS) and treated with either a TrueBeam® or Trilogy® were selected for this retrospective study. For each Eclipse VMAT plan, 2 corresponding plans were generated on the X1 TPS with 10 mm jaws (X1-10mm) and 20 mm jaws (X1-20mm) using our institutional planning constraints. All clinically relevant metrics in this study, including PTV D95%, PTV D2%, Conformity Index (CI), R50, organs-at-risk (OAR) constraints, and beam-on time were analyzed and compared between 126 VMAT and RefleXion plans using paired t-tests. Results: All but 3 planning metrics were either equivalent or superior for the X1-10mm plans as compared to the Eclipse VMAT plans across all planning sites investigated. The Eclipse VMAT and X1-10mm plans generally achieved superior plan quality and sharper dose fall-off superior/inferior to targets as compared to the X1-20mm plans, however, the X1-20mm plans were still considered acceptable for treatment. On average, the required beam-on time increased by a factor of 1.6 across all sites for X1-10mm compared to X1-20mm plans. Conclusions: Clinically acceptable IMRT/SBRT treatment plans were generated with the X1 TPS for both the 10 mm and 20 mm jaw settings.

Published

2022

38. A new platform for ultra-high dose rate radiobiological research using the BELLA PW laser proton beamline

Author

Bin, Jianhui, Obst-Huebl, Lieselotte, Mao, Jian-Hua, Nakamura, Kei, Geulig, Laura D, Chang, Hang, Ji, Qing, He, Li, De Chant, Jared, Kober, Zachary, Gonsalves, Anthony J, Bulanov, Stepan, Celniker, Susan E, Schroeder, Carl B, Geddes, Cameron GR, Esarey, Eric, Simmons, Blake A, Schenkel, Thomas, Blakely, Eleanor A, Steinke, Sven, and Snijders, Antoine M

Subjects

Physical Sciences, Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Radiation Oncology, Cancer, Cell Line, Humans, Lasers, Monte Carlo Method, Neoplasms, Proton Therapy, Radiobiology, Radiometry, Radiotherapy Dosage, Synchrotrons, ATAP-BELLA Center, ATAP-GENERAL

Abstract

Radiotherapy is the current standard of care for more than 50% of all cancer patients. Improvements in radiotherapy (RT) technology have increased tumor targeting and normal tissue sparing. Radiations at ultra-high dose rates required for FLASH-RT effects have sparked interest in potentially providing additional differential therapeutic benefits. We present a new experimental platform that is the first one to deliver petawatt laser-driven proton pulses of 2 MeV energy at 0.2 Hz repetition rate by means of a compact, tunable active plasma lens beamline to biological samples. Cell monolayers grown over a 10 mm diameter field were exposed to clinically relevant proton doses ranging from 7 to 35 Gy at ultra-high instantaneous dose rates of 107 Gy/s. Dose-dependent cell survival measurements of human normal and tumor cells exposed to LD protons showed significantly higher cell survival of normal-cells compared to tumor-cells for total doses of 7 Gy and higher, which was not observed to the same extent for X-ray reference irradiations at clinical dose rates. These findings provide preliminary evidence that compact LD proton sources enable a new and promising platform for investigating the physical, chemical and biological mechanisms underlying the FLASH effect.

Published

2022

39. Bladder surface dose modeling in prostate cancer radiotherapy: An analysis of motion‐induced variations and the cumulative dose across the treatment

Author

Lao, Yi, Cao, Minsong, Yang, Yingli, Kishan, Amar U, Yang, Wensha, Wang, Yalin, and Sheng, Ke

Subjects

Urologic Diseases, Clinical Research, Prostate Cancer, Cancer, Humans, Male, Prostatic Neoplasms, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Image-Guided, Radiotherapy, Intensity-Modulated, Urinary Bladder, bladder motions, prostate cancer, surface-based registration, surface dose model, Other Physical Sciences, Biomedical Engineering, Oncology and Carcinogenesis, Nuclear Medicine & Medical Imaging

Abstract

PurposeTo introduce a novel surface-based dose mapping method to improve quantitative bladder dosimetric assessment in prostate cancer (PC) radiotherapy.MethodsBased on the planning and daily pre and postfraction MRIs of 12 PC patients, bladder surface models (SMs) were generated on manually delineated contours and regionally aligned via surface-based registration. Subsequently, bladder surface dose models (SDMs) were created using face-wise dose sampling. To determine the bladder intrafractional and interfractional motion and dose variation, we performed a pose analysis between pre and postfraction bladder SMs, as well as surface mapping for fractional SMs. Discrepancies between the received dose, accumulated from daily SDMs, and the planned dose were then assessed on the corresponding SDMs. Complementary to the surface dose mapping, dose surface histogram (DSH)-based comparisons were also performed.ResultsThe intrafraction pose analysis revealed a significant (p

Published

2021

40. Radiotherapy of oligometastatic prostate cancer: a systematic review

Author

Rogowski, Paul, Roach, Mack, Schmidt-Hegemann, Nina-Sophie, Trapp, Christian, von Bestenbostel, Rieke, Shi, Run, Buchner, Alexander, Stief, Christian, Belka, Claus, and Li, Minglun

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Urologic Diseases, Prostate Cancer, Biomedical Imaging, Cancer, 4.2 Evaluation of markers and technologies, Detection, screening and diagnosis, Bone Neoplasms, Humans, Lymph Nodes, Lymphatic Metastasis, Male, Prostatic Neoplasms, Radiosurgery, Radiotherapy Dosage, ENRT, Metastasis‐directed therapy, Oligometastatic prostate cancer, Radiotherapy, SBRT, Oncology & Carcinogenesis, Clinical sciences, Oncology and carcinogenesis

Abstract

BackgroundDue to improved imaging sensitivity, the term "oligometastatic" prostate cancer disease is diagnosed more often, leading to an increasing interest in metastasis-directed therapy (MDT). There are two types of radiation based MDT applied when treating oligometastatic disease: (1) stereotactic body radiation therapy (SBRT) generally used for bone metastases; or (2) SBRT for isolated nodal oligometastases combined with prophylactic elective nodal radiotherapy. This review aims to summarize current evidence data, which may shed light on the optimal management of this heterogeneous group of patients.MethodsA systematic review of the Medline database through PubMed was performed according to PRISMA guidelines. All relevant studies published up to November 2020 were identified and screened. Fifty-six titles were included. Besides outcome parameters, different prognostic and predictive factors were assessed, including site of metastases, time between primary treatment and MDT, use of systemic therapies, hormone sensitivity, as well as pattern of recurrence.FindingsEvidence consists largely of retrospective case series and no consistent precise definition of oligometastasis exists, however, most investigators seem to acknowledge the need to distinguish between patients presenting with what is frequently called "synchronous" versus "metachronous" oligometastatic disease. Available data on radiotherapy as MDT demonstrate high local control rates and a small but relevant proportion of patients without progressive disease after 2 years. This holds true for both hormone sensitive and castration resistant prostate cancer diseases. The use of 68Ga-PSMA PET/CT for staging increased dramatically. Radiation doses and field sizes varied considerably among the studies. The search for relevant prognostic and predictive factors is ongoing.ConclusionsTo our best knowledge this review on oligometastatic prostate cancer included the largest number of original articles. It demonstrates the therapeutic potential and challenges of MDT for oligometastatic prostate cancer. Prospective studies are under way and will provide further high-level evidence.

Published

2021

41. Surgical complications and clinical outcomes after dose-escalated trimodality therapy for non-small cell lung cancer in the era of intensity-modulated radiotherapy

Author

Liu, Kevin X, Sierra-Davidson, Kailan, Tyan, Kevin, Orlina, Lawrence T, Marcoux, J Paul, Kann, Benjamin H, Kozono, David E, Mak, Raymond H, White, Abby, and Singer, Lisa

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Cancer, Lung Cancer, Clinical Research, Lung, Patient Safety, Evaluation of treatments and therapeutic interventions, 6.5 Radiotherapy and other non-invasive therapies, Aged, Carcinoma, Non-Small-Cell Lung, Chemoradiotherapy, Disease-Free Survival, Female, Humans, Lung Neoplasms, Radiotherapy Dosage, Radiotherapy, Intensity-Modulated, Retrospective Studies, Non-small cell lung cancer, Trimodality, Radiation, Intensity modulated radiotherapy, IMRT, Radiation dose, Other Physical Sciences, Oncology & Carcinogenesis, Clinical sciences, Oncology and carcinogenesis, Medical and biological physics

Abstract

BackgroundTrimodality therapy (TMT) with preoperative chemoradiation followed by surgical resection is used for locally-advanced non-small-cell lung cancer (LA-NSCLC). Traditionally, preoperative radiation doses ≤54 Gy are used due to concerns regarding excess morbidity, but little is known about outcomes and toxicities after TMT with intensity-modulated radiotherapy (IMRT) to higher doses.MethodsA retrospective analysis of patients who received planned TMT with IMRT for LA-NSCLC at Brigham and Women's Hospital/Dana-Farber Cancer Institute between 2008 and 2017 was performed. Clinical and treatment characteristics, pathologic response, and surgical toxicity were assessed. Kaplan-Meier method and log-rank test was used for survival outcomes. Cox proportional-hazards regression was used for multivariable analysis.ResultsForty-six patients received less than definitive doses of 7 days were associated with OS.ConclusionsWith IMRT, there was no increased rate of surgical complications in patients receiving higher doses of radiation. Survival outcomes or LOS did not differ based on radiation dose, but increased LOS was associated with worse OS. Larger prospective studies are needed to further examine outcomes after IMRT in patients with LA-NSCLC receiving TMT.

Published

2021

42. Simultaneous radiosurgery for multiple brain metastases: technical overview of the UCLA experience

Author

Agazaryan, Nzhde, Tenn, Steve, Lee, Chul, Steinberg, Michael, Hegde, John, Chin, Robert, Pouratian, Nader, Yang, Isaac, Kim, Won, and Kaprealian, Tania

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Bioengineering, Rare Diseases, Algorithms, Brain Neoplasms, Humans, Margins of Excision, Movement, Organs at Risk, Phantoms, Imaging, Prognosis, Radiosurgery, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Intensity-Modulated, Surgery, Computer-Assisted, Oncology & Carcinogenesis, Clinical sciences, Oncology and carcinogenesis

Abstract

Purpose/objective(s)To communicate our institutional experience with single isocenter radiosurgery treatments for multiple brain metastases, including challenges with determining planning target volume (PTV) margins and resulting consequences, image-guidance translational and rotational tolerances, intra-fraction patient motion, and prescription considerations with larger PTV margins.Materials/methodsEight patient treatments with 51 targets were planned with various margins using Elements Multiple Brain Mets SRS treatment planning software (Brainlab, Munich, Germany). Forty-eight plans with 0 mm, 1 mm and 2 mm margins were created, including plans with variable margins, where targets more than 6 cm away from the isocenter were planned with larger margins. The dosimetric impact of the margins were analyzed with V5Gy, V8Gy, V10Gy, V12Gy values. Additionally, 12 patient motion data were analyzed to determine both the impact of the repositioning threshold and the distributions of the patient translational and rotational movements.ResultsThe V5Gy, V8Gy, V10Gy, V12Gy volumes approximately doubled when margins change from 0 to 1 mm and tripled when change from 0 to 2 mm. With variable margins, the aggregated results are similar to results from plans using the lower of two margins, since only 12.2% of the targets were more than 6 cm away from the isocenter. With 0.5 mm re-positioning threshold, 57.4% of the time the patients are repositioned. Reducing the threshold to 0.25 mm results in 91.7% repositioning rate, due to limitations of the fusion algorithm and actual patient motion. The 90th percentile of translational movements in all directions is 0.7 mm, while the 90th percentile of rotational movements in all directions is 0.6 degrees. Median translations and rotations are 0.2 mm and 0.2 degrees, respectively.ConclusionsBased on the data presented, we have switched our modus operandi from 2 to 1 mm PTV margins, with an eventual goal of using 0.5 and 1.0 mm variable margins when an automated margin assignment method becomes available. The 0.5 mm and 0.5 degrees repositioning thresholds are clinically appropriate with small residual patient movements.

Published

2021

43. End of treatment cone-beam computed tomography (CBCT) is predictive of radiation response and overall survival in oropharyngeal squamous cell carcinoma

Author

Sumner, Whitney, Kim, Sangwoo S, Vitzthum, Lucas, Moore, Kevin, Atwood, Todd, Murphy, James, Miyauchi, Sayuri, Califano, Joseph A, Mell, Loren K, Mundt, Arno J, and Sharabi, Andrew B

Subjects

Rare Diseases, Cancer, Biomedical Imaging, Clinical Research, Dental/Oral and Craniofacial Disease, Detection, screening and diagnosis, 4.2 Evaluation of markers and technologies, Adult, Aged, Aged, 80 and over, Carcinoma, Squamous Cell, Cone-Beam Computed Tomography, Female, Follow-Up Studies, Humans, Image Processing, Computer-Assisted, Male, Middle Aged, Organs at Risk, Oropharyngeal Neoplasms, Prognosis, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Image-Guided, Radiotherapy, Intensity-Modulated, Retrospective Studies, Survival Rate, Head and neck squamous cell carcinoma, Head and neck cancer, Radiotherapy, Radiation, Cone beam CT, CBCT, Oncology and Carcinogenesis, Oncology & Carcinogenesis

Abstract

BackgroundImage guidance in radiation oncology has resulted in significant improvements in the accuracy and precision of radiation therapy (RT). Recently, the resolution and quality of cone beam computed tomography (CBCT) for image guidance has increased so that tumor masses and lymph nodes are readily detectable and measurable. During treatment of head and neck squamous cell carcinoma (HNSCC), on-board CBCT setup imaging is routinely obtained; however, this CBCT imaging data is not utilized to predict patient outcomes. Here, we analyzed whether changes in CBCT measurements obtained during a course of radiation therapy correlate with responses on routine 3-month follow-up diagnostic imaging and overall survival (OS).Materials/methodsPatients with oropharyngeal primary tumors who received radiation therapy between 2015 and 2018 were included. Anatomical measurements were collected of largest nodal conglomerate (LNC) at CT simulation, end of radiation treatment (EOT CBCT), and routine 3-month post-RT imaging. At each timepoint anteroposterior (AP), mediolateral (ML) and craniocaudal (CC) measurements were obtained and used to create a 2-dimensional (2D) maximum.ResultsCBCT data from 64 node positive patients were analyzed. The largest nodal 2D maximum and CC measurements on EOT CBCT showed a statistically significant correlation with complete response on 3-month post-RT imaging (r = 0.313, p = 0.02 and r = 0.318, p = 0.02, respectively). Furthermore, patients who experienced a 30% or greater reduction in the CC dimension had improved OS (Binary Chi-Square HR 4.85, p = 0.028).ConclusionDecreased size of pathologic lymph nodes measured using CBCT setup imaging during a radiation course correlates with long term therapeutic response and overall survival of HNSCC patients. These results indicate that CBCT setup imaging may have utility as an early predictor of treatment response in oropharyngeal HNSCC.

Published

2021

44. Dose Summation Strategies for External Beam Radiation Therapy and Brachytherapy in Gynecologic Malignancy: A Review from the NRG Oncology and NCTN Medical Physics Subcommittees

Author

Kim, Hayeon, Lee, Yongsook C, Benedict, Stanley H, Dyer, Brandon, Price, Michael, Rong, Yi, Ravi, Ananth, Leung, Eric, Beriwal, Sushil, Bernard, Mark E, Mayadev, Jyoti, Leif, Jessica RL, and Xiao, Ying

Subjects

Clinical Research, Clinical Trials and Supportive Activities, Cancer, Biological Products, Brachytherapy, Female, Humans, Physics, Radiotherapy Dosage, Uterine Cervical Neoplasms, Other Physical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Oncology & Carcinogenesis

Abstract

Definitive, nonsurgical management of gynecologic malignancies involves external beam radiation therapy (EBRT) and/or brachytherapy (BT). Summation of the cumulative dose is critical to assess the total biologic effective dose to targets and organs at risk. Cumulative dose calculation from EBRT and BT can be performed with or without image registration (IR) and biologic dose summation. Among these dose summation strategies, linear addition of dose-volume histogram (DVH) parameters without IR is the global standard for composite dose reporting. This approach stems from an era without image guidance and simple external beam and brachytherapy treatment approaches. With technological advances, EBRT and high-dose-rate BT have evolved to allow for volume-based treatment planning and delivery. Modern conformal therapeutic radiation involves volumetric or intensity modulated EBRT, capable of simultaneously treating multiple targets at different specified dose levels. Therefore, given the complexity of modern radiation treatment, the linear addition of DVH parameters from EBRT and high-dose-rate BT is challenging to represent the combined dose distribution. Deformable image registration (DIR) between EBRT and image guided brachytherapy (IGBT) data sets may provide a more nuanced calculation of multimodal dose accumulation. However, DIR is still nascent in this regard, and needs further development for accuracy and efficiency for clinical use. Biologic dose summation can combine physical dose maps from EBRT and each IGBT fraction, thereby generating a composite DVH from the biologic effective dose. However, accurate radiobiologic parameters are tissue-dependent and not well characterized. A combination of voxel-based DIR and biologic weighted dose maps may be the best approximation of dose accumulation but remains invalidated. The purpose of this report is to review dose summation strategies for EBRT and BT, including conventional equivalent dose in 2-Gy fractions dose summation without image registration, physical dose summation using 3-dimensional rigid IR and DIR, and biologic dose summation. We also provide general clinical workflows for IGBT with a focus on cervical cancer.

Published

2021

45. Knowledge-based dose prediction models to inform gynecologic brachytherapy needle supplementation for locally advanced cervical cancer

Author

Kallis, Karoline, Mayadev, Jyoti, Kisling, Kelly, Brown, Derek, Scanderbeg, Daniel, Ray, Xenia, Cortes, Katherina, Simon, Aaron, Yashar, Catheryn M, Einck, John P, Mell, Loren K, Moore, Kevin L, and Meyers, Sandra M

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Cancer, Brachytherapy, Dietary Supplements, Female, Humans, Needles, Radiotherapy Dosage, Uterine Cervical Neoplasms, knowledge-based, Dose prediction, Cervix cancer, Needle supplementation, Clinical Sciences, Oncology & Carcinogenesis, Clinical sciences

Abstract

PurposeThe use of interstitial needles, combined with intracavitary applicators, enables customized dose distributions and is beneficial for complex cases, but increases procedure time. Overall, applicator selection is not standardized and depends on physician expertise and preference. The purpose of this study is to determine whether dose prediction models can guide needle supplementation decision-making for cervical cancer.Materials and methodsIntracavitary knowledge-based models for organ-at-risk (OAR) dose estimation were trained and validated for tandem-and-ring/ovoids (T&R/T&O) implants. Models were applied to hybrid cases with 1-3 implanted needles to predict OAR dose without needles. As a reference, 70/67 hybrid T&R/T&O cases were replanned without needles, following a standardized procedure guided by dose predictions. If a replanned dose exceeded the dose objective, the case was categorized as requiring needles. Receiver operating characteristic (ROC) curves of needle classification accuracy were generated. Optimal classification thresholds were determined from the Youden Index.ResultsNeedle supplementation reduced dose to OARs. However, 67%/39% of replans for T&R/T&O met all dose constraints without needles. The ROC for T&R/T&O models had an area-under-curve of 0.89/0.86, proving high classification accuracy. The optimal threshold of 99%/101% of the dose limit for T&R/T&O resulted in classification sensitivity and specificity of 78%/86% and 85%/78%.ConclusionsNeedle supplementation reduced OAR dose for most cases but was not always required to meet standard dose objectives, particularly for T&R cases. Our knowledge-based dose prediction model accurately identified cases that could have met constraints without needle supplementation, suggesting that such models may be beneficial for applicator selection.

Published

2021

46. Evaluation of dose differences between intracavitary applicators for cervical brachytherapy using knowledge-based models

Author

Kallis, Karoline, Mayadev, Jyoti, Covele, Brent, Brown, Derek, Scanderbeg, Daniel, Simon, Aaron, Frisbie-Firsching, Helena, Yashar, Catheryn M, Einck, John P, Mell, Loren K, Moore, Kevin L, and Meyers, Sandra M

Subjects

Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Cancer, Cervical Cancer, Clinical Research, Urologic Diseases, Good Health and Well Being, Brachytherapy, Female, Humans, Organs at Risk, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Rectum, Uterine Cervical Neoplasms, Knowledge-based planning, Dose prediction, Cervical cancer, Intracavitary brachytherapy, Tandem and ovoids, Tandem and ring, Clinical Sciences, Oncology & Carcinogenesis, Clinical sciences

Abstract

PurposeCurrently, there is a lack of patient-specific tools to guide brachytherapy planning and applicator choice for cervical cancer. The purpose of this study is to evaluate the accuracy of organ-at-risk (OAR) dose predictions using knowledge-based intracavitary models, and the use of these models and clinical data to determine the dosimetric differences of tandem-and-ring (T&R) and tandem-and-ovoids (T&O) applicators.Materials and methodsKnowledge-based models, which predict organ D2cc, were trained on 77/75 cases and validated on 32/38 for T&R/T&O applicators. Model performance was quantified using ΔD2cc=D2cc,actual-D2cc,predicted, with standard deviation (σ(ΔD2cc)) representing precision. Model-predicted applicator dose differences were determined by applying T&O models to T&R cases, and vice versa, and compared to clinically-achieved D2cc differences. Applicator differences were assessed using a Student's t-test (p < 0.05 significant).ResultsValidation T&O/T&R model precision was 0.65/0.55 Gy, 0.55/0.38 Gy, and 0.43/0.60 Gy for bladder, rectum and sigmoid, respectively, and similar to training. When applying T&O/T&R models to T&R/T&O cases, bladder, rectum and sigmoid D2cc values in EQD2 were on average 5.69/2.62 Gy, 7.31/6.15 Gy and 3.65/0.69 Gy lower for T&R, with similar HRCTV volume and coverage. Clinical data also showed lower T&R OAR doses, with mean EQD2 D2cc deviations of 0.61 Gy, 7.96 Gy (p < 0.01) and 5.86 Gy (p < 0.01) for bladder, rectum and sigmoid.ConclusionsAccurate knowledge-based dose prediction models were developed for two common intracavitary applicators. These models could be beneficial for standardizing and improving the quality of brachytherapy plans. Both models and clinical data suggest that significant OAR sparing can be achieved with T&R over T&O applicators, particularly for the rectum.

Published

2021

47. Outcome of dose-escalated intensity-modulated radiotherapy for limited disease small cell lung cancer.

Author

Eunyeong Yang, Young Seob Shin, Ji Hyeon Joo, Wonsik Choi, Su Ssan Kim, Eun Kyung Choi, Jaeha Lee, and Si Yeol Song

Subjects

*SMALL cell lung cancer, *INTENSITY modulated radiotherapy, *RADIOTHERAPY

Abstract

Purpose: An optimal once-daily radiotherapy (RT) regimen is under investigation for definitive concurrent chemoradiotherapy (CCRT) in limited disease small cell lung cancer (LD-SCLC). We compared the efficacy and safety of dose escalation with intensity-modulated radiotherapy (IMRT). Materials and Methods: Between January 2016 and March 2021, patients treated with definitive CCRT for LD-SCLC with IMRT were retrospectively reviewed. Patients who received a total dose <50 Gy or those with a history of thoracic RT or surgery were excluded. The patients were divided into two groups (standard and dose-escalated) based on the total biologically effective dose (BED, α/β = 10) of 70 Gy. The chemotherapeutic regimen comprised four cycles of etoposide and cisplatin. Results: One hundred and twenty-two patients were analyzed and the median follow-up was 27.8 months (range, 4.4 to 76.9 months). The median age of the patients was 63 years (range, 35 to 78 years) and the majority had a history of smoking (86.0%). The 1- and 3-year overall survival rates of the escalated dose group were significantly higher than those of the standard group (93.5% and 50.5% vs. 76.7% and 33.3%, respectively; p = 0.008), as were the 1- and 3-year freedom from infield failure rates (91.4% and 66.5% vs. 73.8% and 46.9%, respectively; p = 0.018). The incidence of grade 2 or higher acute and late pneumonitis was not significantly different between the two groups (p = 0.062, 0.185). Conclusion: Dose-escalated once-daily CCRT with IMRT led to improved locoregional control and survival, with no increase in toxicity. [ABSTRACT FROM AUTHOR]

Published

2023

48. Findings of the AAPM Ad Hoc committee on magnetic resonance imaging in radiation therapy: Unmet needs, opportunities, and recommendations

Author

McGee, Kiaran P, Tyagi, Neelam, Bayouth, John E, Cao, Minsong, Fallone, B Gino, Glide‐Hurst, Carri K, Goerner, Frank L, Green, Olga L, Kim, Taeho, Paulson, Eric S, Yanasak, Nathan E, Jackson, Edward F, Goodwin, James H, Dieterich, Sonja, Jordan, David W, Hugo, Geoffrey D, Bernstein, Matt A, Balter, James M, Kanal, Kalpana M, Hazle, John D, and Pelc, Norbert J

Subjects

Biomedical Imaging, Clinical Research, Humans, Magnetic Resonance Imaging, Particle Accelerators, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Image-Guided, United States, biomarker, magnetic resonance, MRgRT, radiation therapy, safety, simulation, Other Physical Sciences, Biomedical Engineering, Oncology and Carcinogenesis, Nuclear Medicine & Medical Imaging

Abstract

The past decade has seen the increasing integration of magnetic resonance (MR) imaging into radiation therapy (RT). This growth can be contributed to multiple factors, including hardware and software advances that have allowed the acquisition of high-resolution volumetric data of RT patients in their treatment position (also known as MR simulation) and the development of methods to image and quantify tissue function and response to therapy. More recently, the advent of MR-guided radiation therapy (MRgRT) - achieved through the integration of MR imaging systems and linear accelerators - has further accelerated this trend. As MR imaging in RT techniques and technologies, such as MRgRT, gain regulatory approval worldwide, these systems will begin to propagate beyond tertiary care academic medical centers and into more community-based health systems and hospitals, creating new opportunities to provide advanced treatment options to a broader patient population. Accompanying these opportunities are unique challenges related to their adaptation, adoption, and use including modification of hardware and software to meet the unique and distinct demands of MR imaging in RT, the need for standardization of imaging techniques and protocols, education of the broader RT community (particularly in regards to MR safety) as well as the need to continue and support research, and development in this space. In response to this, an ad hoc committee of the American Association of Physicists in Medicine (AAPM) was formed to identify the unmet needs, roadblocks, and opportunities within this space. The purpose of this document is to report on the major findings and recommendations identified. Importantly, the provided recommendations represent the consensus opinions of the committee's membership, which were submitted in the committee's report to the AAPM Board of Directors. In addition, AAPM ad hoc committee reports differ from AAPM task group reports in that ad hoc committee reports are neither reviewed nor ultimately approved by the committee's parent groups, including at the council and executive committee level. Thus, the recommendations given in this summary should not be construed as being endorsed by or official recommendations from the AAPM.

Published

2021

49. Phase 3 Multi-Center, Prospective, Randomized Trial Comparing Single-Dose 24 Gy Radiation Therapy to a 3-Fraction SBRT Regimen in the Treatment of Oligometastatic Cancer

Author

Zelefsky, Michael J, Yamada, Yoshiya, Greco, Carlo, Lis, Eric, Schöder, Heiko, Lobaugh, Stephanie, Zhang, Zhigang, Braunstein, Steve, Bilsky, Mark H, Powell, Simon N, Kolesnick, Richard, and Fuks, Zvi

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Cancer, Clinical Research, Clinical Trials and Supportive Activities, Biomedical Imaging, Adult, Aged, Humans, Male, Middle Aged, Neoplasm Metastasis, Neoplasms, Radiation Dosage, Radiosurgery, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted, Other Physical Sciences, Oncology & Carcinogenesis, Oncology and carcinogenesis, Theoretical and computational chemistry, Medical and biological physics

Abstract

PurposeThis prospective phase 3 randomized trial was designed to test whether ultra high single-dose radiation therapy (24 Gy SDRT) improves local control of oligometastatic lesions compared to a standard hypofractionated stereotactic body radiation therapy regimen (3 × 9 Gy SBRT). The secondary endpoint was to assess the associated toxicity and the impact of ablation on clinical patterns of metastatic progression.Methods and materialsBetween November 2010 and September 2015, 117 patients with 154 oligometastatic lesions (≤5/patient) were randomized in a 1:1 ratio to receive 24 Gy SDRT or 3 × 9 Gy SBRT. Local control within the irradiated field and the state of metastatic spread were assessed by periodic whole-body positron emission tomography/computed tomography and/or magnetic resonance imaging. Median follow-up was 52 months.ResultsA total of 59 patients with 77 lesions were randomized to 24 Gy SDRT and 58 patients with 77 lesions to 3 × 9 Gy SBRT. The cumulative incidence of local recurrence for SDRT-treated lesions was 2.7% (95% confidence interval [CI], 0%-6.5%) and 5.8% (95% CI, 0.2%-11.5%) at years 2 and 3, respectively, compared with 9.1% (95% CI, 2.6%-15.6%) and 22% (95% CI, 11.9%-32.1%) for SBRT-treated lesions (P = .0048). The 2- and 3-year cumulative incidences of distant metastatic progression in the SDRT patients were 5.3% (95% CI, 0%-11.1%), compared with 10.7% (95% CI, 2.5%-18.8%) and 22.5% (95% CI, 11.1%-33.9%), respectively, for the SBRT patients (P = .010). No differences in toxicity were observed.ConclusionsThe study confirms SDRT as a superior ablative treatment, indicating that effective ablation of oligometastatic lesions is associated with significant mitigation of distant metastatic progression.

Published

2021

50. National variation in the delivery of radiation oncology procedures in the non-facility-based setting.

Author

Valle, Luca F, Chu, Fang-I, Kundu, Palak, Yoon, Stephanie M, Gilchrist, Travis, Steinberg, Michael L, and Raldow, Ann C

Subjects

Humans, Radiotherapy, Brachytherapy, Radiosurgery, Radiotherapy, Conformal, Radiotherapy Dosage, Odds Ratio, Regression Analysis, Radiation Oncology, Sex Factors, Clinical Competence, Databases, Factual, Medicare, Professional Practice Location, United States, Female, Male, Radiotherapy, Intensity-Modulated, Practice Patterns, Physicians', Radiation Oncologists, Centers for Medicare and Medicaid Services, U.S., behavioral science, clinical management, radiation therapy, radiotherapy, registries, Cancer, Clinical Research, Biochemistry and Cell Biology, Oncology and Carcinogenesis

Abstract

PurposeThough utilization of medical procedures has been shown to vary considerably across the United States, similar efforts to characterize variation in the delivery of radiation therapy (RT) procedures have not been forthcoming. Our aim was to characterize variation in the delivery of common RT procedures in the Medicare population. We hypothesized that delivery would vary significantly based on provider characteristics.MethodsThe Centers for Medicare and Medicaid Services (CMS) Physician and Other Supplier Public Use File was linked to the CMS Physician Compare (PC) database by physician NPI to identify and sum all treatment delivery charges submitted by individual radiation oncologists in the non-facility-based (NFB) setting in 2016. Multivariable logistic regression analysis was carried out to determine provider characteristics (gender, practice rurality, practice region, and years since graduation) that predicted for the delivery of 3D conformal RT (3DCRT), intensity modulated RT (IMRT), stereotactic body RT (SBRT), stereotactic radiosurgery (SRS), low dose rate (LDR) brachytherapy, and high dose rate (HDR) brachytherapy delivery in the Medicare patient population. The overall significance of categorical variables in the multivariable logistic regression model was assessed by the likelihood ratio test (LRT).ResultsIn total, 1,802 physicians from the NFB practice setting were analyzed. Male gender predicted for greater LDR brachytherapy delivery (OR 8.19, 95% CI 2.58-26.05, p

Published

2021