Search

Your search keyword '"Hoogeman, Mischa"' showing total 588 results
Start Over Author "Hoogeman, Mischa"
588 results on '"Hoogeman, Mischa"'

1. A probabilistic deep learning model of inter-fraction anatomical variations in radiotherapy

Author

Pastor-Serrano, Oscar, Habraken, Steven, Hoogeman, Mischa, Lathouwers, Danny, Schaart, Dennis, Nomura, Yusuke, Xing, Lei, and Perkó, Zoltán

Subjects
Physics - Medical Physics
Abstract

In radiotherapy, the internal movement of organs between treatment sessions causes errors in the final radiation dose delivery. Motion models can be used to simulate motion patterns and assess anatomical robustness before delivery. Traditionally, such models are based on principal component analysis (PCA) and are either patient-specific (requiring several scans per patient) or population-based, applying the same deformations to all patients. We present a hybrid approach which, based on population data, allows to predict patient-specific inter-fraction variations for an individual patient. We propose a deep learning probabilistic framework that generates deformation vector fields (DVFs) warping a patient's planning computed tomography (CT) into possible patient-specific anatomies. This daily anatomy model (DAM) uses few random variables capturing groups of correlated movements. Given a new planning CT, DAM estimates the joint distribution over the variables, with each sample from the distribution corresponding to a different deformation. We train our model using dataset of 312 CT pairs from 38 prostate cancer patients. For 2 additional patients (22 CTs), we compute the contour overlap between real and generated images, and compare the sampled and ground truth distributions of volume and center of mass changes. With a DICE score of 0.86 and a distance between prostate contours of 1.09 mm, DAM matches and improves upon PCA-based models. The distribution overlap further indicates that DAM's sampled movements match the range and frequency of clinically observed daily changes on repeat CTs. Conditioned only on a planning CT and contours of a new patient without any pre-processing, DAM can accurately predict CTs seen during following treatment sessions, which can be used for anatomically robust treatment planning and robustness evaluation against inter-fraction anatomical changes.

Published
2022
Full Text
View/download PDF

25. Response to the letter-to-the-editor “Comments on: Accounting for fractionation and heterogeneous dose distributions in the modelling of osteoradionecrosis in oropharyngeal carcinoma treatment’’

Author

Verduijn, Gerda M., primary, Sijtsema, Nienke D., additional, van Norden, Yvette, additional, Heemsbergen, Wilma D., additional, Mast, Hetty, additional, Sewnaik, Aniel, additional, Chin, Denzel, additional, Baker, Sarah, additional, Capala, Marta E., additional, van der Lugt, Aad, additional, van Meerten, Esther, additional, Hoogeman, Mischa S., additional, and Petit, Steven F., additional

Published
2023
Full Text
View/download PDF

28. Evaluation of Multi-metric Registration for Online Adaptive Proton Therapy of Prostate Cancer

Author

Elmahdy, Mohamed S., Jagt, Thyrza, Yousefi, Sahar, Sokooti, Hessam, Zinkstok, Roel, Hoogeman, Mischa, Staring, Marius, Hutchison, David, Series Editor, Kanade, Takeo, Series Editor, Kittler, Josef, Series Editor, Kleinberg, Jon M., Series Editor, Mattern, Friedemann, Series Editor, Mitchell, John C., Series Editor, Naor, Moni, Series Editor, Pandu Rangan, C., Series Editor, Steffen, Bernhard, Series Editor, Terzopoulos, Demetri, Series Editor, Tygar, Doug, Series Editor, Weikum, Gerhard, Series Editor, Klein, Stefan, editor, Staring, Marius, editor, Durrleman, Stanley, editor, and Sommer, Stefan, editor

Published
2018
Full Text
View/download PDF

34. Multi‐institutional consensus on machine QA for isochronous cyclotron‐based systems delivering ultra‐high dose rate (FLASH) pencil beam scanning proton therapy in transmission mode.

Author

Spruijt, Kees, Mossahebi, Sina, Lin, Haibo, Lee, Eunsin, Kraus, James, Dhabaan, Anees, Poulsen, Per, Lowe, Matthew, Ayan, Ahmet, Spiessens, Sylvie, Godart, Jeremy, and Hoogeman, Mischa

Subjects
PROTON beams, PROTON therapy, QUALITY assurance standards, MACHINERY
Abstract

Background: The first clinical trials to assess the feasibility of FLASH radiotherapy in humans have started (FAST‐01, FAST‐02) and more trials are foreseen. To increase comparability between trials it is important to assure treatment quality and therefore establish a standard for machine quality assurance (QA). Currently, the AAPM TG‐224 report is considered as the standard on machine QA for proton therapy, however, it was not intended to be used for ultra‐high dose rate (UHDR) proton beams, which have gained interest due to the observation of the FLASH effect. Purpose: The aim of this study is to find consensus on practical guidelines on machine QA for UHDR proton beams in transmission mode in terms of which QA is required, how they should be done, which detectors are suitable for UHDR machine QA, and what tolerance limits should be applied. Methods: A risk assessment to determine the gaps in the current standard for machine QA was performed by an international group of medical physicists. Based on that, practical guidelines on how to perform machine QA for UHDR proton beams were proposed. Results: The risk assessment clearly identified the need for additional guidance on temporal dosimetry, addressing dose rate (constancy), dose spillage, and scanning speed. In addition, several minor changes from AAPM TG‐224 were identified; define required dose rate levels, the use of clinically relevant dose levels, and the use of adapted beam settings to minimize activation of detector and phantom materials or to avoid saturation effects of specific detectors. The final report was created based on discussions and consensus. Conclusions: Consensus was reached on what QA is required for UHDR scanning proton beams in transmission mode for isochronous cyclotron‐based systems and how they should be performed. However, the group discussions also showed that there is a lack of high temporal resolution detectors and sufficient QA data to set appropriate limits for some of the proposed QA procedures. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

41. Trade-off in healthy tissue sparing of FLASH and fractionation in stereotactic proton therapy of lung lesions with transmission beams

Author

Habraken, Steven, Breedveld, Sebastiaan, Groen, Jort, Nuyttens, Joost, Hoogeman, Mischa, and Radiation Oncology

Subjects
Lung Neoplasms, SDG 3 - Good Health and Well-being, Oncology, Radiotherapy Planning, Computer-Assisted, Proton Therapy, Humans, Radiotherapy Dosage, Radiology, Nuclear Medicine and imaging, Radiotherapy, Intensity-Modulated, Hematology, Protons, Radiosurgery, Lung
Abstract

Purpose and objective: Besides a dose-rate threshold of 40–100 Gy/s, the FLASH effect may require a dose > 3.5–7 Gy. Even in hypofractioned treatments, with all beams delivered in each fraction (ABEF), most healthy tissue is irradiated to a lower fraction dose. This can be circumvented by single-beam-per-fraction (SBPF) delivery, with a loss of healthy tissue sparing by fractionation. We investigated the trade-off between FLASH and loss of fractionation in SBPF stereotactic proton therapy of lung cancer and determined break-even FLASH-enhancement ratios (FERs). Materials and Methods: Treatment plans for 12 patients were generated. GTV delineations were available and a 5 mm GTV-PTV margin was applied. Equiangular arrangements of 3, 5, 7, and 9 244 MeV proton transmission beams were used. To facilitate SBPF, the number of fractions was equal to the number of beams. Iso-effective fractionation schedules with a single field uniform dose prescription were used: D95%,PTV = 100%Dpres per beam. All plans were evaluated in terms of dose to lung and conformity of dose to target of FLASH-enhanced biologically equivalent dose (EQD2). Results: Compared to ABEF, SBPF resulted in a median increase of EQD2mean to healthy lung of 56%, 58%, 55% and 54% in plans with 3, 5, 7 and 9 fractions respectively and of 236%, 78%, 50% and 41% in V100% EQD2, quantifying conformity. This can be compensated for by FERs of at least 1.28, 1.32, 1.30 and 1.23 respectively for EQD2mean and 1.29, 1.18, 1.28 and 1.15 for V100%,EQD2. Conclusion: A FLASH effect outweighing the loss of fractionation in SBPF may be achieved in stereotactic lung treatments. The trade-off with fractionation depends on the conditions under which the FLASH effect occurs. Better understanding of the underlying biology and the impact of delivery conditions is needed.

Published
2022

46. HYpofractionated, Dose-redistributed RAdiotherapy with protons and photons to combat radiation-induced immunosuppression in head and neck squamous cell carcinoma: study protocol of the phase-I HYDRA trial

Author

Elbers, Joris B.W., primary, Gunsch, Pascal A., additional, Vulpen, Marco van, additional, Debets, Reno, additional, Keereweer, Stijn, additional, Meerten, Esther van, additional, Zindler, Jaap, additional, Norden, Yvette van, additional, Hoogeman, Mischa, additional, Verduijn, Gerda M., additional, Kroesen, Michiel, additional, and Nout, Remi A., additional

Published
2023
Full Text
View/download PDF

48. Post radiation mucosal ulcer risk after a hypofractionated stereotactic boost and conventional fractionated radiotherapy for oropharyngeal carcinoma

Author

Verduijn, Gerda M., primary, Petit, Steven F., additional, Lauwers, Iris, additional, van Norden, Yvette, additional, Sijtsema, Nienke D., additional, Sewnaik, Aniel, additional, Mast, Hetty, additional, Capala, Marta, additional, Nout, Remi, additional, Baker, Sarah, additional, van Meerten, Esther, additional, Hoogeman, Mischa S., additional, van der Lugt, Aad, additional, and Heemsbergen, Wilma D., additional

Published
2022
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results