3D Monte Carlo dosimetry of intraoperative electron radiation therapy (IOERT)

Alhamada, Husein; Simon, Stéphane; Philippson, C.; Vandekerkhove, C.; Jourani, Y.; Pauly, Nicolas; Gestel, Dirk Van; Reynaert, N.

doi:10.1016/j.ejmp.2018.12.037

Cited by 11 publications

(8 citation statements)

References 27 publications

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“…Currently, there are dedicated UHDR HEE devices [11,12,[19][20][21]26] and converted medical linacs repurposed for UHDR HEE [13,14] (see Figure 2), albeit often with beam characteristics different from those used to treat patients. For example, some UHDR machines produce Gaussian beams with FWHM that can range from a few to about 15 cm, or even more [27][28][29][30]. Others produce smaller but flat beams for preclinical treatments and in vivo studies.…”

Section: Uhdr Hee Delivery Techniques and Challengesmentioning

confidence: 99%

“…Computer speed has increased enough to make MC methods become the gold standard for electron linac treatment head simulations, beam modelling in the TPS, and dose calculation of electron beams in patient anatomies [55]. Consequently, approaches based on MC methods are well established for HEE RT for these tasks and most recent research and clinical HEE beam models apply MC codes for particle transport in the treatment head as well as particle transport and dose computations in the patient [16,28,29,55,56].…”

Section: Beam Models Of Hee Rtmentioning

confidence: 99%

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FLASH radiotherapy treatment planning and models for electron beams

Rahman

Trigilio

Franciosini

et al. 2022

Radiotherapy and Oncology

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Section: Uhdr Hee Delivery Techniques and Challengesmentioning

confidence: 99%

Section: Beam Models Of Hee Rtmentioning

confidence: 99%

FLASH radiotherapy treatment planning and models for electron beams

Rahman

Trigilio

Franciosini

et al. 2022

Radiotherapy and Oncology

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“…Nonetheless, dose calculation algorithms in current systems may lack the accuracy that characterizes analogous devices dedicated to EBRT. Monte Carlo dose calculation is currently implemented in treatment planning systems dedicated to electron-beam IORT [ 4 , 5 , 6 , 9 , 10 ]. However, most systems still employ suboptimal, simplified algorithms that cannot guarantee a dosimetric accuracy at the same level of systems developed for advanced photon-beam modulated techniques.…”

Section: Current Technologymentioning

confidence: 99%

“…The time is probably ripe for a change. Availability of accurate dose calculation algorithms for clinical use, such as real-time Monte Carlo calculation [ 4 , 5 , 6 ], the prospected coming of radically new irradiation schemes such as FLASH therapy [ 7 ], and the possibility to use in-room imaging [ 8 ] call for an evolution of treatment planning systems in IORT.…”

Section: Introductionmentioning

confidence: 99%

Treatment Planning in Intraoperative Radiation Therapy (IORT): Where Should We Go?

Cavedon

Mazzarotto

2022

Cancers

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As opposed to external beam radiation therapy (EBRT), treatment planning systems (TPS) dedicated to intraoperative radiation therapy (IORT) were not subject to radical modifications in the last two decades. However, new treatment regimens such as ultrahigh dose rates and combination with multiple treatment modalities, as well as the prospected availability of dedicated in-room imaging, call for important new features in the next generation of treatment planning systems in IORT. Dosimetric accuracy should be guaranteed by means of advanced dose calculation algorithms, capable of modelling complex scattering phenomena and accounting for the non-tissue equivalent materials used to shape and compensate electron beams. Kilovoltage X-ray based IORT also presents special needs, including the correct description of extremely steep dose gradients and the accurate simulation of applicators. TPSs dedicated to IORT should also allow real-time imaging to be used for treatment adaptation at the time of irradiation. Other features implemented in TPSs should include deformable registration and capability of radiobiological planning, especially if unconventional irradiation schemes are used. Finally, patient safety requires that the multiple features be integrated in a comprehensive system in order to facilitate control of the whole process.

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“…A further step in IOERT dose calculation involves the use of a specific commercial treatment planning system (TPS) [4,5] or other solutions developed for this purpose [6] that take account of tissue heterogeneity by means of computed tomography (CT) studies. However, the actual treatment field can deviate from that foreseen in the TPS when using preoperative CT studies owing to variations in the patient's position, surgical access, tumour resection and IOERT parameters.…”

Section: Introductionmentioning

confidence: 99%

Intraoperative computed tomography imaging for dose calculation in intraoperative electron radiation therapy: Initial clinical observations

et al. 2020

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In intraoperative electron radiation therapy (IOERT) the energy of the electron beam is selected under the conventional assumption of water-equivalent tissues at the applicator end. However, the treatment field can deviate from the theoretic flat irradiation surface, thus altering dose profiles. This patient-based study explored the feasibility of acquiring intraoperative computed tomography (CT) studies for calculating three-dimensional dose distributions with two factors not included in the conventional assumption, namely the air gap from the applicator end to the irradiation surface and tissue heterogeneity. In addition, dose distributions under the conventional assumption and from preoperative CT studies (both also updated with intraoperative data) were calculated to explore whether there are other alternatives to intraoperative CT studies that can provide similar dose distributions. The IOERT protocol was modified to incorporate the acquisition of intraoperative CT studies before radiation delivery in six patients. Three studies were not valid to calculate dose distributions due to the presence of metal artefacts. For the remaining three cases, the average gamma pass rates between the doses calculated from intraoperative CT studies and those obtained assuming water-equivalent tissues or from preoperative CT studies were 73.4% and 74.0% respectively. The agreement increased when the air gap was included in the conventional assumption (98.1%) or in the preoperative CT images (98.4%). Therefore, this factor was the one mostly influencing the dose distributions of this study. Our experience has shown

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3D Monte Carlo dosimetry of intraoperative electron radiation therapy (IOERT)

Cited by 11 publications

References 27 publications

FLASH radiotherapy treatment planning and models for electron beams

FLASH radiotherapy treatment planning and models for electron beams

Treatment Planning in Intraoperative Radiation Therapy (IORT): Where Should We Go?

Intraoperative computed tomography imaging for dose calculation in intraoperative electron radiation therapy: Initial clinical observations

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