A quantitative FLASH effectiveness model to reveal potentials and pitfalls of high dose rate proton therapy

Krieger, Miriam; Water, Steven van de; Folkerts, Michael; Mazal, A.; Fabiano, Silvia; Bizzocchi, Nicola; Weber, Damien Charles; Safai, Sairos; Lomax, Anthony

doi:10.1002/mp.15459

Cited by 32 publications

(34 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It might make more sense to use a method that considers the time necessary to deliver a certain minimum dose, which has been described earlier. 49 …”

Section: Discussionmentioning

confidence: 99%

Single-fraction 34 Gy Lung Stereotactic Body Radiation Therapy Using Proton Transmission Beams: FLASH-dose Calculations and the Influence of Different Dose-rate Methods and Dose/Dose-rate Thresholds

Marlen

Verbakel

Slotman

et al. 2022

Advances in Radiation Oncology

View full text Add to dashboard Cite

“…It might make more sense to use a method that considers the time necessary to deliver a certain minimum dose, which has been described earlier. 49 …”

Section: Discussionmentioning

confidence: 99%

Single-fraction 34 Gy Lung Stereotactic Body Radiation Therapy Using Proton Transmission Beams: FLASH-dose Calculations and the Influence of Different Dose-rate Methods and Dose/Dose-rate Thresholds

Marlen

Verbakel

Slotman

et al. 2022

Advances in Radiation Oncology

View full text Add to dashboard Cite

“…We assumed that Flash occurs whenever the dose delivered within the time window is larger than the dose threshold; in that case, all dose within the time window is considered as “Flash dose” (i.e., no gradual build‐up of Flash effect is hypothesized). As such, this metric is very similar to the “Flash effectiveness model” proposed by Krieger et al 41 . The sliding window metric does not provide 3D dose rate distributions as the DADR metric does, but directly gives the 3D Flash dose distribution as output instead.…”

Section: Plan Evaluationmentioning

confidence: 92%

“…Identifying Flash dose using a sliding window slided over the dose delivery time trace per voxel for each field, and the combination of Flash dose rate and dose thresholds determines the time window width (e.g., 40 Gy/s and 4 Gy thresholds imply a 100 ms time window). We assumed that Flash occurs whenever the dose delivered within the time window is larger than the dose threshold; in that case, all dose within the time window is considered as "Flash dose" (i.e., no gradual buildup of Flash effect is hypothesized).As such,this metric is very similar to the "Flash effectiveness model" proposed by Krieger et al 41 The sliding window metric does not provide 3D dose rate distributions as the DADR metric does, but directly gives the 3D Flash dose distribution as output instead.…”

Section: Sliding Windowmentioning

confidence: 99%

Treatment planning for Flash radiotherapy: General aspects and applications to proton beams

et al. 2022

Self Cite

View full text Add to dashboard Cite

The increased radioresistence of healthy tissues when irradiated at very high dose rates (known as the Flash effect) is a radiobiological mechanism that is currently investigated to increase the therapeutic ratio of radiotherapy treatments. To maximize the benefits of the clinical application of Flash, a patient‐specific balance between different properties of the dose distribution should be found, that is, Flash needs to be one of the variables considered in treatment planning. We investigated the Flash potential of three proton therapy planning and beam delivery techniques, each on a different anatomical region. Based on a set of beam delivery parameters, on hypotheses on the dose and dose rate thresholds needed for the Flash effect to occur, and on two definitions of Flash dose rate, we generated exemplary illustrations of the capabilities of current proton therapy equipment to generate Flash dose distributions. All techniques investigated could both produce dose distributions comparable with a conventional proton plan and reach the Flash regime, to an extent that was strongly dependent on the dose per fraction and the Flash dose threshold. The beam current, Flash dose rate threshold, and dose rate definition typically had a more moderate effect on the amount of Flash dose in normal tissue. A systematic estimation of the impact of Flash on different patient anatomies and treatment protocols is possible only if Flash‐specific treatment planning features become readily available. Planning evaluation tools such as a voxel‐based dose delivery time structure, and the inclusion in the optimization cost function of parameters directly associated with Flash (e.g., beam current, spot delivery sequence, and scanning speed), are needed to generate treatment plans that are taking full advantage of the potential benefits of the Flash effect.

show abstract

“…• Various dose delivery parameter-based metrics that aim to quantify the 'FLASH potential' of a dose distribution have been proposed. They include simple parameter thresholds, such as dose, dose rate and dose rate volume histogram thresholds and aim typically to quantify voxels or a dose fraction per voxel that fulfil these criteria, assuming a binary FLASH effect [115,[118][119][120][121]. Furthermore, more complex metrics, such as dose-averaged dose rate and '95% of the dose in a voxel delivered within a certain time', have been proposed for UHDR treatments with a more complex delivery time structure, such as scanned beams delivered via multiple portals [75,115,119,[122][123][124].…”

Section: Accounting For the Flash Effect In Uhdr Electron Treatment P...mentioning

confidence: 99%

FLASH radiotherapy treatment planning and models for electron beams

Rahman

Trigilio

Franciosini

et al. 2022

Radiotherapy and Oncology

View full text Add to dashboard Cite

A quantitative FLASH effectiveness model to reveal potentials and pitfalls of high dose rate proton therapy

Cited by 32 publications

References 29 publications

Single-fraction 34 Gy Lung Stereotactic Body Radiation Therapy Using Proton Transmission Beams: FLASH-dose Calculations and the Influence of Different Dose-rate Methods and Dose/Dose-rate Thresholds

Single-fraction 34 Gy Lung Stereotactic Body Radiation Therapy Using Proton Transmission Beams: FLASH-dose Calculations and the Influence of Different Dose-rate Methods and Dose/Dose-rate Thresholds

Treatment planning for Flash radiotherapy: General aspects and applications to proton beams

FLASH radiotherapy treatment planning and models for electron beams

Contact Info

Product

Resources

About