Beam angle optimization in IMRT: are we really optimizing what matters?

Rocha, Humberto; Dias, Joana; Ventura, Tiago; Ferreira, B.; Lopes, Maria do Carmo

doi:10.1111/itor.12587

Cited by 20 publications

(31 citation statements)

References 27 publications

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“…CG has been shown to be effective for BOO in radiation therapy problems. 15,21,61 While CG does not guarantee an optimal solution, the CG algorithm has been shown to have superior performance when compared to clinical plans, 10,15,21,30,50,52,53,[62][63][64][65][66][67][68][69][70] and the algorithm is summarized in the sections that follow. A list of all indices, parameters, variables, and functions used in this paper and their definitions are provided in Table I.…”

Section: C Full and Limited Boo Problemmentioning

confidence: 99%

“…The final objective function in these works is usually a function of the differences between the actual and prescribed dosage received by healthy tissues, organs at risk (OARs), and the PTV . But computing the dose influence matrices and the FMO are both very complex and time intensive operations, taking hours to compute dose influence matrices and minutes to solve the FMO, which ultimately hampers the implementation of BOO in clinical routines . Breedveld et al used a “wish list” to prioritize constraints and objective functions related to OARs and the tumor and to iteratively add new beam orientations to the set of currently selected beams.…”

Section: Introductionmentioning

confidence: 99%

“…[16][17][18][19][20][21][22][23][24][25][26][27][28] But computing the dose influence matrices and the FMO are both very complex and time intensive operations, 29 taking hours to compute dose influence matrices and minutes to solve the FMO, which ultimately hampers the implementation of BOO in clinical routines. 13,20,24,[30][31][32] Breedveld et al 13 used a "wish list" to prioritize constraints and objective functions related to OARs and the tumor and to iteratively add new beam orientations to the set of currently selected beams. Yarmand et al 31 scored beamlets of candidate beams based on their contributions to irradiating tumors and weighted the average of the total dose received by OARs.…”

Section: Introductionmentioning

confidence: 99%

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A fast deep learning approach for beam orientation optimization for prostate cancer treated with intensity‐modulated radiation therapy

et al. 2020

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Purpose Beam orientation selection, whether manual or protocol‐based, is the current clinical standard in radiation therapy treatment planning, but it is tedious and can yield suboptimal results. Many algorithms have been designed to optimize beam orientation selection because of its impact on treatment plan quality, but these algorithms suffer from slow calculation of the dose influence matrices of all candidate beams. We propose a fast beam orientation selection method, based on deep learning neural networks (DNN), capable of developing a plan comparable to those developed by the state‐of‐the‐art column generation (CG) method. Our model's novelty lies in its supervised learning structure (using CG to teach the network), DNN architecture, and ability to learn from anatomical features to predict dosimetrically suitable beam orientations without using dosimetric information from the candidate beams. This may save hours of computation. Methods A supervised DNN is trained to mimic the CG algorithm, which iteratively chooses beam orientations one‐by‐one by calculating beam fitness values based on Karush‐Kush‐Tucker optimality conditions at each iteration. The DNN learns to predict these values. The dataset contains 70 prostate cancer patients — 50 training, 7 validation, and 13 test patients — to develop and test the model. Each patient’s data contains 6 contours: PTV, body, bladder, rectum, and left and right femoral heads. Column generation was implemented with a GPU‐based Chambolle‐Pock algorithm, a first‐order primal‐dual proximal‐class algorithm, to create 6270 plans. The DNN trained over 400 epochs, each with 2500 steps and a batch size of 1, using the Adam optimizer at a learning rate of 1 × 10−5 and a sixfold cross‐validation technique. Results The average and standard deviation of training, validation, and testing loss functions among the six folds were 0.62 ± 0.09%, 1.04 ± 0.06%, and 1.44 ± 0.11%, respectively. Using CG and supervised DNN, we generated two sets of plans for each scenario in the test set. The proposed method took at most 1.5 s to select a set of five beam orientations and 300 s to calculate the dose influence matrices for 5 beams and finally 20 s to solve the fluence map optimization (FMO). However, CG needed around 15 h to calculate the dose influence matrices of all beams and at least 400 s to solve both the beam orientation selection and FMO problems. The differences in the dose coverage of PTV between plans generated by CG and by DNN were 0.2%. The average dose differences received by organs at risk were between 1 and 6 percent: Bladder had the smallest average difference in dose received (0.956 ± 1.184%), then Rectum (2.44 ± 2.11%), Left Femoral Head (6.03 ± 5.86%), and Right Femoral Head (5.885 ± 5.515%). The dose received by Body had an average difference of 0.10 ± 0.1% between the generated treatment plans. Conclusions We developed a fast beam orientation selection method based on a DNN that selects beam orientations in seconds and is therefore suitable for clinical routines. In the ...

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Section: C Full and Limited Boo Problemmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A fast deep learning approach for beam orientation optimization for prostate cancer treated with intensity‐modulated radiation therapy

et al. 2020

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“…An alternative formulation of the BAO problem has been considered in our works. All possible continuous beam angle directions around the tumor have been considered instead of a discretized set of beam directions, leading to a continuous global optimization problem [24,25,26,27,28]. The continuous formulation of the noncoplanar BAO problem is briefly described next.…”

Section: Noncoplanar Beam Angle Optimizationmentioning

confidence: 99%

An Optimization Approach for Noncoplanar Intensity-Modulated Arc Therapy Trajectories

Rocha

Dias

Ventura

et al. 2019

Computational Science and Its Applications – ICCSA 2019

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The latest generation of linear accelerators allows the simultaneous motion of gantry and couch leading to highly noncoplanar arc trajectories. The use of noncoplanar trajectories in arc radiotherapy was recently proposed to combine the benefits of arc treatment plans, such as short treatment times, with the benefits of step-and-shoot noncoplanar intensity-modulated radiation therapy (IMRT) treatment plans, such as improved organ sparing. In this paper, a two-step approach for the optimization of highly noncoplanar arc trajectories is presented and tested using a complex nasopharyngeal tumor case already treated at the Portuguese Institute of Oncology of Coimbra. In the first step, a set of noncoplanar beam directions is calculated resorting to one of the beam angle optimization (BAO) algorithms proposed in our previous works for step-and-shoot IMRT. In the second step, anchored in the points (beam directions) calculated in the first step, the proposed optimization strategy determines iteratively more anchor points that will define the noncoplanar arc trajectory, considering the dosimetric criteria used for the noncoplanar BAO search rather than geometric or time criteria commonly used. For the patient tested, the resulting noncoplanar arc therapy plan has undoubtedly greater overall quality compared to both the coplanar arc therapy plan and the typically used coplanar equispaced step-and-shoot IMRT plan.

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“…In this paper, we propose a two-step approach based on dosimetric criteria for the optimization of noncoplanar arc trajectories. In the first step, an initial set of anchor points (noncoplanar beam directions) is computed taking advantage of the work previously developed in BAO for step-and-shoot IMRT [7][8][9][10][11][12][13]. In the second step, anchored in the beam directions already calculated, the noncoplanar arc trajectory is defined by iteratively computing additional anchor points considering the same dosimetric criteria used for the noncoplanar BAO.…”

Section: Introductionmentioning

confidence: 99%

Optimization of Highly Noncoplanar Arc Therapy Trajectories: A Dosimetric Approach

et al. 2019

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The latest generation of linear accelerators allows the use of noncoplanar trajectories in arc therapy which combine the benefits of noncoplanar intensity-modulated radiation therapy (IMRT) treatment plans, such as improved organ sparing, with the benefits of arc therapy treatment plans, such as short treatment times. In this paper, we propose a two-step approach based on dosimetric criteria for the optimization of noncoplanar arc trajectories. In the first step, an initial set of anchor points (noncoplanar beam directions) is computed using a beam angle optimization (BAO) algorithm. In the second step, anchored in the beam directions already calculated, the noncoplanar arc trajectory is defined by iteratively computing additional anchor points considering the same dosimetric criteria used for the noncoplanar BAO. A nasopharyngeal tumor case already treated at the Portuguese Institute of Oncology of Coimbra (IPOC), is used to illustrate the benefits of the proposed optimization approach.

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Beam angle optimization in IMRT: are we really optimizing what matters?

Cited by 20 publications

References 27 publications

A fast deep learning approach for beam orientation optimization for prostate cancer treated with intensity‐modulated radiation therapy

A fast deep learning approach for beam orientation optimization for prostate cancer treated with intensity‐modulated radiation therapy

An Optimization Approach for Noncoplanar Intensity-Modulated Arc Therapy Trajectories

Optimization of Highly Noncoplanar Arc Therapy Trajectories: A Dosimetric Approach

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