ESTRO 2022

Session Item

Monday

May 09

09:00 - 10:00

Poster Station 1

17: Treatment planning

Chair: Christoph Schneider, The Netherlands

Session Code: 3160

Session Type: Poster Discussion

Track: Physics

Artificial Intelligence and Multi-Criteria Optimization for automatic treatment plan generation

Gwenaelle Sidorski, France

Presentation Number: PD-0734

Abstract

Abstract Title:

Artificial Intelligence and Multi-Criteria Optimization for automatic treatment plan generation

Authors:

Jocelyne MAZURIER¹, Gwenaelle SIDORSKI¹, Xavier Franceries², Isabelle BERRY³, Baptiste PICHON¹, Baptiste PINEL¹, Igor LATORZEFF¹, Olivier Gallocher⁴, Gaelle JIMENEZ¹, Jeremy CAMILLERI¹, Vincent Connord¹, Yoan MARTY¹, Nicolas MATHY¹, Daniel ZARATE¹

¹Clinique Pasteur, radiotherapy, Toulouse, France; ²Université Toulouse Sabatier 3, INSERM UMR1037, TOULOUSE, France; ³CNRS, CERCO, TOULOUSE, France; ⁴Clinique Pasteur, radiotherapy, toulouse, France

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Purpose or Objective

In RayStation v11A® TPS, 3 methods are available to generate treatment plans: A Multi-Criteria Optimization (MCO) and two Artificial Intelligences (AI), a Machine Learning (ML) and a Deep Learning (DL) algorithm. The goal is to evaluate these advanced methods to automatize our clinical routine.

Material and Methods

The ML is based on Atlas of Random Forest and the DL on a Fully Convolutional Neural Network. They generate a predicted dose distribution. The AI methods were both trained on local treatment plans database, then the obtained models were adjusted in a dedicated RaySearch module, RayLearner.

The MCO algorithm generate treatment plans (from users constraints) were no optimization goals can be improved without deteriorating another: Optimal Pareto Plans. The chosen predicted dose distribution calculated from theorical fluence.

Then, the three methods use the same Mimicking algorithm which transforms the predicted dose distribution into a deliverable treatment plan.

Methods have been evaluated on prostate cancer treated at 78, 76 or 66 Gy, delivered with VMAT arcs of photons (6 or 10MV) on Novalis TX and Halcyon VARIAN®. We developed scripts to use MCO automatically and the AI algorithms were trained with 100 of our 78Gy treatment plans and they were adjusted in RayLearner to be used at 76 and 66Gy.

Plans were clinically accepted when they fullfil the RECORAD recommendations and pass the Patient Quality Assurance Criteria: Gamma index > 1 for 95% of points in 3% 2mm, measured with ARCHECK (and/or EPID SunCheck system (SunNuclear)

We compared MCO, ML and DL plans to manual Standard Optimized plans (SO) on 50 treatment plans with dosimetric Index: Conformity (C), Homogeneity (H) and Dose Gradient (DG). And the plan complexity were compared with the Modulation Complexity Score (MCS). We also evaluate the plan generation duration: active time (required by the user) and passive time (without the user).

Results

SO plans were clinically accepted with index : C≈ 0.84, H≈0.07, DG ≈3.11, MSC ≈ 0.35 and plans were generated in an average time of 180 active minutes.

80% of ML plans were accepted after 16 passive minutes and 85% of DL plans were accepted after 11 passive minutes. 100 % of others AI plans were accepted after additionnal optimization (≈ 5 active minutes). AI dose distributions were at least equivalent and more complex than SO: C≈ 0.86, H≈0.08, DG ≈3.02, MSC ≈ 0.31

100% of MCO plans were generated in 30 passive minutes and were after additionnal standard optimization (≈ 30 active minutes). MCO plans had the best and most complex dose distributions (C≈ 0.87, H≈0.06, DG ≈2.88, MSC ≈ 0.2)

Conclusion

Automated methods gives results more homogeneous and very close (DL / ML) or event better (MCO) than SO. Futhermore, calculation were 2(MCO) to 16 (DL) times faster. Finally, MCO seems to be more adapted to complex and unusual clinical cases and AI can be used on classical clinical cases which allows to consider adaptative radiotherapy.