Parallel Reinforcement Learning and Gaussian Process Regression for Improved Physics-Based Nasal Surgery Planning

Rüttgers, Mario; Hübenthal, Fabian; Tsubokura, Makoto; Lintermann, Andreas

doi:10.1007/978-3-031-85703-4_6

Contribution to a conference proceedings/Contribution to a book

FZJ-2026-01057

Parallel Reinforcement Learning and Gaussian Process Regression for Improved Physics-Based Nasal Surgery Planning

Rüttgers, M. (Corresponding author) ; Hübenthal, F. ; Tsubokura, M. ; Lintermann, A.FZJ*

2025
Springer Nature Switzerland Cham
ISBN: 978-3-031-85702-7 (print), 978-3-031-85703-4 (electronic)

Parallel Processing and Applied Mathematics
International Conference on Parallel Processing and Applied Mathematics, PPAM 2024, Ostrava, Czech Republic, 8 Sep 2024 - 11 Sep 2024 Cham : Springer Nature Switzerland, Lecture Notes in Computer Science 15581, 79 - 96 (2025) [10.1007/978-3-031-85703-4_6]

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Please use a persistent id in citations: doi:10.1007/978-3-031-85703-4_6 doi:10.34734/FZJ-2026-01057

Abstract: Septoplasty and turbinectomy are among the most frequentbut also most debated interventions in the field of rhinology. A previouslydeveloped tool enhances surgery planning by physical aspects of respi-ration, i.e., for the first time a reinforcement learning (RL) algorithm iscombined with large-scale computational fluid dynamics (CFD) simula-tions to plan anti-obstructive surgery. In the current study, an improve-ment of the tool’s predictive capabilities is investigated for the afore-mentioned types of surgeries by considering two approaches: (i) trainingof parallel environments is executed on multiple ranks and the agentsof each environment share their experience in a pre-defined interval and(ii) for some of the state-reward combinations the CFD solver is replacedby a Gaussian process regression (GPR) model for an improved compu-tational efficiency. It is found that employing a parallel RL algorithmimproves the reliability of the surgery planning tool in finding the globaloptimum. However, parallel training leads to a larger number of state-reward combinations that need to be computed by the CFD solver. Thisoverhead is compensated by replacing some of the computations withthe GPR algorithm, i.e., around 6% of the computations can be savedwithout significantly degrading the predictions’ accuracy. Nevertheless,increasing the number of state-reward combinations predicted by theGPR algorithm only works to a certain extent, since this also leads tolarger errors.

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