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Abstract

Fast and realistic coupling of blood flow and the vessel wall is of great importance to virtual surgery. In this paper, we propose a novel data-driven coupling method that formulates physics-based blood flow simulation as a regression problem, using an improved periodic-corrected neural network, estimating the acceleration of every particle at each frame to obtain fast, stable, and realistic simulation. We design a particle state feature vector based on smoothed particle hydrodynamics, modeling the mixed contribution of neighboring proxy particles on the blood vessel wall and neighboring blood particles, giving the extrapolation ability to deal with more complex couplings. We present a semi-supervised training strategy to improve the traditional back propagation neural network, which corrects the error periodically to ensure long-term stability. Experimental results demonstrate that our method is able to implement stable and vivid coupling of blood flow and the vessel wall while greatly improving computational efficiency.

Keywords

Fluid–solid coupling blood vessel data-driven periodic-corrected smoothed particle hydrodynamics

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References

Bao

Wang

. A open source based general framework for virtual surgery simulation. In: 2008 international conference on biomedical engineering and informatics, vol. 1. IEEE, pp. 575–579.

Ztonyi

Paget

Szkely

, et al. Real-time synthesis of bleeding for virtual hysteroscopy. Med Image Anal 2005; 9: 255.

Cebral

Castro

Appanaboyina

, et al. Efficient pipeline for image-based patient-specific analysis of cerebral aneurysm hemodynamics: technique and sensitivity. IEEE Trans Med Imaging 2005; 24: 457–67.

Raghavan

Vorp

Federle

, et al. Wall stress distribution on three-dimensionally reconstructed models of human abdominal aortic aneurysm. J Vasc Surg 2000; 31: 760–769.

Tong

Yuan

Zhao

, et al. Magnetic levitation haptic augmentation for virtual tissue stiffness perception. IEEE Trans Vis Comput Graph 2018; 24: 3123–3136.

Akinci

Cornelis

Akinci

, et al. Coupling elastic solids with smoothed particle hydrodynamics fluids. Comput Anim Virtual Worlds 2013; 24: 195203.

Akinci

Ihmsen

Akinci

, et al. Versatile rigid-fluid coupling for incompressible SPH. ACM Trans Graph 2012; 31: 1–8.

Schechter

Bridson

Ghost SPH for animating water. ACM Trans Graph 2012; 31: 1–8.

Goswami

Schlegel

Solenthaler

, et al. Interactive SPH simulation and rendering on the GPU. In: Proceedings of the 2010 ACM SIGGRAPH/Eurographics symposium on computer animation. Eurographics Association, pp. 55–64.

10.

Liao

Yuan

, et al. Animating wall-bounded turbulent smoke via filament-mesh particle-particle method. IEEE Trans Visual Comput Graph 2018; 24: 1260–1273.

11.

Müller

Schirm

Teschner

Interactive blood simulation for virtual surgery based on smoothed particle hydrodynamics. Technol Health Care 2004; 12: 25–31.

12.

Qin

Pang

Chui

, et al. Hardware-accelerated bleeding simulation for virtual surgery. In: MICCAI 2007 workshop proceedings, vol. 133.

13.

Qin

Pang

Nguyen

, et al. Particle-based simulation of blood flow and vessel wall interactions in virtual surgery. In: Proceedings of the 2010 symposium on information and communication technology. ACM, pp. 128–133.

14.

Lai

Xiang

. Bleeding simulation of virtual surgery implemented on GPU. J Image Graph 2014; 19: 1532–1538.

15.

Guo

Yuan

Liao

, et al. GPU-assisted real-time coupling of blood flow and vessel wall. Comput Anim Virtual Worlds 2015; 26: 337–345.

16.

Raveendran

Wojtan

Thuerey

, et al. Blending liquids. ACM Trans Graph 2014; 33: 1–10.

17.

Yang

Xiao

. Data-driven projection method in fluid simulation. Comput Anim Virtual Worlds 2016; 27: 415–424.

18.

Jeong

Solenthaler

Pollefeys

, et al. Data-driven fluid simulations using regression forests. ACM Trans Graph 2015; 34: 199.

19.

Cleary

. Modelling confined multi-material heat and mass flows using SPH. Appl Math Modell 1998; 22: 981–993.

20.

Duda

Hart

Stork

. Pattern classification. New York: Wiley Interscience, 2000.

Periodic-corrected data-driven coupling of blood flow and the vessel wall for virtual surgery

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