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Erschienen in:
On the Validation of the Proper Generalized Decomposition Method with Finite Element Method: 3D Heat Problem Under Cyclic Loading Kapitel lesen Erstes Kapitel lesen

2019 | OriginalPaper | Buchkapitel

Modelling the Deformation of Biologically Inspired Flexible Structures for Needle Steering

verfasst von : T. Watts, R. Secoli, F. Rodriguez y Baena

Erschienen in: Mechanism, Machine, Robotics and Mechatronics Sciences

Verlag: Springer International Publishing

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Abstract

Recent technical advances in minimally invasive surgery have been enabled by the development of new medical instruments and technologies. To date, the vast majority of mechanisms used within a clinical context are rigid, contrasting with the compliant nature of biological tissues. The field of robotics has seen an increased interest in flexible and compliant systems, and in this paper we investigate the behaviour of deformable multi-segment structures, which take their inspiration from the ovipositor design of parasitic wood wasps. These configurable structures have been shown to steer through highly compliant substrates, potentially enabling percutaneous access to the most delicate of tissues, such as the brain. The model presented here sheds light on how the deformation of the unique structure is related to its shape, and allows comparison between different potential designs. A finite element study is used to evaluate the proposed model, which is shown to provide a good fit (root-mean-square deviation 0.2636 mm for 4-segment case). The results show that both 3-segment and 4-segment designs are able to achieve deformation in all directions, however the magnitude of deformation is more consistent in the 4-segment case.

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Literatur
1.
Abolhassani N, Patel R, Moallem M (2007) Needle insertion into soft tissue: A survey. Med Eng Phys 29(4):413–431CrossRef
2.
Vincent JFV, King MJ (1995) The mechanism of drilling by wood wasp ovipositors. Biomimetics 3:187–201
3.
Parittotokkaporn T, Frasson L, Schneider A, Huq SE, Davies BL, Dagenaar P, Biesenack J, Rodriguez y Baena F (2008) Soft tissue traversal with zero net force: feasibility study of a biologically inspired design based on reciprocal motion. In: Proceedings of the IEEE international conference on robotics and biomimetics Bangkok, Thailand
4.
Frasson L, Ko SY, Turner A, Parittotokkaporn T, Vincent JF, Rodriguez y Baena F (2010) STING: a soft-tissue intervention and neurosurgical guide to access deep brain lesions through curved trajectories. Proc Inst Mech Eng Part H: J Eng Med 224(6):775–788CrossRef
5.
Secoli R, Rodriguez y Baena F (2016) Adaptive path-following control for bio-inspired steerable needles. In: Proceedings of the 6th IEEE international conference on biomedical robotics and biomechatronics (BioRob), pp 87–93
6.
van de Berg NJ, van Gerwen DJ, Dankelman J, van den Dobbelsteen JJ (2015) Design choices in needle steering—a review. IEEE/ASME Trans Mechatron 20(5):2172–2183CrossRef
7.
Reed KB, Majewicz A, Kallem V, Alterovitz R, Goldberg K, Cowan NJ, Okamura AM (2011) Robot-assisted needle steering. IEEE Robot Autom Mag 18(4):35–46CrossRef
8.
Engh JA, Minhas DS, Kondziolka D, Riviere CN (2010) Percutaneous intracerebral navigation by duty-cycled spinning of flexible bevel-tipped needles. Neurosurgery 67(4):1117–1122CrossRef
9.
Kallem V, Cowan NJ (2009) Image guidance of flexible tip-steerable needles. IEEE Trans Robot 25(1):191–196CrossRef
10.
Reed KB, Kallem V, Alterovitz R, Goldberg K, Okamura AM, Cowan NJ (2008) Integrated planning and image-guided control for planar needle steering. In: Proceedings of the IEEE conference on biomedical robotics and biomechatronics, pp 819–824
11.
Webster RJ, Kim JS, Cowan NJ, Chirikjian GS, Okamura AM (2006) Nonholonomic modeling of needle steering. Int J Robot Res 25(5–6):509–525CrossRef
12.
Swaney PJ, Burgner J, Gilbert HB, Webster RJ (2013) A flexure-based steerable needle: High curvature with reduced tissue damage. IEEE Trans Biomed Eng 60(4):906–909CrossRef
13.
Dupont PE, Lock J, Itkowitz B, Butler E (2010) Design and control of concentric-tube robots. IEEE Trans Robot 26(2):209–225CrossRef
14.
Rucker DC, Jones BA, Webster RJ (2010) A model for concentric tube continuum robots under applied wrenches. In: Proceedings of the IEEE international conference on robotics and automation (ICRA), pp 1047–1052
15.
Frasson L, Parittotokkaporn T, Davies BL, Rodriguez y Baena F (2008) Early developments of a novel smart actuator inspired by nature. In: 15th International conference on mechatronics and machine vision in practice, pp 163–168
16.
Ko SY, Rodriguez y Baena F (2012) Trajectory following for a flexible probe with state/input constraints: An approach based on model predictive control. Robot Auton Syst 60(4):509–521CrossRef
17.
Qi P, Liu H, Seneviratne L, Althoefer K (2014) Towards kinematic modeling of a multi-DOF tendon driven robotic catheter. In: Proceedings of the 36th annual international conference of the ieee engineering in medicine and biology society (EMBC), pp 3009–3012
18.
Roesthuis RJ, van de Berg NJ, van den Dobbelsteen JJ, Misra S (2015) Modeling and steering of a novel actuated-tip needle through a soft-tissue simulant using fiber bragg grating sensors. In: IEEE international conference on robotics and automation (ICRA), pp 2283–2289
19.
Ryu SC, Quek ZF, Koh J, Renaud P, Black RJ, Moslehi B, Daniel BL, Cho K, Cutkosky MR (2015) Design of an optically controlled MR-Compatible active needle. IEEE Trans Robot 31(1):1–11CrossRef
20.
Quicke DLJ, Ralec AL, Vilhelmsen L (1999) Ovipositor structure and function in the parasitic Hymenoptera with an exploration of new hypotheses. Atti Acad Naz Ital Entomol Rc 47:197–239. http://​bit.​do/​eeFMZ
21.
Oldfield MJ, Dini D, Giordano G, Rodriguez y Baena F (2013) Detailed finite element modelling of deep needle insertions into a soft tissue phantom using a cohesive approach. Comput Methods Biomech Biomed Eng 16(5):530–543CrossRef
22.
Alterovitz R, Goldberg K, Okamura AM (2005) Planning for steerable bevel-tip needle insertion through 2D soft tissue with obstacles. In: IEEE international conference on robotics and automation, pp 1640–1645
23.
DiMaio SP, Salcudean SE (2005) Interactive simulation of needle insertion models. IEEE Trans Biomed Eng 52(7):1167–1179CrossRef
24.
Khadem M, Rossa C, Usmani N, Sloboda RS, Tavakoli M (2016) A two-body rigid/flexible model of needle steering dynamics in soft tissue. IEEE/ASME Trans Mechatron 21(5):2352–2364CrossRef
25.
Glozman D, Shoham M (2004) Flexible needle steering and optimal trajectory planning for percutaneous therapies. In: Proceedings of the international conference on medical image computing and computer assisted intervention, pp 137–144CrossRef
26.
Burrows C, Secoli R, Rodriguez y Baena F (2013) Experimental characterisation of a biologically inspired 3D steering needle. In: Proceedings of the international conference on control, automation and systems, pp 1252–1257
27.
Quicke DLJ, Fitton MG (1995) Ovipositor steering mechanisms in parasitic wasps of the families Gasteruptiidae and Aulacidae (hymenoptera). Proc R Soc Lond 261:99–103CrossRef
Metadaten
Titel
Modelling the Deformation of Biologically Inspired Flexible Structures for Needle Steering
verfasst von
T. Watts
R. Secoli
F. Rodriguez y Baena
Copyright-Jahr
2019
Buch
Mechanism, Machine, Robotics and Mechatronics Sciences

Print ISBN: 978-3-319-89910-7

Electronic ISBN: 978-3-319-89911-4

Copyright-Jahr: 2019

DOI
https://doi.org/10.1007/978-3-319-89911-4_6

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