Needle insertion is commonly performed in minimally invasive medical procedures such as biopsy and radiation cancer treatment. During such procedures, accurate needle tip placement is critical for correct diagnosis or successful treatment. Accurate placement of the needle tip inside tissue is challenging, especially when the target moves and anatomical obstacles must be avoided. We develop a needle steering system capable of autonomously and accurately guiding a steerable needle using two-dimensional (2D) ultrasound images. The needle is steered to a moving target while avoiding moving obstacles in a three-dimensional (3D) non-static environment. Using a 2D ultrasound imaging device, our system accurately tracks the needle tip motion in 3D space in order to estimate the tip pose. The needle tip pose is used by a rapidly exploring random tree-based motion planner to compute a feasible needle path to the target. The motion planner is sufficiently fast such that replanning can be performed repeatedly in a closed-loop manner. This enables the system to correct for perturbations in needle motion, and movement in obstacle and target locations. Our needle steering experiments in a soft-tissue phantom achieves maximum targeting errors of 0.86 ± 0.35 mm (without obstacles) and 2.16 ± 0.88 mm (with a moving obstacle).
AbayazidMBuijs op denJde KorteC. (2012) Effect of skin thickness on target motion during needle insertion into soft-tissue phantoms. In: Proceedings of the IEEE RAS/EMBS International conference on biomedical robotics and biomechatronics (BioRob), Rome, Italy, 24–27 June 2012, pp. 755–760.
2.
AbayazidMKempMMisraS (2013a) 3D flexible needle steering in soft-tissue phantoms using fiber Bragg grating sensors. In: Proceedings of the IEEE International conference on robotics and automation (ICRA), Karlsruhe, Germany, 6–10 May 2013, pp. 5823–5829.
3.
AbayazidMRoesthuisRJReilinkR. (2013b) Integrating deflection models and image feedback for real-time flexible needle steering. IEEE Transactions on Robotics29(2): 542–553.
4.
AbolhassaniNPatelRVMoallemM (2007) Needle insertion into soft tissue: A survey. Medical Engineering and Physics29(4): 413–431.
5.
AldrichJE (2007) Basic physics of ultrasound imaging. Critical Care Medicine35(5): S131–S137.
6.
AlterovitzRBranickyMGoldbergK (2008) Motion planning under uncertainty for image-guided medical needle steering. The International Journal of Robotics Research27(11–12): 1361–1374.
7.
AsadianAKermaniMPatelR (2011) Robot-assisted needle steering using a control theoretic approach. Journal of Intelligent and Robotic Systems62(3–4): 397–418.
8.
Bar-ShalomYLiXRKirubarajanT (2001) Estimation with Applications to Tracking and Navigation. New York: John Wiley and Sons.
9.
BernardesMAdornoBPoignetP. (2013) Robot-assisted automatic insertion of steerable needles with closed-loop imaging feedback and intraoperative trajectory replanning. Mechatronics23(6): 630–645.
10.
BlumenfeldPHataNDiMaioS. (2007) Transperineal prostate biopsy under magnetic resonance image guidance: A needle placement accuracy study. Journal of Magnetic Resonance Imaging26(3): 688–694.
BrennerDJHallEJ (2007) Computed tomography—An increasing source of radiation exposure. New England Journal of Medicine357(22): 2277–2284.
13.
CookJRBouchardRREmelianovSY (2011) Tissue-mimicking phantoms for photoacoustic and ultrasonic imaging. Biomedical Optics Express2(11): 3193–3206.
14.
CowanNJGoldbergKChirikjianG. (2011) Robotic needle steering: Design, modeling, planning, and image guidance. In: RosenJHannafordBSatavaRM (eds) Surgical Robotics. New York: Springer, pp. 557–582.
15.
DeurlooEEGilhuijsKGKoolLJS. (2001) Displacement of breast tissue and needle deviations during stereotactic procedures. Investigative Radiology36(6): 347–353.
16.
DiMaioSPSalcudeanSE (2005) Needle steering and motion planning in soft tissues. IEEE Transactions on Biomedical Engineering52(6): 965–974.
17.
DiMaioSPSamsetEFischerG. (2007) Dynamic MRI scan plane control for passive tracking of instruments and devices. In: Proceedings of the 10th International conference on medical image computing and computer-assisted intervention (MICCAI), Brisbane, Australia, 29 October–2 November 2007, pp. 50–58.
18.
DuindamVXuJAlterovitzR. (2010) Three-dimensional motion planning algorithms for steerable needles using inverse kinematics. The International Journal of Robotics Research29(7): 789–800.
19.
DupontPELockJItkowitzB. (2010) Design and control of concentric-tube robots. IEEE Transactions on Robotics26(2): 209–225.
20.
FredH (2004) Drawbacks and limitations of computed tomography: views from a medical educator. Texas Heart Institute Journal31(4): 345–348.
21.
GefenADilmoneyB (2007) Mechanics of the normal woman’s breast. Technology and Health Care15(4): 259–271.
22.
GlossopNDClearyKKullL. (2002) Needle tracking using the aurora magnetic position sensor. In: Proceedings of the International society for computer assisted orthopaedic surgery (CAOS), Santa Fe, CA, USA, pp. 90–92.
GüthUHuangDJHuberM. (2008) Tumor size and detection in breast cancer: Self-examination and clinical breast examination are at their limit. Cancer Detection and Prevention32(3): 224–228.
25.
HauserKAlterovitzRChentanezN. (2009) Feedback control for steering needles through 3D deformable tissue using helical paths. In: Proceedings of Robotics: Science and systems (RSS), Seattle, WA, USA.
26.
HongJDohiTHashizumeM. (2004) An ultrasound-driven needle-insertion robot for percutaneous cholecystostomy. Physics in Medicine and Biology49(3): 441–455.
27.
HuangJTriedmanJVasilyevN. (2007) Imaging artifacts of medical instruments in ultrasound-guided interventions. Journal of Ultrasound in Medicine26(10): 1303–1322.
28.
KoSYFrassonLRodriguez y BaenaF (2011) Closed-loop planar motion control of a steerable probe with a “programmable bevel” inspired by nature. IEEE Transactions on Robotics27(5): 970–983.
29.
LaValleSM (2006) Planning Algorithms. Cambridge; New York: Cambridge University Press. Available at: http://planning.cs.uiuc.edu.
30.
MajewiczAMarraSPvan VledderMG. (2012) Behavior of tip-steerable needles in ex vivo and in vivo tissue. IEEE Transactions on Biomedical Engineering59(10): 2705–2715.
31.
MinhasDSEnghJAFenskeMM. (2007) Modeling of needle steering via duty-cycled spinning. In: Proceedings of the IEEE International conference on engineering in medicine and biology society (EMBC), Lyon, France, 23–26 August 2007, pp. 2756–2759.
32.
MisraSReedKBSchaferBW. (2010) Mechanics of flexible needles robotically steered through soft tissue. International Journal of Robotic Research29(13): 1640–1660.
33.
NeshatHPatelR (2008) Real-time parametric curved needle segmentation in 3D ultrasound images. In: Proceedings of the IEEE RAS EMBS International conference on biomedical robotics and biomechatronics (BioRob), Scottsdale, AZ, USA, 19–22 October 2008, pp. 670–675.
34.
NeubachZShohamM (2010) Ultrasound-guided robot for flexible needle steering. IEEE Transactions on Biomedical Engineering57(4): 799–805.
35.
NovotnyPMStollJAVasilyevNV. (2007) GPU based real-time instrument tracking with three-dimensional ultrasound. Medical Image Analysis11(5): 458–464.
OnuigboMACCuffy-HallamMEDunsmoreNA. (2001) Mammography reveals a 2-mm intraductal breast carcinoma. Hospital Physician37(5): 61–64.
38.
Op den BuijsJAbayazidMde KorteCL. (2011a) Target motion predictions for pre-operative planning during needle-based interventions. In: Proceedings of the IEEE International conference on engineering in medicine and biology society (EMBC), Boston, MA, USA, 30 August–3 September 2011, pp. 5380–5385.
39.
Op den BuijsJHansenHHGLopataRGP. (2011b) Predicting target displacements using ultrasound elastography and finite element modeling. IEEE Transactions on Biomedical Engineering58(11): 3143–3155.
40.
ParkWWangYChirikjianG (2010) The path-of-probability algorithm for steering and feedback control of flexible needles. The International Journal of Robotics Research29(7): 813–830.
41.
PatilSAlterovitzR (2010) Interactive motion planning for steerable needles in 3D environments with obstacles. In: Proceedings of the IEEE RAS and EMBS International conference on biomedical robotics and biomechatronics (BioRob), Tokyo, Japan, 26–29 September 2010, pp. 893–899.
42.
PatilSvan den BergJAlterovitzR (2011) Motion planning under uncertainty in highly deformable environments. In: Proceedings of Robotics: Science and systems (RSS), Los Angeles, CA, USA.
RoesthuisRJvan VeenYRJJayhaA. (2011) Mechanics of needle-tissue interaction. In: Proceedings of the IEEE International conference on intelligent robots and systems (IROS), San Francisco, CA, USA, 25–30 September 2011, pp. 2557–2563.
45.
ShkolnikAWalterMTedrakeR (2009) Reachability guided sampling for planning under differential constraints. In: Proceeding of the IEEE International conference on robotics and automation (ICRA), Kobe, Japan, 12–17 May 2009, pp. 2859–2865.
46.
TaschereauRPouliotJRoyJ. (2000) Seed misplacement and stabilizing needles in transperineal permanent prostate implants. Radiotherapy and Oncology55(1): 59–63.
47.
TaubinG (1991) Estimation of planar curves, surfaces, and nonplanar space curves defined by implicit equations with applications to edge and range image segmentation. IEEE Transactions on Pattern Analysis and Machine Intelligence13(11): 1115–1138.
48.
TomozawaYInabaYYamauraH. (2011) Clinical value of ct-guided needle biopsy for retroperitoneal lesions. Korean Journal of Radiology12(3): 351–357.
49.
Van den BergJPatilSAlterovitzR. (2010) LQG-based planning, sensing, and control of steerable needles. In: Workshop on algorithmic foundations of robotics (WAFR), Singapore, 13–15 December 2010, pp. 373–389.
50.
Van VeenYRJJahyaAMisraS (2012) Macroscopic and microscopic observations of needle insertion into gels. Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine226(6): 441–449.
51.
VosPJD (2013) Effect of system parameters on target motion. Bachelor’s Dissertation, Faculty of Science and Technology, University of Twente, The Netherlands.
52.
VrooijinkGJAbayazidMMisraS (2013) Real-time three-dimensional flexible needle tracking using two-dimensional ultrasound. In: Proceedings of the IEEE International conference on robotics and automation (ICRA), Karlsruhe, Germany, 6–10 May 2013, pp. 1680–1685.
53.
WebsterRJKimJSCowanNJ. (2006) Nonholonomic modeling of needle steering. The International Journal of Robotics Research25(5–6): 509–525.
54.
Webster IIIRJJonesBA (2010) Design and kinematic modeling of constant curvature continuum robots: A review. The International Journal of Robotics Research29(13): 1661–1683.
55.
XuJDuindamVAlterovitzR. (2008) Motion planning for steerable needles in 3d environments with obstacles using rapidly-exploring random trees and backchaining. In: Proceedings of the IEEE International conference on automation science and engineering (CASE), Washington DC, USA, 23–26 August 2008, pp. 41–46.
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