Image-guided robotic k-wire placement for orthopaedic trauma surgery

R. C. Vijayan; R. Han; P. Wu; N. M. Sheth; M. D. Ketcha; P. Vagdargi; S. Vogt; G. Kleinszig; G. M. Osgood; J. H. Siewerdsen; A. Uneri

doi:10.1117/12.2549713

Image-guided robotic k-wire placement for orthopaedic trauma surgery

R. C. Vijayan, R. Han, P. Wu, N. M. Sheth, M. D. Ketcha, P. Vagdargi, S. Vogt, G. Kleinszig, G. M. Osgood, J. H. Siewerdsen, A. Uneri

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

4 Scopus citations

Abstract

Purpose. We report the initial development of an image-based solution for robotic assistance of pelvic fracture fixation. The approach uses intraoperative radiographs, preoperative CT, and an end effector of known design to align the robot with target trajectories in CT. The method extends previous work to solve the robot-to-patient registration from a single radiographic view (without C-arm rotation) and addresses the workflow challenges associated with integrating robotic assistance in orthopaedic trauma surgery in a form that could be broadly applicable to isocentric or non-isocentric C-arms. Methods. The proposed method uses 3D-2D known-component registration to localize a robot end effector with respect to the patient by: (1) exploiting the extended size and complex features of pelvic anatomy to register the patient; and (2) capturing multiple end effector poses using precise robotic manipulation. These transformations, along with an offline hand-eye calibration of the end effector, are used to calculate target robot poses that align the end effector with planned trajectories in the patient CT. Geometric accuracy of the registrations was independently evaluated for the patient and the robot in phantom studies. Results. The resulting translational difference between the ground truth and patient registrations of a pelvis phantom using a single (AP) view was 1.3 mm, compared to 0.4 mm using dual (AP+Lat) views. Registration of the robot in air (i.e., no background anatomy) with five unique end effector poses achieved mean translational difference ∼1.4 mm for K-wire placement in the pelvis, comparable to tracker-based margins of error (commonly ∼2 mm). Conclusions. The proposed approach is feasible based on the accuracy of the patient and robot registrations and is a preliminary step in developing an image-guided robotic guidance system that more naturally fits the workflow of fluoroscopically guided orthopaedic trauma surgery. Future work will involve end-to-end development of the proposed guidance system and assessment of the system with delivery of K-wires in cadaver studies.

Original language	English (US)
Title of host publication	Medical Imaging 2020
Subtitle of host publication	Image-Guided Procedures, Robotic Interventions, and Modeling
Editors	Baowei Fei, Cristian A. Linte
Publisher	SPIE
ISBN (Electronic)	9781510633971
DOIs	https://doi.org/10.1117/12.2549713
State	Published - 2020
Externally published	Yes
Event	Medical Imaging 2020: Image-Guided Procedures, Robotic Interventions, and Modeling - Houston, United States Duration: Feb 16 2020 → Feb 19 2020

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	11315
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Medical Imaging 2020: Image-Guided Procedures, Robotic Interventions, and Modeling
Country/Territory	United States
City	Houston
Period	2/16/20 → 2/19/20

Keywords

3D-2D registration
Image-guided surgery
Known-component registration
Surgical robotics

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics
Computer Science Applications
Applied Mathematics
Electrical and Electronic Engineering

Access to Document

10.1117/12.2549713

Cite this

Vijayan, R. C., Han, R., Wu, P., Sheth, N. M., Ketcha, M. D., Vagdargi, P., Vogt, S., Kleinszig, G., Osgood, G. M., Siewerdsen, J. H., & Uneri, A. (2020). Image-guided robotic k-wire placement for orthopaedic trauma surgery. In B. Fei, & C. A. Linte (Eds.), Medical Imaging 2020: Image-Guided Procedures, Robotic Interventions, and Modeling Article 113151A (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11315). SPIE. https://doi.org/10.1117/12.2549713

Image-guided robotic k-wire placement for orthopaedic trauma surgery. / Vijayan, R. C.; Han, R.; Wu, P. et al.
Medical Imaging 2020: Image-Guided Procedures, Robotic Interventions, and Modeling. ed. / Baowei Fei; Cristian A. Linte. SPIE, 2020. 113151A (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11315).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Vijayan, RC, Han, R, Wu, P, Sheth, NM, Ketcha, MD, Vagdargi, P, Vogt, S, Kleinszig, G, Osgood, GM, Siewerdsen, JH & Uneri, A 2020, Image-guided robotic k-wire placement for orthopaedic trauma surgery. in B Fei & CA Linte (eds), Medical Imaging 2020: Image-Guided Procedures, Robotic Interventions, and Modeling., 113151A, Proceedings of SPIE - The International Society for Optical Engineering, vol. 11315, SPIE, Medical Imaging 2020: Image-Guided Procedures, Robotic Interventions, and Modeling, Houston, United States, 2/16/20. https://doi.org/10.1117/12.2549713

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title = "Image-guided robotic k-wire placement for orthopaedic trauma surgery",

abstract = "Purpose. We report the initial development of an image-based solution for robotic assistance of pelvic fracture fixation. The approach uses intraoperative radiographs, preoperative CT, and an end effector of known design to align the robot with target trajectories in CT. The method extends previous work to solve the robot-to-patient registration from a single radiographic view (without C-arm rotation) and addresses the workflow challenges associated with integrating robotic assistance in orthopaedic trauma surgery in a form that could be broadly applicable to isocentric or non-isocentric C-arms. Methods. The proposed method uses 3D-2D known-component registration to localize a robot end effector with respect to the patient by: (1) exploiting the extended size and complex features of pelvic anatomy to register the patient; and (2) capturing multiple end effector poses using precise robotic manipulation. These transformations, along with an offline hand-eye calibration of the end effector, are used to calculate target robot poses that align the end effector with planned trajectories in the patient CT. Geometric accuracy of the registrations was independently evaluated for the patient and the robot in phantom studies. Results. The resulting translational difference between the ground truth and patient registrations of a pelvis phantom using a single (AP) view was 1.3 mm, compared to 0.4 mm using dual (AP+Lat) views. Registration of the robot in air (i.e., no background anatomy) with five unique end effector poses achieved mean translational difference ∼1.4 mm for K-wire placement in the pelvis, comparable to tracker-based margins of error (commonly ∼2 mm). Conclusions. The proposed approach is feasible based on the accuracy of the patient and robot registrations and is a preliminary step in developing an image-guided robotic guidance system that more naturally fits the workflow of fluoroscopically guided orthopaedic trauma surgery. Future work will involve end-to-end development of the proposed guidance system and assessment of the system with delivery of K-wires in cadaver studies.",

keywords = "3D-2D registration, Image-guided surgery, Known-component registration, Surgical robotics",

author = "Vijayan, {R. C.} and R. Han and P. Wu and Sheth, {N. M.} and Ketcha, {M. D.} and P. Vagdargi and S. Vogt and G. Kleinszig and Osgood, {G. M.} and Siewerdsen, {J. H.} and A. Uneri",

note = "Publisher Copyright: {\textcopyright} 2020 SPIE.; Medical Imaging 2020: Image-Guided Procedures, Robotic Interventions, and Modeling ; Conference date: 16-02-2020 Through 19-02-2020",

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AU - Han, R.

AU - Wu, P.

AU - Sheth, N. M.

AU - Ketcha, M. D.

AU - Vagdargi, P.

AU - Vogt, S.

AU - Kleinszig, G.

AU - Osgood, G. M.

AU - Siewerdsen, J. H.

AU - Uneri, A.

PY - 2020

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N2 - Purpose. We report the initial development of an image-based solution for robotic assistance of pelvic fracture fixation. The approach uses intraoperative radiographs, preoperative CT, and an end effector of known design to align the robot with target trajectories in CT. The method extends previous work to solve the robot-to-patient registration from a single radiographic view (without C-arm rotation) and addresses the workflow challenges associated with integrating robotic assistance in orthopaedic trauma surgery in a form that could be broadly applicable to isocentric or non-isocentric C-arms. Methods. The proposed method uses 3D-2D known-component registration to localize a robot end effector with respect to the patient by: (1) exploiting the extended size and complex features of pelvic anatomy to register the patient; and (2) capturing multiple end effector poses using precise robotic manipulation. These transformations, along with an offline hand-eye calibration of the end effector, are used to calculate target robot poses that align the end effector with planned trajectories in the patient CT. Geometric accuracy of the registrations was independently evaluated for the patient and the robot in phantom studies. Results. The resulting translational difference between the ground truth and patient registrations of a pelvis phantom using a single (AP) view was 1.3 mm, compared to 0.4 mm using dual (AP+Lat) views. Registration of the robot in air (i.e., no background anatomy) with five unique end effector poses achieved mean translational difference ∼1.4 mm for K-wire placement in the pelvis, comparable to tracker-based margins of error (commonly ∼2 mm). Conclusions. The proposed approach is feasible based on the accuracy of the patient and robot registrations and is a preliminary step in developing an image-guided robotic guidance system that more naturally fits the workflow of fluoroscopically guided orthopaedic trauma surgery. Future work will involve end-to-end development of the proposed guidance system and assessment of the system with delivery of K-wires in cadaver studies.

AB - Purpose. We report the initial development of an image-based solution for robotic assistance of pelvic fracture fixation. The approach uses intraoperative radiographs, preoperative CT, and an end effector of known design to align the robot with target trajectories in CT. The method extends previous work to solve the robot-to-patient registration from a single radiographic view (without C-arm rotation) and addresses the workflow challenges associated with integrating robotic assistance in orthopaedic trauma surgery in a form that could be broadly applicable to isocentric or non-isocentric C-arms. Methods. The proposed method uses 3D-2D known-component registration to localize a robot end effector with respect to the patient by: (1) exploiting the extended size and complex features of pelvic anatomy to register the patient; and (2) capturing multiple end effector poses using precise robotic manipulation. These transformations, along with an offline hand-eye calibration of the end effector, are used to calculate target robot poses that align the end effector with planned trajectories in the patient CT. Geometric accuracy of the registrations was independently evaluated for the patient and the robot in phantom studies. Results. The resulting translational difference between the ground truth and patient registrations of a pelvis phantom using a single (AP) view was 1.3 mm, compared to 0.4 mm using dual (AP+Lat) views. Registration of the robot in air (i.e., no background anatomy) with five unique end effector poses achieved mean translational difference ∼1.4 mm for K-wire placement in the pelvis, comparable to tracker-based margins of error (commonly ∼2 mm). Conclusions. The proposed approach is feasible based on the accuracy of the patient and robot registrations and is a preliminary step in developing an image-guided robotic guidance system that more naturally fits the workflow of fluoroscopically guided orthopaedic trauma surgery. Future work will involve end-to-end development of the proposed guidance system and assessment of the system with delivery of K-wires in cadaver studies.

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ER -

Image-guided robotic k-wire placement for orthopaedic trauma surgery

Abstract

Publication series

Conference

Keywords

ASJC Scopus subject areas

Access to Document

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