Your search keyword '"Vogt, S."' showing total 21 results

1. Multi-stage 3D–2D registration for correction of anatomical deformation in image-guided spine surgery

Author

Ketcha, M D, primary, De Silva, T, additional, Uneri, A, additional, Jacobson, M W, additional, Goerres, J, additional, Kleinszig, G, additional, Vogt, S, additional, Wolinsky, J-P, additional, and Siewerdsen, J H, additional

Published

2017

2. Intraoperative evaluation of device placement in spine surgery using known-component 3D–2D image registration

Author

Uneri, A, primary, De Silva, T, additional, Goerres, J, additional, Jacobson, M W, additional, Ketcha, M D, additional, Reaungamornrat, S, additional, Kleinszig, G, additional, Vogt, S, additional, Khanna, A J, additional, Osgood, G M, additional, Wolinsky, J-P, additional, and Siewerdsen, J H, additional

Published

2017

3. Spinal pedicle screw planning using deformable atlas registration

Author

Goerres, J, primary, Uneri, A, additional, De Silva, T, additional, Ketcha, M, additional, Reaungamornrat, S, additional, Jacobson, M, additional, Vogt, S, additional, Kleinszig, G, additional, Osgood, G, additional, Wolinsky, J-P, additional, and Siewerdsen, J H, additional

Published

2017

4. Registration of MRI to intraoperative radiographs for target localization in spinal interventions

Author

De Silva, T, primary, Uneri, A, additional, Ketcha, M D, additional, Reaungamornrat, S, additional, Goerres, J, additional, Jacobson, M W, additional, Vogt, S, additional, Kleinszig, G, additional, Khanna, A J, additional, Wolinsky, J-P, additional, and Siewerdsen, J H, additional

Published

2017

5. Performance evaluation of MIND demons deformable registration of MR and CT images in spinal interventions

Author

Reaungamornrat, S, primary, De Silva, T, additional, Uneri, A, additional, Goerres, J, additional, Jacobson, M, additional, Ketcha, M, additional, Vogt, S, additional, Kleinszig, G, additional, Khanna, A J, additional, Wolinsky, J-P, additional, Prince, J L, additional, and Siewerdsen, J H, additional

Published

2016

6. 3D–2D image registration for target localization in spine surgery: investigation of similarity metrics providing robustness to content mismatch

Author

De Silva, T, primary, Uneri, A, additional, Ketcha, M D, additional, Reaungamornrat, S, additional, Kleinszig, G, additional, Vogt, S, additional, Aygun, N, additional, Lo, S-F, additional, Wolinsky, J-P, additional, and Siewerdsen, J H, additional

Published

2016

7. Known-component 3D–2D registration for quality assurance of spine surgery pedicle screw placement

Author

Uneri, A, primary, De Silva, T, additional, Stayman, J W, additional, Kleinszig, G, additional, Vogt, S, additional, Khanna, A J, additional, Gokaslan, Z L, additional, Wolinsky, J-P, additional, and Siewerdsen, J H, additional

Published

2015

8. Evaluation of low-dose limits in 3D-2D rigid registration for surgical guidance

Author

Uneri, A, primary, Wang, A S, additional, Otake, Y, additional, Kleinszig, G, additional, Vogt, S, additional, Khanna, A J, additional, Gallia, G L, additional, Gokaslan, Z L, additional, and Siewerdsen, J H, additional

Published

2014

9. 3D–2D registration for surgical guidance: effect of projection view angles on registration accuracy

Author

Uneri, A, primary, Otake, Y, additional, Wang, A S, additional, Kleinszig, G, additional, Vogt, S, additional, Khanna, A J, additional, and Siewerdsen, J H, additional

Published

2013

10. Surgical navigation for guidewire placement from intraoperative fluoroscopy in orthopaedic surgery.

Author

Mekki L, Sheth NM, Vijayan RC, Rohleder M, Sisniega A, Kleinszig G, Vogt S, Kunze H, Osgood GM, Siewerdsen JH, and Uneri A

Subjects

Humans, Fluoroscopy methods, Imaging, Three-Dimensional methods, Orthopedic Procedures methods, Surgery, Computer-Assisted methods, Fractures, Bone surgery

Abstract

Objective . Surgical guidewires are commonly used in placing fixation implants to stabilize fractures. Accurate positioning of these instruments is challenged by difficulties in 3D reckoning from 2D fluoroscopy. This work aims to enhance the accuracy and reduce exposure times by providing 3D navigation for guidewire placement from as little as two fluoroscopic images. Approach . Our approach combines machine learning-based segmentation with the geometric model of the imager to determine the 3D poses of guidewires. Instrument tips are encoded as individual keypoints, and the segmentation masks are processed to estimate the trajectory. Correspondence between detections in multiple views is established using the pre-calibrated system geometry, and the corresponding features are backprojected to obtain the 3D pose. Guidewire 3D directions were computed using both an analytical and an optimization-based method. The complete approach was evaluated in cadaveric specimens with respect to potential confounding effects from the imaging geometry and radiographic scene clutter due to other instruments. Main results . The detection network identified the guidewire tips within 2.2 mm and guidewire directions within 1.1°, in 2D detector coordinates. Feature correspondence rejected false detections, particularly in images with other instruments, to achieve 83% precision and 90% recall. Estimating the 3D direction via numerical optimization showed added robustness to guidewires aligned with the gantry rotation plane. Guidewire tips and directions were localized in 3D world coordinates with a median accuracy of 1.8 mm and 2.7°, respectively. Significance . The paper reports a new method for automatic 2D detection and 3D localization of guidewires from pairs of fluoroscopic images. Localized guidewires can be virtually overlaid on the patient's pre-operative 3D scan during the intervention. Accurate pose determination for multiple guidewires from two images offers to reduce radiation dose by minimizing the need for repeated imaging and provides quantitative feedback prior to implant placement., (Creative Commons Attribution license.)

Published

2023

11. 3D-2D image registration in the presence of soft-tissue deformation in image-guided transbronchial interventions.

Author

Vijayan R, Sheth N, Mekki L, Lu A, Uneri A, Sisniega A, Magaraggia J, Kleinszig G, Vogt S, Thiboutot J, Lee H, Yarmus L, and Siewerdsen JH

Subjects

Animals, Swine, Cone-Beam Computed Tomography methods, Lung diagnostic imaging, Fluoroscopy methods, Algorithms, Imaging, Three-Dimensional methods, Surgery, Computer-Assisted methods

Abstract

Purpose . Target localization in pulmonary interventions (e.g. transbronchial biopsy of a lung nodule) is challenged by deformable motion and may benefit from fluoroscopic overlay of the target to provide accurate guidance. We present and evaluate a 3D-2D image registration method for fluoroscopic overlay in the presence of tissue deformation using a multi-resolution/multi-scale (MRMS) framework with an objective function that drives registration primarily by soft-tissue image gradients. Methods . The MRMS method registers 3D cone-beam CT to 2D fluoroscopy without gating of respiratory phase by coarse-to-fine resampling and global-to-local rescaling about target regions-of-interest. A variation of the gradient orientation (GO) similarity metric (denotedGO') was developed to downweight bone gradients and drive registration via soft-tissue gradients. Performance was evaluated in terms of projection distance error at isocenter (PDE iso ). Phantom studies determined nominal algorithm parameters and capture range. Preclinical studies used a freshly deceased, ventilated porcine specimen to evaluate performance in the presence of real tissue deformation and a broad range of 3D-2D image mismatch. Results . Nominal algorithm parameters were identified that provided robust performance over a broad range of motion (0-20 mm), including an adaptive parameter selection technique to accommodate unknown mismatch in respiratory phase. TheGO'metric yielded median PDE iso = 1.2 mm, compared to 6.2 mm for conventionalGO.Preclinical studies with real lung deformation demonstrated median PDE iso = 1.3 mm with MRMS +GO'registration, compared to 2.2 mm with a conventional transform. Runtime was 26 s and can be reduced to 2.5 s given a prior registration within ∼5 mm as initialization. Conclusions . MRMS registration via soft-tissue gradients achieved accurate fluoroscopic overlay in the presence of deformable lung motion. By driving registration via soft-tissue image gradients, the method avoided false local minima presented by bones and was robust to a wide range of motion magnitude., (© 2022 Institute of Physics and Engineering in Medicine.)

Published

2022

12. C-arm orbits for metal artifact avoidance (MAA) in cone-beam CT.

Author

Wu P, Sheth N, Sisniega A, Uneri A, Han R, Vijayan R, Vagdargi P, Kreher B, Kunze H, Kleinszig G, Vogt S, Lo SF, Theodore N, and Siewerdsen JH

Subjects

Algorithms, Artifacts, Humans, Imaging, Three-Dimensional methods, Pedicle Screws, Spine diagnostic imaging, Cone-Beam Computed Tomography instrumentation, Cone-Beam Computed Tomography methods, Image Processing, Computer-Assisted methods, Metals chemistry, Phantoms, Imaging, Spine surgery, Surgery, Computer-Assisted methods

Abstract

Metal artifacts present a challenge to cone-beam CT (CBCT) image-guided surgery, obscuring visualization of metal instruments and adjacent anatomy-often in the very region of interest pertinent to the imaging/surgical tasks. We present a method to reduce the influence of metal artifacts by prospectively defining an image acquisition protocol-viz., the C-arm source-detector orbit-that mitigates metal-induced biases in the projection data. The metal artifact avoidance (MAA) method is compatible with simple mobile C-arms, does not require exact prior information on the patient or metal implants, and is consistent with 3D filtered backprojection (FBP), more advanced (e.g. polyenergetic) model-based image reconstruction (MBIR), and metal artifact reduction (MAR) post-processing methods. The MAA method consists of: (i) coarse localization of metal objects in the field-of-view (FOV) via two or more low-dose scout projection views and segmentation (e.g. a simple U-Net) in coarse backprojection; (ii) model-based prediction of metal-induced x-ray spectral shift for all source-detector vertices accessible by the imaging system (e.g. gantry rotation and tilt angles); and (iii) identification of a circular or non-circular orbit that reduces the variation in spectral shift. The method was developed, tested, and evaluated in a series of studies presenting increasing levels of complexity and realism, including digital simulations, phantom experiment, and cadaver experiment in the context of image-guided spine surgery (pedicle screw implants). The MAA method accurately predicted tilted circular and non-circular orbits that reduced the magnitude of metal artifacts in CBCT reconstructions. Realistic distributions of metal instrumentation were successfully localized (0.71 median Dice coefficient) from 2-6 low-dose scout views even in complex anatomical scenes. The MAA-predicted tilted circular orbits reduced root-mean-square error (RMSE) in 3D image reconstructions by 46%-70% and 'blooming' artifacts (apparent width of the screw shaft) by 20-45%. Non-circular orbits defined by MAA achieved a further ∼46% reduction in RMSE compared to the best (tilted) circular orbit. The MAA method presents a practical means to predict C-arm orbits that minimize spectral bias from metal instrumentation. Resulting orbits-either simple tilted circular orbits or more complex non-circular orbits that can be executed with a motorized multi-axis C-arm-exhibited substantial reduction of metal artifacts in raw CBCT reconstructions by virtue of higher fidelity projection data, which are in turn compatible with subsequent MAR post-processing and/or polyenergetic MBIR to further reduce artifacts.

Published

2020

13. Multi-body 3D-2D registration for image-guided reduction of pelvic dislocation in orthopaedic trauma surgery.

Author

Han R, Uneri A, Ketcha M, Vijayan R, Sheth N, Wu P, Vagdargi P, Vogt S, Kleinszig G, Osgood GM, and Siewerdsen JH

Subjects

Algorithms, Fluoroscopy, Humans, Phantoms, Imaging, Imaging, Three-Dimensional methods, Joint Dislocations diagnostic imaging, Joint Dislocations surgery, Orthopedic Procedures, Pelvis injuries, Pelvis surgery, Surgery, Computer-Assisted

Abstract

Surgical reduction of pelvic dislocation is a challenging procedure with poor long-term prognosis if reduction does not accurately restore natural morphology. The procedure often requires long fluoroscopic exposure times and trial-and-error to achieve accurate reduction. We report a method to automatically compute the target pose of dislocated bones in preoperative CT and provide 3D guidance of reduction using routine 2D fluoroscopy. A pelvic statistical shape model (SSM) and a statistical pose model (SPM) were formed from an atlas of 40 pelvic CT images. Multi-body bone segmentation was achieved by mapping the SSM to a preoperative CT via an active shape model. The target reduction pose for the dislocated bone is estimated by fitting the poses of undislocated bones to the SPM. Intraoperatively, multiple bones are registered to fluoroscopy images via 3D-2D registration to obtain 3D pose estimates from 2D images. The method was examined in three studies: (1) a simulation study of 40 CT images simulating a range of dislocation patterns; (2) a pelvic phantom study with controlled dislocation of the left innominate bone; (3) a clinical case study investigating feasibility in images acquired during pelvic reduction surgery. Experiments investigated the accuracy of registration as a function of initialization error (capture range), image quality (radiation dose and image noise), and field of view (FOV) size. The simulation study achieved target pose estimation with translational error of median 2.3 mm (1.4 mm interquartile range, IQR) and rotational error of 2.1° (1.3° IQR). 3D-2D registration yielded 0.3 mm (0.2 mm IQR) in-plane and 0.3 mm (0.2 mm IQR) out-of-plane translational error, with in-plane capture range of ±50 mm and out-of-plane capture range of ±120 mm. The phantom study demonstrated 3D-2D target registration error of 2.5 mm (1.5 mm IQR), and the method was robust over a large dose range, down to 5 [Formula: see text]Gy/frame (an order of magnitude lower than the nominal fluoroscopic dose). The clinical feasibility study demonstrated accurate registration with both preoperative and intraoperative radiographs, yielding 3.1 mm (1.0 mm IQR) projection distance error with robust performance for FOV ranging from 340 × 340 mm 2 to 170 × 170 mm 2 (at the image plane). The method demonstrated accurate estimation of the target reduction pose in simulation, phantom, and a clinical feasibility study for a broad range of dislocation patterns, initialization error, dose levels, and FOV size. The system provides a novel means of guidance and assessment of pelvic reduction from routinely acquired preoperative CT and intraoperative fluoroscopy. The method has the potential to reduce radiation dose by minimizing trial-and-error and to improve outcomes by guiding more accurate reduction of joint dislocations.

Published

2020

14. Atlas-based automatic planning and 3D-2D fluoroscopic guidance in pelvic trauma surgery.

Author

Han R, Uneri A, De Silva T, Ketcha M, Goerres J, Vogt S, Kleinszig G, Osgood G, and Siewerdsen JH

Subjects

Adolescent, Adult, Aged, Algorithms, Bone Screws, Cadaver, Female, Fractures, Bone diagnostic imaging, Fractures, Bone pathology, Humans, Male, Middle Aged, Pelvis diagnostic imaging, Pelvis pathology, Young Adult, Fluoroscopy methods, Fractures, Bone surgery, Image Processing, Computer-Assisted methods, Imaging, Three-Dimensional methods, Pelvis surgery, Surgery, Computer-Assisted methods, Tomography, X-Ray Computed methods

Abstract

Percutaneous screw fixation in pelvic trauma surgery is a challenging procedure that often requires long fluoroscopic exposure times and trial-and-error insertion attempts along narrow bone corridors of the pelvis. We report a method to automatically plan surgical trajectories using preoperative CT and assist device placement by augmenting the fluoroscopic scene with planned trajectories. A pelvic shape atlas was formed from 40 CT images and used to construct a statistical shape model (SSM). Each member of the atlas included expert definition of volumetric regions representing safe trajectory within bone corridors for fixating 10 common fracture patterns. Patient-specific planning is obtained by mapping the SSM to the (un-segmented) patient CT via active shape model (ASM) registration and free-form deformation (FFD), and the resulting transformation is used to transfer the atlas trajectory volumes to the patient CT. Fluoroscopic images acquired during K-wire placement are in turn augmented with projection of the planned trajectories via 3D-2D registration. Registration performance was evaluated via leave-one-out cross-validation over the 40-member atlas, computing the root mean square error (RMSE) in pelvic surface alignment (volumetric registration error), the positive predicted value (PPV) of volumetric trajectories within bone corridors (safety of the automatically planned trajectories), and the distance between trajectories within the planned volume and the bone cortex (absence of breach). A cadaver study was conducted in which K-wires were placed under fluoroscopic guidance to validate 3D-2D registration accuracy and evaluate the potential utility of augmented fluoroscopy with planned trajectories. The leave-one-out cross-validation achieved surface RMSE of 2.2  ±  0.3 mm after ASM registration and 1.8  ±  0.2 mm after FFD refinement. Automatically determined surgical plans conformed within bone corridors with PPV  >  90% and centerline trajectory within 3-5 mm of the bone cortex. 3D-2D registration in the cadaver study achieved 0.3  ±  0.8 mm accuracy (in-plane translation) and  <4° accuracy (in-plane rotation). Fluoroscopic images augmented with planning data exhibited  >90% conformance of volumetric planning data overlay within bone, and all centerline trajectories were within safe corridors. The approach yields a method for both automatic planning of pelvic fracture fixation and augmentation of fluoroscopy for improved surgical precision and safety. The method does not require segmentation of the patient CT, operates without additional hardware (e.g. tracking systems), and is consistent with common workflow in fluoroscopically guided procedures. The approach has the potential to reduce operating time and radiation dose by minimizing trial-and-error attempts in percutaneous screw placement.

Published

2019

15. Real-time, image-based slice-to-volume registration for ultrasound-guided spinal intervention.

Author

De Silva T, Uneri A, Zhang X, Ketcha M, Han R, Sheth N, Martin A, Vogt S, Kleinszig G, Belzberg A, Sciubba DM, and Siewerdsen JH

Subjects

Algorithms, Humans, Magnetic Resonance Imaging, Phantoms, Imaging, Ultrasonography, Image Processing, Computer-Assisted methods, Spine diagnostic imaging, Spine surgery, Surgery, Computer-Assisted

Abstract

Real-time fusion of magnetic resonance (MR) and ultrasound (US) images could facilitate safe and accurate needle placement in spinal interventions. We develop an entirely image-based registration method (independent of or complementary to surgical trackers) that includes an efficient US probe pose initialization algorithm. The registration enables the simultaneous display of 2D ultrasound image slices relative to 3D pre-procedure MR images for navigation. A dictionary-based 3D-2D pose initialization algorithm was developed in which likely probe positions are predefined in a dictionary with feature encoding by Haar wavelet filters. Feature vectors representing the 2D US image are computed by scaling and translating multiple Haar basis filters to capture scale, location, and relative intensity patterns of distinct anatomical features. Following pose initialization, fast 3D-2D registration was performed by optimizing normalized cross-correlation between intra- and pre-procedure images using Powell's method. Experiments were performed using a lumbar puncture phantom and a fresh cadaver specimen presenting realistic image quality in spinal US imaging. Accuracy was quantified by comparing registration transforms to ground truth motion imparted by a computer-controlled motion system and calculating target registration error (TRE) in anatomical landmarks. Initialization using a 315-length feature vector yielded median translation accuracy of 2.7 mm (3.4 mm interquartile range, IQR) in the phantom and 2.1 mm (2.5 mm IQR) in the cadaver. By comparison, storing the entire image set in the dictionary and optimizing correlation yielded a comparable median accuracy of 2.1 mm (2.8 mm IQR) in the phantom and 2.9 mm (3.5 mm IQR) in the cadaver. However, the dictionary-based method reduced memory requirements by 47×  compared to storing the entire image set. The overall 3D error after registration measured using 3D landmarks was 3.2 mm (1.8 mm IQR) mm in the phantom and 3.0 mm (2.3 mm IQR) mm in the cadaver. The system was implemented in a 3D Slicer interface to facilitate translation to clinical studies. Haar feature based initialization provided accuracy and robustness at a level that was sufficient for real-time registration using an entirely image-based method for ultrasound navigation. Such an approach could improve the accuracy and safety of spinal interventions in broad utilization, since it is entirely software-based and can operate free from the cost and workflow requirements of surgical trackers.

Published

2018

16. A line fiducial method for geometric calibration of cone-beam CT systems with diverse scan trajectories.

Author

Jacobson MW, Ketcha MD, Capostagno S, Martin A, Uneri A, Goerres J, De Silva T, Reaungamornrat S, Han R, Manbachi A, Stayman JW, Vogt S, Kleinszig G, and Siewerdsen JH

Subjects

Humans, Image Processing, Computer-Assisted methods, Algorithms, Calibration, Cone-Beam Computed Tomography methods, Fiducial Markers, Phantoms, Imaging, Tomography Scanners, X-Ray Computed

Abstract

Modern cone-beam CT systems, especially C-arms, are capable of diverse source-detector orbits. However, geometric calibration of these systems using conventional configurations of spherical fiducials (BBs) may be challenged for novel source-detector orbits and system geometries. In part, this is because the BB configurations are designed with careful forethought regarding the intended orbit so that BB marker projections do not overlap in projection views. Examples include helical arrangements of BBs (Rougee et al 1993 Proc. SPIE 1897 161-9) such that markers do not overlap in projections acquired from a circular orbit and circular arrangements of BBs (Cho et al 2005 Med. Phys. 32 968-83). As a more general alternative, this work proposes a calibration method based on an array of line-shaped, radio-opaque wire segments. With this method, geometric parameter estimation is accomplished by relating the 3D line equations representing the wires to the 2D line equations of their projections. The use of line fiducials simplifies many challenges with fiducial recognition and extraction in an orbit-independent manner. For example, their projections can overlap only mildly, for any gantry pose, as long as the wires are mutually non-coplanar in 3D. The method was tested in application to circular and non-circular trajectories in simulation and in real orbits executed using a mobile C-arm prototype for cone-beam CT. Results indicated high calibration accuracy, as measured by forward and backprojection/triangulation error metrics. Triangulation errors on the order of microns and backprojected ray deviations uniformly less than 0.2 mm were observed in both real and simulated orbits. Mean forward projection errors less than 0.1 mm were observed in a comprehensive sweep of different C-arm gantry angulations. Finally, successful integration of the method into a CT imaging chain was demonstrated in head phantom scans.

Published

2018

17. Planning, guidance, and quality assurance of pelvic screw placement using deformable image registration.

Author

Goerres J, Uneri A, Jacobson M, Ramsay B, De Silva T, Ketcha M, Han R, Manbachi A, Vogt S, Kleinszig G, Wolinsky JP, Osgood G, and Siewerdsen JH

Subjects

Cadaver, Fluoroscopy methods, Humans, Imaging, Three-Dimensional methods, Pelvis diagnostic imaging, Algorithms, Bone Screws, Image Processing, Computer-Assisted methods, Pelvis surgery, Quality Assurance, Health Care, Surgery, Computer-Assisted methods, Tomography, X-Ray Computed methods

Abstract

Percutaneous pelvic screw placement is challenging due to narrow bone corridors surrounded by vulnerable structures and difficult visual interpretation of complex anatomical shapes in 2D x-ray projection images. To address these challenges, a system for planning, guidance, and quality assurance (QA) is presented, providing functionality analogous to surgical navigation, but based on robust 3D-2D image registration techniques using fluoroscopy images already acquired in routine workflow. Two novel aspects of the system are investigated: automatic planning of pelvic screw trajectories and the ability to account for deformation of surgical devices (K-wire deflection). Atlas-based registration is used to calculate a patient-specific plan of screw trajectories in preoperative CT. 3D-2D registration aligns the patient to CT within the projective geometry of intraoperative fluoroscopy. Deformable known-component registration (dKC-Reg) localizes the surgical device, and the combination of plan and device location is used to provide guidance and QA. A leave-one-out analysis evaluated the accuracy of automatic planning, and a cadaver experiment compared the accuracy of dKC-Reg to rigid approaches (e.g. optical tracking). Surgical plans conformed within the bone cortex by 3-4 mm for the narrowest corridor (superior pubic ramus) and  >5 mm for the widest corridor (tear drop). The dKC-Reg algorithm localized the K-wire tip within 1.1 mm and 1.4° and was consistently more accurate than rigid-body tracking (errors up to 9 mm). The system was shown to automatically compute reliable screw trajectories and accurately localize deformed surgical devices (K-wires). Such capability could improve guidance and QA in orthopaedic surgery, where workflow is impeded by manual planning, conventional tool trackers add complexity and cost, rigid tool assumptions are often inaccurate, and qualitative interpretation of complex anatomy from 2D projections is prone to trial-and-error with extended fluoroscopy time.

Published

2017

18. 3D–2D registration in mobile radiographs: algorithm development and preliminary clinical evaluation.

Author

Otake Y, Wang AS, Uneri A, Kleinszig G, Vogt S, Aygun N, Lo SF, Wolinsky JP, Gokaslan ZL, and Siewerdsen JH

Subjects

Abdomen, Cadaver, Computer Simulation, Humans, Phantoms, Imaging, Retrospective Studies, Algorithms, Fluoroscopy methods, Imaging, Three-Dimensional methods, Pelvis diagnostic imaging, Radiography, Thoracic, Spine diagnostic imaging, Tomography, X-Ray Computed methods

Abstract

An image-based 3D-2D registration method is presented using radiographs acquired in the uncalibrated, unconstrained geometry of mobile radiography. The approach extends a previous method for six degree-of-freedom (DOF) registration in C-arm fluoroscopy (namely 'LevelCheck') to solve the 9-DOF estimate of geometry in which the position of the source and detector are unconstrained. The method was implemented using a gradient correlation similarity metric and stochastic derivative-free optimization on a GPU. Development and evaluation were conducted in three steps. First, simulation studies were performed that involved a CT scan of an anthropomorphic body phantom and 1000 randomly generated digitally reconstructed radiographs in posterior-anterior and lateral views. A median projection distance error (PDE) of 0.007 mm was achieved with 9-DOF registration compared to 0.767 mm for 6-DOF. Second, cadaver studies were conducted using mobile radiographs acquired in three anatomical regions (thorax, abdomen and pelvis) and three levels of source-detector distance (~800, ~1000 and ~1200 mm). The 9-DOF method achieved a median PDE of 0.49 mm (compared to 2.53 mm for the 6-DOF method) and demonstrated robustness in the unconstrained imaging geometry. Finally, a retrospective clinical study was conducted with intraoperative radiographs of the spine exhibiting real anatomical deformation and image content mismatch (e.g. interventional devices in the radiograph that were not in the CT), demonstrating a PDE = 1.1 mm for the 9-DOF approach. Average computation time was 48.5 s, involving 687 701 function evaluations on average, compared to 18.2 s for the 6-DOF method. Despite the greater computational load, the 9-DOF method may offer a valuable tool for target localization (e.g. decision support in level counting) as well as safety and quality assurance checks at the conclusion of a procedure (e.g. overlay of planning data on the radiograph for verification of the surgical product) in a manner consistent with natural surgical workflow.

Published

2015

19. Soft-tissue imaging with C-arm cone-beam CT using statistical reconstruction.

Author

Wang AS, Stayman JW, Otake Y, Kleinszig G, Vogt S, Gallia GL, Khanna AJ, and Siewerdsen JH

Subjects

Head diagnostic imaging, Humans, Phantoms, Imaging, Radiography, Abdominal, Signal-To-Noise Ratio, Torso diagnostic imaging, Cone-Beam Computed Tomography methods, Image Processing, Computer-Assisted methods

Abstract

The potential for statistical image reconstruction methods such as penalized-likelihood (PL) to improve C-arm cone-beam CT (CBCT) soft-tissue visualization for intraoperative imaging over conventional filtered backprojection (FBP) is assessed in this work by making a fair comparison in relation to soft-tissue performance. A prototype mobile C-arm was used to scan anthropomorphic head and abdomen phantoms as well as a cadaveric torso at doses substantially lower than typical values in diagnostic CT, and the effects of dose reduction via tube current reduction and sparse sampling were also compared. Matched spatial resolution between PL and FBP was determined by the edge spread function of low-contrast (∼ 40-80 HU) spheres in the phantoms, which were representative of soft-tissue imaging tasks. PL using the non-quadratic Huber penalty was found to substantially reduce noise relative to FBP, especially at lower spatial resolution where PL provides a contrast-to-noise ratio increase up to 1.4-2.2 × over FBP at 50% dose reduction across all objects. Comparison of sampling strategies indicates that soft-tissue imaging benefits from fully sampled acquisitions at dose above ∼ 1.7 mGy and benefits from 50% sparsity at dose below ∼ 1.0 mGy. Therefore, an appropriate sampling strategy along with the improved low-contrast visualization offered by statistical reconstruction demonstrates the potential for extending intraoperative C-arm CBCT to applications in soft-tissue interventions in neurosurgery as well as thoracic and abdominal surgeries by overcoming conventional tradeoffs in noise, spatial resolution, and dose.

Published

2014

20. 3D-2D registration for surgical guidance: effect of projection view angles on registration accuracy.

Author

Uneri A, Otake Y, Wang AS, Kleinszig G, Vogt S, Khanna AJ, and Siewerdsen JH

Subjects

Imaging, Three-Dimensional instrumentation, Tomography, X-Ray Computed instrumentation, Imaging, Three-Dimensional methods, Surgery, Computer-Assisted, Tomography, X-Ray Computed methods

Abstract

An algorithm for intensity-based 3D-2D registration of CT and x-ray projections is evaluated, specifically using single- or dual-projection views to provide 3D localization. The registration framework employs the gradient information similarity metric and covariance matrix adaptation evolution strategy to solve for the patient pose in six degrees of freedom. Registration performance was evaluated in an anthropomorphic phantom and cadaver, using C-arm projection views acquired at angular separation, Δθ, ranging from ∼0°-180° at variable C-arm magnification. Registration accuracy was assessed in terms of 2D projection distance error and 3D target registration error (TRE) and compared to that of an electromagnetic (EM) tracker. The results indicate that angular separation as small as Δθ ∼10°-20° achieved TRE <2 mm with 95% confidence, comparable or superior to that of the EM tracker. The method allows direct registration of preoperative CT and planning data to intraoperative fluoroscopy, providing 3D localization free from conventional limitations associated with external fiducial markers, stereotactic frames, trackers and manual registration.

Published

2014

21. Robust 3D-2D image registration: application to spine interventions and vertebral labeling in the presence of anatomical deformation.

Author

Otake Y, Wang AS, Webster Stayman J, Uneri A, Kleinszig G, Vogt S, Khanna AJ, Gokaslan ZL, and Siewerdsen JH

Subjects

Humans, Spine surgery, Fluoroscopy methods, Imaging, Three-Dimensional methods, Spine abnormalities, Spine diagnostic imaging, Tomography, X-Ray Computed methods

Abstract

We present a framework for robustly estimating registration between a 3D volume image and a 2D projection image and evaluate its precision and robustness in spine interventions for vertebral localization in the presence of anatomical deformation. The framework employs a normalized gradient information similarity metric and multi-start covariance matrix adaptation evolution strategy optimization with local-restarts, which provided improved robustness against deformation and content mismatch. The parallelized implementation allowed orders-of-magnitude acceleration in computation time and improved the robustness of registration via multi-start global optimization. Experiments involved a cadaver specimen and two CT datasets (supine and prone) and 36 C-arm fluoroscopy images acquired with the specimen in four positions (supine, prone, supine with lordosis, prone with kyphosis), three regions (thoracic, abdominal, and lumbar), and three levels of geometric magnification (1.7, 2.0, 2.4). Registration accuracy was evaluated in terms of projection distance error (PDE) between the estimated and true target points in the projection image, including 14 400 random trials (200 trials on the 72 registration scenarios) with initialization error up to ±200 mm and ±10°. The resulting median PDE was better than 0.1 mm in all cases, depending somewhat on the resolution of input CT and fluoroscopy images. The cadaver experiments illustrated the tradeoff between robustness and computation time, yielding a success rate of 99.993% in vertebral labeling (with 'success' defined as PDE <5 mm) using 1,718 664 ± 96 582 function evaluations computed in 54.0 ± 3.5 s on a mid-range GPU (nVidia, GeForce GTX690). Parameters yielding a faster search (e.g., fewer multi-starts) reduced robustness under conditions of large deformation and poor initialization (99.535% success for the same data registered in 13.1 s), but given good initialization (e.g., ±5 mm, assuming a robust initial run) the same registration could be solved with 99.993% success in 6.3 s. The ability to register CT to fluoroscopy in a manner robust to patient deformation could be valuable in applications such as radiation therapy, interventional radiology, and an assistant to target localization (e.g., vertebral labeling) in image-guided spine surgery.

Published

2013