3D reconstruction from projection matrices in a C-arm based 3D-angiography system

Navab, Nassir; Bani‐Hashemi, A; Nadar, Mariappan S.; Wiesent, K.; Durlak, Peter; Brunner, Thomas; Barth, K.; Graumann, Rainer

doi:10.1007/bfb0056194

Cited by 43 publications

(42 citation statements)

References 14 publications

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“…While the filtering steps were implemented using fast Fourier space methods using FFT, back-projection steps were efficiently implemented by using projection matrices that intrinsically describe the projection geometry [8], [9] and [10]. 4.…”

Section: Resultsmentioning

confidence: 99%

Tomographic Reconstruction for Truncated Cone Beam Data Using Prior CT Information

Ramamurthi

Prince

2003

Lecture Notes in Computer Science

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Abstract. C-arms can be used in surgery to acquire rotational conebeam data, which can be used to obtain three-dimensional reconstructions of anatomy. In many scenarios, there is insufficient space or capability to obtain the large angular rotations required to reconstruct artifact-free anatomy. Projection data can also suffer from truncation, which causes additional artifacts in three-dimensional reconstruction. In this paper we present a method that compensates for truncation using prior information from computed tomography and provides accurate reconstruction in the mid-plane under certain conditions.

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Section: Resultsmentioning

confidence: 99%

Tomographic Reconstruction for Truncated Cone Beam Data Using Prior CT Information

Ramamurthi

Prince

2003

Lecture Notes in Computer Science

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“…Direct motion estimation from consecutive projection matrices as shown in [7] is more precise than motion estimation by decomposing these projection matrices and computing the extrinsic parameters for each frame. We therefore propose a scenario in which we do not need to compute the intrinsic parameters of either our X-ray imaging system or the optical one.…”

Section: Determination Of X-ray Projection Matrices For a Camcmentioning

confidence: 99%

“…On-line calibration: For each frame, the motion of the X-ray source relative to its position in the off-line calibration step is computed using optical cameras. This is done by computing the projection matrix for optical camera and estimating the motion without ever computing its intrinsic parameters: ([R, t] = f (P c , P c )), see [7] for more details on direct motion estimation. We then apply this motion to the reference X-ray projection matrix P x , resulting in X-ray projection matrixP x = P x · R t 0 T 1 .…”

Section: Determination Of X-ray Projection Matrices For a Camcmentioning

confidence: 99%

“…We use the Xray phantom and calibration process used in [7]. X-ray phantoms interfere with the patient's X-ray image and cannot be used for mobile C-arm systems in real application.…”

Section: Motion Platformmentioning

confidence: 99%

“…1 In order to obtain the three-dimensional reconstruction the position of the C-arm mounted X-ray source and detector relative to the patient has to be measured. If the C-arm geometry is reproducible, the geometrical calibration can be done off-line using X-ray phantoms [9,2,7] and the pose information can be used for the patient examination. However mobile C-arm systems do not guarantee reproducible motion for consecutive examinations.…”

Section: Introductionmentioning

confidence: 99%

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Camera-Augmented Mobile C-arm (CAMC) Application: 3D Reconstruction Using a Low-Cost Mobile C-arm

Navab

Mitschke

Schütz

1999

Lecture Notes in Computer Science

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Abstract. High-end X-ray C-arm gantries have recently been used for 3D reconstruction. Low-cost mobile C-arms enjoy the advantage of being readily available and are often used as interventional imaging device, but do not guarantee the reproducibility of their motion. The calibration and reconstruction process used for high-end C-arms cannot be applied to them. Camera-Augmented Mobile C-arm (CAMC) is the solution we propose. A CCD camera is attached to the (motorized) mobile C-arm in order to calibrate the C-arm's projection geometry on-line. The relationship between X-ray and camera projection geometry is characterized in an off-line calibration process. We propose the notion of Virtual Detector (VD), which enables us to describe both optical and X-ray geometry as pinhole cameras with fixed intrinsic parameters. We have conducted experiments in order to compare the results of CAMC calibration with the calibration method used for high-end C-arms and using an optical tracking system (Polaris from Northern Digital, Inc.).

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Reduced anatomical clutter in digital breast tomosynthesis with statistical iterative reconstruction

Garrett

et al. 2018

Medical Physics

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Statistical image reconstruction enabled a significant reduction of both the through-plane artifacts level and anatomical clutter in the DBT reconstructions. The β value was found to be β≈2.14 with the SIR method. This value stays in the middle between the β≈1.8 for cone beam CT and β≈3.2 for mammography. In contrast, the measured β value in the clinical reconstructions (β≈3.17) remains close to that of mammography.

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3D reconstruction from projection matrices in a C-arm based 3D-angiography system

Cited by 43 publications

References 14 publications

Tomographic Reconstruction for Truncated Cone Beam Data Using Prior CT Information

Tomographic Reconstruction for Truncated Cone Beam Data Using Prior CT Information

Camera-Augmented Mobile C-arm (CAMC) Application: 3D Reconstruction Using a Low-Cost Mobile C-arm

Reduced anatomical clutter in digital breast tomosynthesis with statistical iterative reconstruction

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