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4. Grundlagen der Flachdetektor-CT (FD-CT)

Author

Kyriakou, Y., Struffert, T., Dörfler, A., and Kalender, W.A.

Abstract

Zusammenfassung: Flachdetektoren (FD) sind für die Anwendung in der Radiographie und Fluoroskopie entwickelt worden, um die damaligen Standards – Film-Folien-Kombinationen (FFK) und Bildverstärker (BV) – zu ersetzen. Im Vergleich zu FFK und BV bietet die FD-Technologie eine höhere Dynamik, Verzerrungsfreiheit und eine gesteigerte Dosiseffizienz. Weitere Vorteile sind die Anfertigung Serienaufnahmen, eine sofortige Digitalausgabe und eine kompakte Bauweise. Dies legt auch eine Anwendung von Flachdetektoren in der Computertomographie (CT) nahe. Inzwischen ist die FD-CT weitgehend in der interventionellen und intraoperativen Bildgebung etabliert – meist als C-Bogen-System. Die FD-Technologie hat erstmals die Weichteilbildgebung in der interventionellen Suite ermöglicht, was mit BV-Systemen nicht möglich war. Diese Übersichtsarbeit konzentriert sich auf die technischen Eigenschaften der FD-Technologie im Hinblick auf die interventionelle 3D-Bildgebung. Das Ziel der FD-CT ist nicht, die klinische CT hinsichtlich der typischen diagnostischen Untersuchungen zu ersetzen. Ihre Vorteile sind v. a. praktischer Art, wie die sofortige Verfügbarkeit der CT-Bildgebung während einer Intervention.

Published
2024
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6. Evaluation of a metal artifact reduction algorithm for flat panel detector CT-angiography in patients after surgical or endovascular treatment of intracranial aneurysms

Author

Pjontek, R, Önenköprülü, B, Hänsel, N, Kyriakou, Y, Scholz, B, Schubert, G, Nikoubashman, O, Othman, A, Wiesmann, M, and Brockmann, MA

Subjects
metal artifact reduction, ddc: 610, clipping, 610 Medical sciences, Medicine, intracranial aneurysm
Abstract

Objective: Flat panel detector angiographic computed tomography with intravenous contrast agent injection (ivACT) allows high-resolution imaging of cerebro-vascular structures. Metal artifacts caused by metallic implants like clips or coils lead to relevant degradation of image quality and are considered[for full text, please go to the a.m. URL], 66. Jahrestagung der Deutschen Gesellschaft für Neurochirurgie (DGNC)

Published
2015
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8. Accelerating ring artifact correction for flat-detector CT using the CUDA framework

Author

Willi A. Kalender, D. Prell, Kyriakou Y, and W. Chen

Subjects
CUDA, Pixel, Computer science, Image quality, Sorted array, Computer graphics (images), Ring Artifact, Detector, Median filter, Filter (signal processing), Algorithm
Abstract

Ring artifacts often appear in flat-detector CT because of imperfect or defect detector elements or calibration. In high-spatial resolution CT images reducing such artifacts becomes a necessity. In this paper, we used the post-processing ring correction in polar coordinates (RCP)1 to eliminate the ring artifacts. The median filter is applied to the uncorrected images in polar coordinates and ring artifacts are extracted from the original images. The algorithm has a very high computational cost due to the time-expensive median filtering and coordinate transformation on CPUs. Graphics processing units (GPUs)ca n be seen as parallel co-processors with high computational power. All steps of the RCP algorithm were implemented with CUDA2(Compute Unified Device Architecture, NVIDIA). We introduced a new GPU-based branchless vectorized median (BVM)filter. 3, 4 This algorithm is based on minmax sorting and keeps track of a sorted array from which values are deleted and to which new values are inserted. For comparison purpose a modified pivot median filter5 on GPUs was presented, which compares a pivot element to all other values and recursively finds the median element. We evaluated the performance of the RCP method using 512 slices, each slice consisted of 512×512 pixels. This post-processing method efficiently reduces ring artifacts in the reconstructed images and improves image quality. Our CUDAbased RCP is up to 13.6 times faster than the optimized CPU-based (single core)r outine. Comparing our two GPU-based median filters showed a performance benefit by roughly 60% when switching from Pivot to BVM code. The main reason is that the BVM algorithm is branchless and makes use of data-level parallelism. The BVM method is better suited to the model of modern graphics processing. A multi-GPU solution showed that the performance scaled nearly linearly.

Published
2010
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29. Robot arm based flat panel CT-guided electromagnetic tracked spine interventions: phantom and animal model experiments.

Author

Penzkofer T, Isfort P, Bruners P, Wiemann C, Kyriakou Y, Kalender WA, Günther RW, Schmitz-Rode T, Mahnken AH, Penzkofer, Tobias, Isfort, Peter, Bruners, Philipp, Wiemann, Christian, Kyriakou, Yiannis, Kalender, Willi A, Günther, Rolf W, Schmitz-Rode, Thomas, and Mahnken, Andreas H

Abstract

Purpose: To evaluate accuracy and procedure times of electromagnetic tracking (EMT) in a robotic arm mounted flat panel setting using phantom and animal cadaveric models.Methods and Materials: A robotic arm mounted flat panel (RMFP) was used in combination with EMT to perform anthropomorphic phantom (n = 90) and ex vivo pig based punctures (n = 120) of lumbar facet joints (FJ, n = 120) and intervertebral discs (IVD, n = 90). Procedure accuracies and times were assessed and evaluated.Results: FJ punctures were carried out with a spatial accuracy of 0.8 ± 0.9 mm (phantom) and 0.6 ± 0.8 mm (ex vivo) respectively. While IVD punctures showed puncture deviations of 0.6 ± 1.2 mm (phantom) and 0.5 ± 0.6 mm (ex vivo), direct and angulated phantom based punctures had accuracies of 0.8 ± 0.9 mm and 1.0 ± 1.3 mm. Planning took longer for ex vivo IVD punctures compared to phantom model interventions (39.3 ± 17.3 s vs. 20.8 ± 5.0 s, p = 0.001) and for angulated vs. direct phantom FJ punctures (19.7 ± 5.1 s vs. 28.6 ± 7.8 s, p < 0.001). Puncture times were longer for ex vivo procedures when compared to phantom model procedures in both FJ (37.9 ± 9.0 s vs. 23.6 ± 7.2 s, p = 0.001) and IVD punctures (43.9 ± 16.1 s vs. 31.1 ± 6.4 s, p = 0.026).Conclusion: The combination of RMFP with EMT provides an accurate method of navigation for spinal interventions such as facet joint punctures and intervertebral disc punctures. [ABSTRACT FROM AUTHOR]

Published
2010
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30. Cardiac phase-correlated image reconstruction and advanced image processing in pulmonary CT imaging.

Author

Lapp RM, Kachelriess M, Ertel D, Kyriakou Y, Kalender WA, Lapp, Robert M, Kachelriess, Marc, Ertel, Dirk, Kyriakou, Yiannis, and Kalender, Willi A

Abstract

Image quality in pulmonary CT imaging is commonly degraded by cardiac motion artifacts. Phase-correlated image reconstruction algorithms known from cardiac imaging can reduce motion artifacts but increase image noise and conventionally require a concurrently acquired ECG signal for synchronization. Techniques are presented to overcome these limitations. Based on standard and phase-correlated images that are reconstructed using a raw data-derived synchronization signal, image-merging and temporal-filtering techniques are proposed that combine the input images automatically or interactively. The performance of the approaches is evaluated in patient and phantom datasets. In the automatic approach, areas of strong motion and static areas were well detected, providing an optimal combination of standard and phase-correlated images with no visible border between the merged regions. Image noise in the non-moving regions was reduced to the noise level of the standard reconstruction. The application of the interactive filtering allowed for an optimal adaptation of image noise and motion artifacts. Noise content after interactive filtering decreased with increasing temporal filter width used. We conclude that a combination of our motion-free merging approach and a dedicated interactive filtering procedure can highly improve pulmonary imaging with respect to motion artifacts and image noise. [ABSTRACT FROM AUTHOR]

Published
2009
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32. Comparison of a contrast-to-noise ratio-driven exposure control and a regular detector dose-driven exposure control in abdominal imaging in a clinical angiography system.

Author

Werncke T, Kemling M, Tashenov S, Hinrichs JB, Meine TC, Maschke SK, Kyriakou Y, Wacker FK, and Meyer BC

Subjects
Fluoroscopy, Humans, Phantoms, Imaging, Radiation Dosage, Angiography, Radiographic Image Enhancement
Abstract

Purpose: The first purpose of this phantom study was to verify whether a contrast-to-noise ratio (CNR)-driven exposure control (CEC) can maintain target CNR in angiography more precisely compared to a conventional detector dose-driven exposure control (DEC). The second purpose was to estimate the difference between incident air kerma produced by CEC and DEC when both exposure controls reach the same CNR., Methods: A standardized 3D-printed phantom with an iron foil and a cavity, filled with iodinated contrast material, was developed to measure CNR using different image acquisition settings. This phantom was placed into a stack of polymethylmethacrylate and aluminum plates, simulating a patient equivalent thickness (PET) of 2.5-40 cm. Images were acquired using fluoroscopy and digital radiography modes with CEC using one image quality level and four image quality gradients and DEC having three different detector dose levels. The spatial frequency weighted CNR and incident air kerma were determined. The differences in incident air kerma between DEC and CEC were estimated., Results: When using DEC, CNR decreased continuously with increasing attenuation, while CEC within physical limits maintained a predefined CNR level. Furthermore, CEC could be parameterized to deliver the CNR as a predefined function of PET. To provide a given CNR level, CEC used equal or lower air kerma than DEC. The mean estimated incident air kerma of CEC compared to DEC was between 3% (PET 20 cm) and 40% (PET 27.5 cm) lower in fluoroscopy and between 1% (PET 20 cm) and 55% (PET 2.5 cm) lower in digital radiography while maintaining CNR., Conclusion: Within physical and legislative limits, the CEC allows for a flexible adjustment of the CNR as a function of PET. Thus, the CEC enables task-dependent examination protocols with predefined image quality in order to easier achieve the as low as reasonably achievable principle. CEC required equal or lower incident air kerma than DEC to provide similar CNR, which allows for a substantial reduction of skin radiation dose in these situations., (© 2021 The Authors. Medical Physics published by Wiley Periodicals LLC on behalf of American Association of Physicists in Medicine.)

Published
2021
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33. Impact of a contrast-to-noise ratio driven and material specific exposure control on image quality and radiation exposure in angiography.

Author

Werncke T, Kemling M, Tashenov S, Hinrichs JB, Meine TC, Maschke SK, Kyriakou Y, Wacker FK, and Meyer BC

Subjects
Barium, Fluoroscopy methods, Humans, Imaging, Three-Dimensional methods, Iodine, Iron, Positron-Emission Tomography, Radiation Dosage, Radiation Exposure, Radiography, Skin radiation effects, X-Rays, Angiography methods, Contrast Media, Phantoms, Imaging, Radiographic Image Enhancement methods
Abstract

Conventional detector-dose driven exposure controls (DEC) do not consider the contrasting material of interest in angiography. Considering the latter when choosing the acquisition parameters should allow for optimization of x-ray quality and consecutively lead to a substantial reduction of radiation exposure. Therefore, the impact of a material-specific, contrast-to-noise ratio (CNR) driven exposure control (CEC) compared to DEC on radiation exposure was investigated. A 3D-printed phantom containing iron, tantalum, and platinum foils and cavities, filled with iodine, barium, and gas (carbon dioxide), was developed to measure the CNR. This phantom was placed within a stack of polymethylmethacrylate and aluminum plates simulating a patient equivalent thickness (PET) of 2.5-40 cm. Fluoroscopy and digital radiography (DR) were conducted applying either CEC or three, regular DEC protocols with parameter settings used in abdominal interventions. CEC protocols where chosen to achieve material-specific CNR values similar to those of DEC. Incident air kerma at the reference point(K a,r ), using either CEC or DEC, was assessed and possible K a,r reduction for similar CNR was estimated. We show that CEC provided similar CNR as DEC at the same or lower K a,r . When imaging barium, iron, and iodine K a,r was substantially reduced below a PET of 20 cm and between 25 cm and 30 cm for fluoroscopy and Dr When imaging platinum and tantalum using fluoroscopy and DR and gas using DR, the K a,r reduction was substantially higher. We estimate the K a,r reduction for these materials between 15% and 84% for fluoroscopy and DR between 15% and 93% depending on the PET. The results of this study demonstrate a high potential for skin dose reduction in abdominal radiology when using a material-specific CEC compared to DEC. This effect is substantial in imaging materials with higher energy K-edges, which is beneficial, for example, in long-lasting embolization procedures with tantalum-based embolization material in young patients with arterio-venous malformations.

Published
2021
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34. Metal artifact reduction for flat panel detector intravenous CT angiography in patients with intracranial metallic implants after endovascular and surgical treatment.

Author

Pjontek R, Önenköprülü B, Scholz B, Kyriakou Y, Schubert GA, Nikoubashman O, Othman A, Wiesmann M, and Brockmann MA

Subjects
Algorithms, Brain diagnostic imaging, Cerebral Arteries diagnostic imaging, Cerebral Veins diagnostic imaging, Computed Tomography Angiography, Contrast Media, Data Display, Humans, Intracranial Aneurysm diagnostic imaging, Metals, Surgical Instruments, Artifacts, Cerebral Angiography methods, Image Processing, Computer-Assisted methods, Prostheses and Implants, Stents, Tomography, X-Ray Computed methods
Abstract

Background: Flat panel detector CT angiography with intravenous contrast agent injection (IV CTA) allows high-resolution imaging of cerebrovascular structures. Artifacts caused by metallic implants like platinum coils or clips lead to degradation of image quality and are a significant problem., Objective: To evaluate the influence of a prototype metal artifact reduction (MAR) algorithm on image quality in patients with intracranial metallic implants., Methods: Flat panel detector CT after intravenous application of 80 mL contrast agent was performed with an angiography system (Artis zee; Siemens, Forchheim, Germany) using a 20 s rotation protocol (200° rotation angle, 20 s acquisition time, 496 projections). The data before and after MAR of 26 patients with a total of 34 implants (coils, clips, stents) were independently evaluated by two blinded neuroradiologists., Results: MAR improved the assessability of the brain parenchyma and small vessels (diameter <1 mm) in the neighborhood of metallic implants and at a distance of 6 cm (p<0.001 each, Wilcoxon test). Furthermore, MAR significantly improved the assessability of parent vessel patency and potential aneurysm remnants (p<0.005 each, McNemar test). MAR, however, did not improve assessability of stented vessels., Conclusions: When an intravenous contrast protocol is used, MAR significantly ameliorates the assessability of brain parenchyma, vessels, and treated aneurysms in patients with intracranial coils or clips., (Published by the BMJ Publishing Group Limited. For permission to use (where not already granted under a licence) please go to http://www.bmj.com/company/products-services/rights-and-licensing/)

Published
2016
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35. A novel technique for the measurement of CBF and CBV with robot-arm-mounted flat panel CT in a large-animal model.

Author

Beuing O, Boese A, Kyriakou Y, Deuerling-Zengh Y, Jöllenbeck B, Scherlach C, Lenz A, Serowy S, Gugel S, Rose G, and Skalej M

Subjects
Animals, Disease Models, Animal, Infarction, Middle Cerebral Artery diagnostic imaging, Sheep, Cerebral Angiography methods, Cerebrovascular Circulation physiology, Perfusion Imaging methods, Robotics methods, Stroke diagnostic imaging
Abstract

Background and Purpose: Endovascular therapy is an emerging treatment option in patients with acute ischemic stroke and especially in cases presenting late after symptom onset. Information about remaining viable tissue as measured with perfusion imaging is crucial for proper patient selection. The aim of this study was to investigate whether perfusion imaging with C-arm CT in the angiography suite is feasible and provides measurements comparable with ones made by CTP., Materials and Methods: The MCA was occluded surgically in 6 sheep. Perfusion studies were performed before surgery, immediately after, and at 3 hours after MCA occlusion by using a robotic flat panel detector C-arm angiographic system. For comparison, conventional CTP was performed at the same time points. Two different protocols with the C-arm CT were tested. Images were analyzed by 2 readers with regard to the presence and size of perfusion abnormalities., Results: With C-arm CT, perfusion abnormalities were detected with a high sensitivity and specificity when vessel occlusion was confirmed by criterion standard DSA. No difference was found between lesions sizes measured with the 2 C-arm CT protocols and CTP. Growth of the CBV lesions with time was captured with C-arm CT and CTP., Conclusions: In this small study, it was feasible to qualitatively measure CBV and CBF by using a flat panel detector angiographic system., (© 2014 by American Journal of Neuroradiology.)

Published
2014
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36. Performance evaluation of a C-Arm CT perfusion phantom.

Author

Boese A, Gugel S, Serowy S, Purmann J, Rose G, Beuing O, Skalej M, Kyriakou Y, and Deuerling-Zheng Y

Subjects
Angiography instrumentation, Brain blood supply, Cerebrovascular Circulation physiology, Humans, Regional Blood Flow physiology, Stroke physiopathology, Perfusion Imaging instrumentation, Phantoms, Imaging, Stroke diagnosis, Tomography Scanners, X-Ray Computed, Tomography, X-Ray Computed instrumentation
Abstract

Purpose: Brain perfusion measurement in stroke patients provides important information on the infarct area and state of involved tissue. Interventional C-Arm angiography systems can provide perfusion measurements. A CT perfusion phantom was developed for C-Arm perfusion imaging to test and evaluate this method and to aid in the design and validation of scan protocols., Methods: A phantom test device was designed based on the anatomy of the human head. Four feeding arteries divided into sixteen sub-branches that lead into a sintered board simulating brain parenchyma. Perfusion measurements were performed using two conventional clinical CT scanners as the gold standard and with a C-Arm CT system to test and compare the implementations. The phantom's input parameters, contrast medium and flow properties were varied. A cerebral perfusion deficit was simulated by occlusion of a feeding artery tube., Results: CT perfusion maps of the sintered board brain tissue surrogate were computed and qualitatively compared for both conventional CT and C-Arm CT systems. A characteristic flow pattern of the tissue board was identifiable in both modalities. The characteristic flow pattern of the resulting perfusion maps is reproducible. The calculated flow and volume were directly related., Conclusions: A new CT perfusion phantom was developed and tested. This phantom is an appropriate model for CT-based tissue perfusion measurements in both conventional CT scanners and C-Arm CT scanners. The influence of input parameter changes can be visualized. Perfusion deficits after occlusion of a feeding artery are readily simulated and identified with CT.

Published
2013
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37. Does preinterventional flat-panel computer tomography pooled blood volume mapping predict final infarct volume after mechanical thrombectomy in acute cerebral artery occlusion?

Author

Wagner M, Kyriakou Y, du Mesnil de Rochemont R, Singer OC, and Berkefeld J

Subjects
Adult, Aged, Aged, 80 and over, Angiography, Digital Subtraction methods, Brain Mapping, Carotid Artery, Internal diagnostic imaging, Carotid Artery, Internal surgery, Carotid Stenosis diagnostic imaging, Carotid Stenosis surgery, Cerebral Revascularization methods, Cohort Studies, Endovascular Procedures methods, Female, Follow-Up Studies, Humans, Infarction, Middle Cerebral Artery surgery, Male, Middle Aged, Pilot Projects, Preoperative Care methods, Retrospective Studies, Risk Assessment, Severity of Illness Index, Stroke surgery, Treatment Outcome, Infarction, Middle Cerebral Artery diagnostic imaging, Radiography, Interventional methods, Stroke diagnostic imaging, Thrombectomy methods, Tomography, X-Ray Computed methods
Abstract

Purpose: Decreased cerebral blood volume is known to be a predictor for final infarct volume in acute cerebral artery occlusion. To evaluate the predictability of final infarct volume in patients with acute occlusion of the middle cerebral artery (MCA) or the distal internal carotid artery (ICA) and successful endovascular recanalization, pooled blood volume (PBV) was measured using flat-panel detector computed tomography (FPD CT)., Materials and Methods: Twenty patients with acute unilateral occlusion of the MCA or distal ACI without demarcated infarction, as proven by CT at admission, and successful Thrombolysis in cerebral infarction score (TICI 2b or 3) endovascular thrombectomy were included. Cerebral PBV maps were acquired from each patient immediately before endovascular thrombectomy. Twenty-four hours after recanalization, each patient underwent multislice CT to visualize final infarct volume. Extent of the areas of decreased PBV was compared with the final infarct volume proven by follow-up CT the next day., Results: In 15 of 20 patients, areas of distinct PBV decrease corresponded to final infarct volume. In 5 patients, areas of decreased PBV overestimated final extension of ischemia probably due to inappropriate timing of data acquisition and misery perfusion., Conclusion: PBV mapping using FPD CT is a promising tool to predict areas of irrecoverable brain parenchyma in acute thromboembolic stroke. Further validation is necessary before routine use for decision making for interventional thrombectomy.

Published
2013
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38. Impact of a new metal artefact reduction algorithm in the noninvasive follow-up of intracranial clips, coils, and stents with flat-panel angiographic CTA: initial results.

Author

Psychogios MN, Scholz B, Rohkohl C, Kyriakou Y, Mohr A, Schramm P, Wachter D, Wasser K, and Knauth M

Subjects
Aged, Blood Vessel Prosthesis, Cerebral Angiography instrumentation, Female, Follow-Up Studies, Humans, Male, Mechanical Thrombolysis instrumentation, Metals, Middle Aged, Radiographic Image Interpretation, Computer-Assisted methods, Reproducibility of Results, Retrospective Studies, Sensitivity and Specificity, Tomography, X-Ray Computed instrumentation, Tomography, X-Ray Computed methods, Treatment Outcome, Algorithms, Artifacts, Cerebral Angiography methods, Intracranial Aneurysm diagnostic imaging, Intracranial Aneurysm surgery, Radiographic Image Enhancement methods, Stents
Abstract

Introduction: Flat-panel angiographic CT after intravenous contrast agent application (ivACT) is increasingly used as a follow-up examination after coiling, clipping, or stenting. The purpose of this study was to evaluate the feasibility of a new metal artefact reduction algorithm (MARA) in patients treated for intracranial aneurysms and stenosis., Methods: IvACT was performed on a flat-panel detector angiography system after intravenous application of 80 ml contrast media. The uncorrected raw images were transferred to a prototype reconstruction workstation where the MARA was applied. Two experienced neuroradiologists examined the corrected and uncorrected images on a commercially available workstation., Results: Artefacts around the implants were detected in all 16 uncorrected cases, while eight cases showed remaining artefacts after correction with the MARA. In the cases without correction, there were 11 cases with "extensive" artefacts and five cases with "many" artefacts. After correction, seven cases showed "few" and only one case "many" artefacts (Wilcoxon test, P < 0.001). Parent vessels were characterized as "not identifiable" in 62% of uncorrected images, while the delineation of parent vessels were classified as "excellent" in 50% of the cases after correction (Wilcoxon test, P = 0.001)., Conclusions: Use of the MARA in our study significantly reduced artefacts around metallic implants on ivACT images and allowed for the delineation of surrounding structures.

Published
2013
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39. Volume-of-interest imaging of the inner ear in a human temporal bone specimen using a robot- driven C-arm flat panel detector CT system.

Author

Kolditz D, Struffert T, Kyriakou Y, Bozzato A, Dörfler A, and Kalender WA

Subjects
Equipment Design, Equipment Failure Analysis, Feasibility Studies, Humans, Radiation Dosage, Reproducibility of Results, Sensitivity and Specificity, Ear, Inner diagnostic imaging, Imaging, Three-Dimensional instrumentation, Pattern Recognition, Automated methods, Radiographic Image Interpretation, Computer-Assisted instrumentation, Robotics instrumentation, Temporal Bone diagnostic imaging, Tomography, X-Ray Computed instrumentation
Abstract

VOI imaging can provide higher image quality at a reduced dose for a subregion. In this study with a robot-driven C-arm FDCT system, the goals were proof of feasibility for inner ear imaging, higher flexibility during data acquisition, and easier processing during reconstruction. First a low-dose OV scan was acquired allowing an orientation and enabling the selection of the VOI. The C-arm was then moved by the robotic system without a need for patient movement and the VOI was scanned with adapted parameters. Uncompromised artifact-free image quality was achieved by the 2-scan approach and the dose was reduced by 80%-90% in comparison with conventional MSCT and FPCT scans.

Published
2012
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40. Image features for misalignment correction in medical flat-detector CT.

Author

Wicklein J, Kunze H, Kalender WA, and Kyriakou Y

Subjects
Algorithms, Artifacts, Calibration, Computer Simulation, Equipment Design, Head pathology, Humans, Medical Errors, Models, Statistical, Motion, Phantoms, Imaging, Reproducibility of Results, Thorax pathology, Image Processing, Computer-Assisted methods, Tomography, X-Ray Computed instrumentation, Tomography, X-Ray Computed methods
Abstract

Purpose: Misalignment artifacts are a serious problem in medical flat-detector computed tomography. Generally, the geometrical parameters, which are essential for reconstruction, are provided by preceding calibration routines. These procedures are time consuming and the later use of stored parameters is sensitive toward external impacts or patient movement. The method of choice in a clinical environment would be a markerless online-calibration procedure that allows flexible scan trajectories and simultaneously corrects misalignment and motion artifacts during the reconstruction process. Therefore, different image features were evaluated according to their capability of quantifying misalignment., Methods: Projections of the FORBILD head and thorax phantoms were simulated. Additionally, acquisitions of a head phantom and patient data were used for evaluation. For the reconstruction different sources and magnitudes of misalignment were introduced in the geometry description. The resulting volumes were analyzed by entropy (based on the gray-level histogram), total variation, Gabor filter texture features, Haralick co-occurrence features, and Tamura texture features. The feature results were compared to the back-projection mismatch of the disturbed geometry., Results: The evaluations demonstrate the ability of several well-established image features to classify misalignment. The authors elaborated the particular suitability of the gray-level histogram-based entropy on identifying misalignment artifacts, after applying an appropriate window level (bone window)., Conclusions: Some of the proposed feature extraction algorithms show a strong correlation with the misalignment level. Especially, entropy-based methods showed very good correspondence, with the best of these being the type that uses the gray-level histogram for calculation. This makes it a suitable image feature for online-calibration.

Published
2012
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41. [Digital volume tomography (DVT) and multislice spiral CT (MSCT): an objective examination of dose and image quality].

Author

Kyriakou Y, Kolditz D, Langner O, Krause J, and Kalender W

Subjects
Anthropometry, Artifacts, Body Burden, Body Size, Filtration instrumentation, Humans, Quality Control, Sensitivity and Specificity, Technology Assessment, Biomedical, Phantoms, Imaging, Radiation Dosage, Radiation Monitoring instrumentation, Radiographic Image Enhancement instrumentation, Software, Spiral Cone-Beam Computed Tomography instrumentation
Abstract

Purpose: In the last five years digital volume tomographs (DVT) have found their way into the diagnostic imaging of the facial skull. In this study both the image quality and dose of DVT and multislice spiral CT (MSCT) in this field of application were investigated using established physical methods for CT., Materials and Methods: Measurements on DVT scanners of various manufacturers and on a modern MSCT scanner were performed. The investigation was based on equivalent dose levels for both modalities (CT dose index, CTDI). For this purpose, the dose was measured with an ionization chamber in a cylindrical PMMA phantom. For the evaluation of image quality, the spatial resolution, contrast and noise were investigated with phantoms established for CT., Results: MSCT exhibited spatial resolution values of 1.0 to 1.6 lp/mm, while DVT provided resolution between 0.6 and 1.0 lp/mm only. Thus, MSCT offered similar or better resolution at an equivalent dose. For soft tissue resolution, DVT showed significant image artifacts. MSCT yielded higher homogeneity and no significant artifacts, and the contrast steps of the phantom were more verifiable. The different DVT devices, from image intensifiers to modern flat-detector (FD) devices, showed significant differences in favor of the FD devices., Conclusion: For medium and high contrast applications (teeth/bones), DVT scanners can be an alternative to MSCT at comparable radiation exposure. However, MSCT offers advantages in terms of constantly good and controlled image quality with significantly more flexible scan parameters at a constant or lower dose and should therefore be given preference., (© Georg Thieme Verlag KG Stuttgart · New York.)

Published
2011
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42. Comparison of extended field-of-view reconstructions in C-arm flat-detector CT using patient size, shape or attenuation information.

Author

Kolditz D, Meyer M, Kyriakou Y, and Kalender WA

Subjects
Algorithms, Body Size, Head diagnostic imaging, Hip diagnostic imaging, Humans, Phantoms, Imaging, Radiography, Thoracic, Reproducibility of Results, Sensitivity and Specificity, Shoulder diagnostic imaging, Tomography, X-Ray Computed instrumentation, Radiation Protection methods, Tomography, X-Ray Computed methods
Abstract

In C-arm-based flat-detector computed tomography (FDCT) it frequently happens that the patient exceeds the scan field of view (SFOV) in the transaxial direction because of the limited detector size. This results in data truncation and CT image artefacts. In this work three truncation correction approaches for extended field-of-view (EFOV) reconstructions have been implemented and evaluated. An FDCT-based method estimates the patient size and shape from the truncated projections by fitting an elliptical model to the raw data in order to apply an extrapolation. In a camera-based approach the patient is sampled with an optical tracking system and this information is used to apply an extrapolation. In a CT-based method the projections are completed by artificial projection data obtained from the CT data acquired in an earlier exam. For all methods the extended projections are filtered and backprojected with a standard Feldkamp-type algorithm. Quantitative evaluations have been performed by simulations of voxelized phantoms on the basis of the root mean square deviation and a quality factor Q (Q = 1 represents the ideal correction). Measurements with a C-arm FDCT system have been used to validate the simulations and to investigate the practical applicability using anthropomorphic phantoms which caused truncation in all projections. The proposed approaches enlarged the FOV to cover wider patient cross-sections. Thus, image quality inside and outside the SFOV has been improved. Best results have been obtained using the CT-based method, followed by the camera-based and the FDCT-based truncation correction. For simulations, quality factors up to 0.98 have been achieved. Truncation-induced cupping artefacts have been reduced, e.g., from 218% to less than 1% for the measurements. The proposed truncation correction approaches for EFOV reconstructions are an effective way to ensure accurate CT values inside the SFOV and to recover peripheral information outside the SFOV.

Published
2011
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43. Reducing metal artifacts in computed tomography caused by hip endoprostheses using a physics-based approach.

Author

Prell D, Kyriakou Y, Kachelrie M, and Kalender WA

Subjects
Algorithms, Anthropometry, Foreign Bodies pathology, Hip Joint pathology, Humans, Image Processing, Computer-Assisted instrumentation, Metals, Physics, Software, Tomography, X-Ray Computed instrumentation, Artifacts, Foreign Bodies diagnostic imaging, Hip Joint diagnostic imaging, Hip Prosthesis, Image Processing, Computer-Assisted methods, Tomography, X-Ray Computed methods
Abstract

Purpose: Metal-induced artifacts may cause severe problems in clinical computed tomography (CT) imaging and may impair diagnosis as well as overall image quality. Many approaches for reducing these artifacts tackle the problem by simply ignoring or interpolating the metal traces in the raw data, which results in a general information loss and additional artifacts in the corrected image. It was the objective of this study to develop an approach aiming at correcting several physical artifact sources. We have also tried to minimize the impact on spatial resolution and attempted to avoid new artifacts resulting from the correction., Materials and Methods: The algorithm works with a first volumetric reconstruction followed by threshold-based metal prostheses segmentation. The segmented metal implants are then forward projected and the resulting sinogram entries are squared and combined, followed by a second reconstruction to yield correction volumes. The resulting volumes are then combined linearly with a combination weight determined to minimize the flatness of the initial image. A directional filtering algorithm following the beam hardening correction applies a nonlinear convolution in the metal traces of the sinogram which reduces existing metal-induced noise artifacts. Phantom measurements on a polyethylene (PE) disc with different inserts and a semi-anthropomorphic hip phantom with optional bone and titanium inserts were used for evaluating the algorithm. Patient datasets containing uni- and bilateral hip endoprostheses verified the applicability and efficiency on realistic clinical cases., Results: Deviations in CT values were reduced to below 3 HU on average. Image noise reduction of up to 70% was achieved (average noise reduction of 37%) with a more homogeneous CT value distribution in soft-tissue areas. A comparison to standard interpolation methods showed superior artifact suppression without producing artifacts caused by interpolation and without the general information loss in the close vicinity to the implants. The impact on spatial resolution was minimized as compared with interpolation algorithms., Conclusions: Metal artifacts caused by hip-endoprostheses were strongly reduced. Soft tissue areas and skeletal structures surrounding the implants were well restored. The correction works by postprocessing CT datasets and it is applicable to any reconstructed image without a priori knowledge.

Published
2010
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44. Empirical beam hardening correction (EBHC) for CT.

Author

Kyriakou Y, Meyer E, Prell D, and Kachelriess M

Subjects
Algorithms, Animals, Artifacts, Biophysical Phenomena, Humans, Phantoms, Imaging, Radiographic Image Interpretation, Computer-Assisted methods, Rats, Scattering, Radiation, X-Rays, Tomography, X-Ray Computed statistics & numerical data
Abstract

Purpose: Due to x-ray beam polychromaticity and scattered radiation, attenuation measurements tend to be underestimated. Cupping and beam hardening artifacts become apparent in the reconstructed CT images. If only one material such as water, for example, is present, these artifacts can be reduced by precorrecting the rawdata. Higher order beam hardening artifacts, as they result when a mixture of materials such as water and bone, or water and bone and iodine is present, require an iterative beam hardening correction where the image is segmented into different materials and those are forward projected to obtain new rawdata. Typically, the forward projection must correctly model the beam polychromaticity and account for all physical effects, including the energy dependence of the assumed materials in the patient, the detector response, and others. We propose a new algorithm that does not require any knowledge about spectra or attenuation coefficients and that does not need to be calibrated. The proposed method corrects beam hardening in single energy CT data., Methods: The only a priori knowledge entering EBHC is the segmentation of the object into different materials. Materials other than water are segmented from the original image, e.g., by using simple thresholding. Then, a (monochromatic) forward projection of these other materials is performed. The measured rawdata and the forward projected material-specific rawdata are monomially combined (e.g., multiplied or squared) and reconstructed to yield a set of correction volumes. These are then linearly combined and added to the original volume. The combination weights are determined to maximize the flatness of the new and corrected volume. EBHC is evaluated using data acquired with a modern cone-beam dual-source spiral CT scanner (Somatom Definition Flash, Siemens Healthcare, Forchheim, Germany), with a modern dual-source micro-CT scanner (Tomo-Scope Synergy Twin, CT Imaging GmbH, Erlangen, Germany), and with a modern C-arm CT scanner (Axiom Artis dTA, Siemens Healthcare, Forchheim, Germany). A large variety of phantom, small animal, and patient data were used to demonstrate the data and system independence of EBHC., Results: Although no physics apart from the initial segmentation procedure enter the correction process, beam hardening artifacts were significantly reduced by EBHC. The image quality for clinical CT, micro-CT, and C-arm CT was highly improved. Only in the case of C-arm CT, where high scatter levels and calibration errors occur, the relative improvement was smaller., Conclusions: The empirical beam hardening correction is an interesting alternative to conventional iterative higher order beam hardening correction algorithms. It does not tend to over- or undercorrect the data. Apart from the segmentation step, EBHC does not require assumptions on the spectra or on the type of material involved. Potentially, it can therefore be applied to any CT image.

Published
2010
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45. Volume-of-interest (VOI) imaging in C-arm flat-detector CT for high image quality at reduced dose.

Author

Kolditz D, Kyriakou Y, and Kalender WA

Subjects
Algorithms, Humans, Reproducibility of Results, Sensitivity and Specificity, Imaging, Three-Dimensional methods, Radiation Dosage, Radiation Protection methods, Radiographic Image Enhancement methods, Radiographic Image Interpretation, Computer-Assisted methods, Tomography, X-Ray Computed instrumentation, Tomography, X-Ray Computed methods
Abstract

Purpose: A novel method for flat-detector computed tomography was developed to enable volume-of-interest (VOI) imaging at high resolution, low noise, and reduced dose. For this, a full low-dose overview (OV) scan and a local high-dose scan of a VOI are combined., Methods: The first scan yields an overview of the whole object and enables the selection of an arbitrary VOI. The second scan of that VOI assures high image quality within the interesting volume. The combination of the two consecutive scans is based on a forward projection of the reconstructed OV volume that was registered to the VOI. The artificial projection data of the OV scan are combined with the measured VOI data in the raw data domain. Different projection values are matched by an appropriate transformation and weighting. The reconstruction is performed with a standard Feldkamp-type algorithm. In simulations, the combination of OV scan and VOI scan was investigated on a mathematically described phantom. In measurements, spatial resolution and noise were evaluated with image quality phantoms. Modulation transfer functions and noise values were calculated. Measurements of an anthropomorphic head phantom were used to validate the proposed method for realistic applications, e.g., imaging stents. In Monte Carlo simulations, 3D dose distributions were calculated and dose values were assessed quantitatively., Results: By the proposed combination method, an image is generated which covers the whole object and provides the VOI at high image quality. In the OV image, a resolution of 0.7 lp/mm (line pairs per millimeter) and noise of 63.5 HU were determined. Inside the VOI, resolution was increased to 2.4 lp/mm and noise was decreased to 18.7 HU. For the performed measurements, the cumulative dose was significantly reduced in comparison to conventional scans by up to 93%. The dose of a high-quality scan, for example, was reduced from 97 to less than 7 mGy, while keeping image quality constant within the VOI., Conclusions: The proposed VOI application with two scans is an effective way to ensure high image quality within the VOI while simultaneously reducing the cumulative patient dose.

Published
2010
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46. Metal artifact reduction for clipping and coiling in interventional C-arm CT.

Author

Prell D, Kyriakou Y, Struffert T, Dörfler A, and Kalender WA

Subjects
Cerebral Hemorrhage diagnostic imaging, Combined Modality Therapy, Equipment Design, Humans, Hydrocephalus diagnostic imaging, Sensitivity and Specificity, Algorithms, Artifacts, Embolization, Therapeutic, Image Enhancement instrumentation, Image Processing, Computer-Assisted instrumentation, Intracranial Aneurysm diagnostic imaging, Intracranial Aneurysm therapy, Metals, Platinum, Radiology, Interventional instrumentation, Surgical Instruments, Tomography, X-Ray Computed instrumentation
Abstract

Background and Purpose: Metallic implants induce massive artifacts in CT images which deteriorate image quality and often superimpose structures of interest. The purpose of this study was to apply and evaluate a dedicated MAR method for neuroradiologic intracranial clips and detachable platinum coiling events. We here report the first clinical results for MAR in FDCT., Materials and Methods: FDCT volume scans of several patients treated with endovascular coiling or intracranial clipping were corrected by using a dedicated FDCT MAR correction algorithm combined with an edge-preserving attenuation-normalization method in the projection space. Corrected and uncorrected images were compared by 2 experienced radiologists and evaluated for several image-quality features., Results: After application of our algorithm, implant delineation and visibility were highly improved. CT values compared with values in metal artifact-unaffected areas showed good agreement (average correction of 1300 HU). Image noise was reduced overall by 27%. Intracranial hemorrhage in the direct surroundings of the implanted coil or clip material was displayed without worrisome metal artifacts, and our algorithm even allowed diagnosis in areas where extensive information losses were seen. The high spatial resolution provided by FDCT imaging was well preserved., Conclusions: Our MAR method provided metal artifact-reduced images in every studied case. It reduced image noise and corrected CT values to levels comparable with images measured without metallic implants. An overall improvement of brain tissue modeling and implant visibility was achieved. MAR in neuroradiologic FDCT imaging is a promising step forward for better image quality and diagnosis in the presence of metallic implants.

Published
2010
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47. Imaging of cochlear implant electrode array with flat-detector CT and conventional multislice CT: comparison of image quality and radiation dose.

Author

Struffert T, Hertel V, Kyriakou Y, Krause J, Engelhorn T, Schick B, Iro H, Hornung J, and Doerfler A

Subjects
Artifacts, Electric Stimulation methods, Electrodes, Implanted, Equipment Design, Facial Nerve diagnostic imaging, Hearing Disorders therapy, Humans, Mastoid diagnostic imaging, Mastoid surgery, Postoperative Period, Radiation Dosage, Spiral Lamina diagnostic imaging, Tympanic Membrane diagnostic imaging, Tympanic Membrane surgery, Cochlea diagnostic imaging, Cochlear Implants, Image Enhancement instrumentation, Temporal Bone diagnostic imaging, Tomography, X-Ray Computed instrumentation
Abstract

Conclusion: Cochlear implantation assessment is possible using commercially available standard flat-detector computed tomography (FD-CT) protocols. Image quality is superior to multislice CT (MSCT). The radiation dose of FD-CT is lower in comparison with MSCT standard protocols and may therefore overcome the limitations of MSCT in the evaluation of cochlear implants., Objective: FD-CT offers higher spatial resolution than MSCT. Our objective was to compare the image quality of FD-CT to conventional MSCT in the visualization of a cochlear implant electrode array with respect to radiation exposure., Methods: An isolated temporal bone specimen was scanned using a commercially available FD-CT system and a 4 and 64 row MSCT scanner. Different scanning protocols were used. Image quality was assessed by four independent readers using a scoring system with different criteria describing delineation of the cochlea and the electrode array, image noise and spatial resolution. Radiation dose was measured using the CT dose index (CTDI) and a 16 cm acrylic phantom., Results: Image quality was rated superior for FD-CT for all criteria by all readers. Single electrode contacts were only visible in FD-CT and assessment of implant position was improved by FD-CT. The radiation dose of FD-CT was half that of MSCT standard protocols.

Published
2010
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48. A fast and pragmatic approach for scatter correction in flat-detector CT using elliptic modeling and iterative optimization.

Author

Meyer M, Kalender WA, and Kyriakou Y

Subjects
Aged, 80 and over, Computer Simulation, Female, Head diagnostic imaging, Hip diagnostic imaging, Humans, Monte Carlo Method, Phantoms, Imaging, Radiography, Thoracic instrumentation, Radiography, Thoracic methods, Time Factors, Tomography, X-Ray Computed instrumentation, Water, Algorithms, Artifacts, Models, Theoretical, Scattering, Radiation, Tomography, X-Ray Computed methods
Abstract

Scattered radiation is a major source of artifacts in flat detector computed tomography (FDCT) due to the increased irradiated volumes. We propose a fast projection-based algorithm for correction of scatter artifacts. The presented algorithm combines a convolution method to determine the spatial distribution of the scatter intensity distribution with an object-size-dependent scaling of the scatter intensity distributions using a priori information generated by Monte Carlo simulations. A projection-based (PBSE) and an image-based (IBSE) strategy for size estimation of the scanned object are presented. Both strategies provide good correction and comparable results; the faster PBSE strategy is recommended. Even with such a fast and simple algorithm that in the PBSE variant does not rely on reconstructed volumes or scatter measurements, it is possible to provide a reasonable scatter correction even for truncated scans. For both simulations and measurements, scatter artifacts were significantly reduced and the algorithm showed stable behavior in the z-direction. For simulated voxelized head, hip and thorax phantoms, a figure of merit Q of 0.82, 0.76 and 0.77 was reached, respectively (Q = 0 for uncorrected, Q = 1 for ideal). For a water phantom with 15 cm diameter, for example, a cupping reduction from 10.8% down to 2.1% was achieved. The performance of the correction method has limitations in the case of measurements using non-ideal detectors, intensity calibration, etc. An iterative approach to overcome most of these limitations was proposed. This approach is based on root finding of a cupping metric and may be useful for other scatter correction methods as well. By this optimization, cupping of the measured water phantom was further reduced down to 0.9%. The algorithm was evaluated on a commercial system including truncated and non-homogeneous clinically relevant objects.

Published
2010
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49. A novel forward projection-based metal artifact reduction method for flat-detector computed tomography.

Author

Prell D, Kyriakou Y, Beister M, and Kalender WA

Subjects
Algorithms, Artifacts, Brain diagnostic imaging, Cadaver, Computer Graphics, Computers, Humans, Models, Statistical, Pattern Recognition, Automated methods, Phantoms, Imaging, Radiographic Image Interpretation, Computer-Assisted instrumentation, Reproducibility of Results, Metals chemistry, Radiographic Image Interpretation, Computer-Assisted methods, Tomography, X-Ray Computed instrumentation, Tomography, X-Ray Computed methods
Abstract

Metallic implants generate streak-like artifacts in flat-detector computed tomography (FD-CT) reconstructed volumetric images. This study presents a novel method for reducing these disturbing artifacts by inserting discarded information into the original rawdata using a three-step correction procedure and working directly with each detector element. Computation times are minimized by completely implementing the correction process on graphics processing units (GPUs). First, the original volume is corrected using a three-dimensional interpolation scheme in the rawdata domain, followed by a second reconstruction. This metal artifact-reduced volume is then segmented into three materials, i.e. air, soft-tissue and bone, using a threshold-based algorithm. Subsequently, a forward projection of the obtained tissue-class model substitutes the missing or corrupted attenuation values directly for each flat detector element that contains attenuation values corresponding to metal parts, followed by a final reconstruction. Experiments using tissue-equivalent phantoms showed a significant reduction of metal artifacts (deviations of CT values after correction compared to measurements without metallic inserts reduced typically to below 20 HU, differences in image noise to below 5 HU) caused by the implants and no significant resolution losses even in areas close to the inserts. To cover a variety of different cases, cadaver measurements and clinical images in the knee, head and spine region were used to investigate the effectiveness and applicability of our method. A comparison to a three-dimensional interpolation correction showed that the new approach outperformed interpolation schemes. Correction times are minimized, and initial and corrected images are made available at almost the same time (12.7 s for the initial reconstruction, 46.2 s for the final corrected image compared to 114.1 s and 355.1 s on central processing units (CPUs)).

Published
2009
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50. Ring artifact correction for high-resolution micro CT.

Author

Kyriakou Y, Prell D, and Kalender WA

Subjects
Algorithms, Animals, Imaging, Three-Dimensional, Mice, Respiration, X-Ray Microtomography instrumentation, Artifacts, X-Ray Microtomography methods
Abstract

In high-resolution micro CT using flat detectors (FD), imperfect or defect detector elements may cause concentric-ring artifacts due to their continuous over- or underestimation of attenuation values, which often disturb image quality. We here present a dedicated image-based ring artifact correction method for high-resolution micro CT, based on median filtering of the reconstructed image and working on a transformed version of the reconstructed images in polar coordinates. This post-processing method reduced ring artifacts in the reconstructed images and improved image quality for phantom and in in vivo scans. Noise and artifacts were reduced both in transversal and in multi-planar reformations along the longitudinal axis.

Published
2009
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