Your search keyword '"Martinsen, Anne Catrine"' showing total 4 results

1. Iterative reconstruction improves image quality and reduces radiation dose in trauma protocols; A human cadaver study.

Author

Godt, Johannes Clemens, Johansen, Cathrine K, Martinsen, Anne Catrine T, Schulz, Anselm, Brøgger, Helga M, Jensen, Kristin, Stray-Pedersen, Arne, and Dormagen, Johann Baptist

Subjects

IMAGE reconstruction, COMPUTED tomography, RADIATION doses, HUMAN experimentation, DISEASE risk factors

Abstract

Background: Radiation-related cancer risk is an object of concern in CT of trauma patients, as these represent a young population. Different radiation reducing methods, including iterative reconstruction (IR), and spilt bolus techniques have been introduced in the recent years in different large scale trauma centers. Purpose: To compare image quality in human cadaver exposed to thoracoabdominal computed tomography using IR and standard filtered back-projection (FBP) at different dose levels. Material and methods: Ten cadavers were scanned at full dose and a dose reduction in CTDIvol of 5 mGy (low dose 1) and 7.5 mGy (low dose 2) on a Siemens Definition Flash 128-slice computed tomography scanner. Low dose images were reconstructed with FBP and Sinogram affirmed iterative reconstruction (SAFIRE) level 2 and 4. Quantitative image quality was analyzed by comparison of contrast-to-noise ratio (CNR) and signal-to-noise ratio (SNR). Qualitative image quality was evaluated by use of visual grading regression (VGR) by four radiologists. Results: Readers preferred SAFIRE reconstructed images over FBP at a dose reduction of 40% (low dose 1) and 56% (low dose 2), with significant difference in overall impression of image quality. CNR and SNR showed significant improvement for images reconstructed with SAFIRE 2 and 4 compared to FBP at both low dose levels. Conclusions: Iterative image reconstruction, SAFIRE 2 and 4, resulted in equal or improved image quality at a dose reduction of up to 56% compared to full dose FBP and may be used a strong radiation reduction tool in the young trauma population. [ABSTRACT FROM AUTHOR]

Published

2021

2. 100 days with scans of the same Catphan phantom on the same CT scanner.

Author

Husby, Ellen, Svendsen, Elisabeth D, Andersen, Hilde K, and Martinsen, Anne Catrine T

Subjects

IMAGE quality analysis, IMAGE processing, COMPUTED tomography, HELICAL springs, QUALITY control

Abstract

Quality control ( QC) of CT scanners is important to evaluate image quality and radiation dose. Different QC phantoms for testing image quality parameters on CT are commercially available, and Catphan phantoms are widely used for this purpose. More data from measured image quality parameters on CT are necessary to assess test methods, tolerance levels, and test frequencies. The aim of this study was to evaluate the stability of essential image quality parameters for axial and helical scans on one CT scanner over time. A Catphan 600 phantom was scanned on a Philips Ingenuity CT scanner for 100 days over a period of 6 months. At each day of testing, one helical scan covering the entire phantom and four axial scans covering four different modules in the phantom were performed. All images were uploaded into Image Owl for automatic analysis of CT numbers, modular transfer function ( MTF), low-contrast resolution, noise, and uniformity. In general, the different image quality parameters for both scan techniques were stable over time compared to given tolerance levels. Average measured CT numbers differed between axial and helical scans, while MTF was almost identical for helical and axial scans. Axial scans had better low-contrast resolution and less noise than helical scans. The uniformity was relatively similar for axial and helical scans. Most standard deviations of measured values were larger for helical scans compared to axial scans. Test results in this study were stable over time for both scan techniques, but further studies on different CT scanners are required to confirm that this also holds true for other systems. [ABSTRACT FROM AUTHOR]

Published

2017

3. A Weighted Histogram-Based Tone Mapping Algorithm for CT Images.

Author

Völgyes, David, Martinsen, Anne Catrine Trægde, Stray-Pedersen, Arne, Waaler, Dag, and Pedersen, Marius

Subjects

*COMPUTED tomography, *IMAGE processing, *HISTOGRAMS, *DATA visualization, *ALGORITHMS, *FAST Fourier transforms

Abstract

Computed Tomography (CT) images have a high dynamic range, which makes visualization challenging. Histogram equalization methods either use spatially invariant weights or limited kernel size due to the complexity of pairwise contribution calculation. We present a weighted histogram equalization-based tone mapping algorithm which utilizes Fast Fourier Transform for distance-dependent contribution calculation and distance-based weights. The weights follow power-law without distance-based cut-off. The resulting images have good local contrast without noticeable artefacts. The results are compared to eight popular tone mapping operators. [ABSTRACT FROM AUTHOR]

Published

2018

4. Image De-Quantization Using Plate Bending Model.

Author

Völgyes, David, Martinsen, Anne Catrine Trægde, Stray-Pedersen, Arne, Waaler, Dag, and Pedersen, Marius

Subjects

*IMAGE processing, *DISCRETIZATION methods, *PIXELS, *BIHARMONIC equations, *IMAGE reconstruction

Abstract

Discretized image signals might have a lower dynamic range than the display. Because of this, false contours might appear when the image has the same pixel value for a larger region and the distance between pixel levels reaches the noticeable difference threshold. There have been several methods aimed at approximating the high bit depth of the original signal. Our method models a region with a bended plate model, which leads to the biharmonic equation. This method addresses several new aspects: the reconstruction of non-continuous regions when foreground objects split the area into separate regions; the incorporation of confidence about pixel levels, making the model tunable; and the method gives a physics-inspired way to handle local maximal/minimal regions. The solution of the biharmonic equation yields a smooth high-order signal approximation and handles the local maxima/minima problems. [ABSTRACT FROM AUTHOR]

Published

2018