Your search keyword '"Arboleda, Carolina"' showing total 8 results

1. Microbubbles as a contrast agent in grating interferometry mammography: an ex vivo proof-of-mechanism study.

Author

Lång K, Arboleda C, Forte S, Wang Z, Prevrhal S, Koehler T, Kuhn N, David B, Jefimovs K, Kubik-Huch RA, and Stampanoni M

Subjects

Animals, Chickens, Feasibility Studies, Iodine, Contrast Media, Interferometry, Mammography methods, Microbubbles

Abstract

Grating interferometry mammography (GIM) is an experimental breast imaging method at the edge of being clinically implemented. Besides attenuation, GIM can measure the refraction and scattering of x-rays resulting in differential phase contrast (DPC) and dark-field (DF) images. In this exploratory study, we assessed the feasibility of using microbubbles as a contrast agent in GIM. Two millilitres of microbubbles and iodine were respectively injected into ex vivo breast phantoms, consisting of fresh chicken breasts. Native and postcontrast images were acquired with a clinically compatible GIM setup, operated at 38 kVp, 14-s acquisition time, and with a dose of 1.3 mGy. The visibility of the contrast agents was analysed in a side-by-side comparison by three radiologists. The contrast-to-noise-ratio (CNR) was calculated for each contrast agent. We found that both contrast agents were judged to be visible by the readers. The mean CNR was 3.1 ± 1.9 for microbubbles in DF and 24.2 ± 6.5 for iodine in attenuation. In conclusion, this is a first proof-of-mechanism study that microbubbles could be used as a contrast agent in clinically compatible GIM, due to their scattering properties, which implies the potential use of a contrast agent with a high safety profile in x-ray-based breast imaging.

Published

2019

2. Towards clinical grating-interferometry mammography

Author

Arboleda, Carolina, Wang, Zhentian, Jefimovs, Konstantins, Koehler, Thomas, Van Stevendaal, Udo, Kuhn, Norbert, David, Bernd, Prevrhal, Sven, Lång, Kristina, Forte, Serafino, Kubik-Huch, Rahel Antonia, Leo, Cornelia, Singer, Gad, Marcon, Magda, Boss, Andreas, Roessl, Ewald, and Stampanoni, Marco

Published

2020

3. Microbubbles as a contrast agent in grating interferometry mammography: an ex vivo proof-of-mechanism study

Author

Lång, Kristina, Arboleda, Carolina, Forte, Serafino, Wang, Zhentian, Prevrhal, Sven, Koehler, Thomas, Kuhn, Norbert, David, Bernd, Jefimovs, Konstantins, Kubik-Huch, Rahel A., and Stampanoni, Marco

Subjects

Interferometry, Microbubbles, Contrast media, education, Phantoms (imaging), 3. Good health, Mammography

Abstract

Grating interferometry mammography (GIM) is an experimental breast imaging method at the edge of being clinically implemented. Besides attenuation, GIM can measure the refraction and scattering of x-rays resulting in differential phase contrast (DPC) and dark-field (DF) images. In this exploratory study, we assessed the feasibility of using microbubbles as a contrast agent in GIM. Two millilitres of microbubbles and iodine were respectively injected into ex vivo breast phantoms, consisting of fresh chicken breasts. Native and postcontrast images were acquired with a clinically compatible GIM setup, operated at 38 kVp, 14-s acquisition time, and with a dose of 1.3 mGy. The visibility of the contrast agents was analysed in a side-by-side comparison by three radiologists. The contrast-to-noise-ratio (CNR) was calculated for each contrast agent. We found that both contrast agents were judged to be visible by the readers. The mean CNR was 3.1 ± 1.9 for microbubbles in DF and 24.2 ± 6.5 for iodine in attenuation. In conclusion, this is a first proof-of-mechanism study that microbubbles could be used as a contrast agent in clinically compatible GIM, due to their scattering properties, which implies the potential use of a contrast agent with a high safety profile in x-ray-based breast imaging., European Radiology Experimental, 3 (1), ISSN:2509-9280

4. Towards clinical grating-interferometry mammography

Author

Arboleda, Carolina, Wang, Zhentian, Jefimovs, Konstantins, Koehler, Thomas, van Stevendaal, Udo, Kuhn, Norbert, David, Bernd, Prevrhal, Sven, Lång, Kristina, Forte, Serafino, Kubik-Huch, Rahel Antonia, Leo, Cornelia, Singer, Gad, Marcon, Magda, Boss, Andreas, Roessl, Ewald, and Stampanoni, Marco

Subjects

Interferometry, Phase contrast, 3. Good health, Mammography

Abstract

Objectives Grating-interferometry-based mammography (GIM) might facilitate breast cancer detection, as several research works have demonstrated in a pre-clinical setting, since it is able to provide attenuation, differential phase contrast, and scattering images simultaneously. In order to translate this technique to the clinics, it has to be adapted to cover a large field-of-view within a clinically acceptable exposure time and radiation dose. Methods We set up a grating interferometer that fits into a standard mammography system and fulfilled the aforementioned conditions. Here, we present the first mastectomy images acquired with this experimental device. Results and conclusion Our system performs at a mean glandular dose of 1.6 mGy for a 5-cm-thick, 18%-dense breast, and a field-of-view of 26 × 21 cm2. It seems to be well-suited as basis for a clinical-environment device. Further, dark-field signals seem to support an improved lesion visualization. Evidently, the effective impact of such indications must be evaluated and quantified within the context of a proper reader study. Key Points • Grating-interferometry-based mammography (GIM) might facilitate breast cancer detection, since it is sensitive to refraction and scattering and thus provides additional tissue information. • The most straightforward way to do grating-interferometry in the clinics is to modify a standard mammography device. • In a first approximation, the doses given with this technique seem to be similar to those of conventional mammography., European Radiology, 30, ISSN:0938-7994, ISSN:1432-1084

5. Can grating interferometry-based mammography discriminate benign from malignant microcalcifications in fresh biopsy samples?

Author

Forte, Serafino, Wang, Zhentian, Arboleda, Carolina, Lång, Kristina, Singer, Gad, Kubik-Huch, Rahel A., and Stampanoni, Marco

Subjects

*MAMMOGRAMS, *STEREOTAXIC techniques, *BIOPSY, *DUCTAL carcinoma, *MAGNETIC resonance mammography, *CARCINOMA in situ, *BREAST cancer, *ABSORPTION, *INTERFEROMETRY, *DIFFERENTIAL diagnosis, *CALCINOSIS, *BREAST, *BREAST tumors, *LONGITUDINAL method

Abstract

Purpose: In addition to absorption imaging, grating interferometry-based mammography (GIM) is capable of detecting differential-phase and scattering signals. In particular, the scattering signal can enable a quantifiable characterization of breast lesions. The purpose of this study was to determine if suspicious microcalcifications associated with benign or malignant lesions can be discriminated based on their absorption and scattering properties.Materials and Methods: In this prospective, ethically approved study, 62 patients (mean age 60 y, range 39-89) with suspicious microcalcifications, who underwent stereotactic biopsies, were included. Biopsies were measured with an experimental GIM device and the ratios of the scattering and absorption signal (R-value) for microcalcifications were calculated. The mean R-values for benign and malignant lesions associated with microcalcifications were compared with the final histopathological diagnosis using a t-test.Results: Twenty of the 62 participants had microcalcifications associated with malignancy. Comparing the two largest histopathological sub-groups of fibrosis (n = 23) vs. ductal carcinoma in situ (n = 15) resulted in an average R-value of 4.08 for benign and 2.80 for malignant lesions; p = 0.07. All microcalcifications associated with malignancy had an R-value below 4.71. Excluding microcalcifications with an R-value above this threshold would result in an 11 % reduction of false positives.Conclusion: The novel GIM modality has the potential to non-invasively characterize microcalcifications and might aid in the discrimination of benign from malignant lesions in fresh biopsy samples. [ABSTRACT FROM AUTHOR]

Published

2020

6. Grating-based interferometry and hybrid photon counting detectors: Towards a new era in X-ray medical imaging.

Author

Gkoumas, Spyridon, Wang, Zhentian, Abis, Matteo, Arboleda, Carolina, Tudosie, George, Donath, Tilman, Brönnimann, Christian, Schulze-Briese, Clemens, and Stampanoni, Marco

Subjects

*RADIOSCOPIC diagnosis, *DIAGNOSTIC imaging, *INTERFEROMETRY, *PHOTON counting, *REFRACTIVE index

Abstract

Progress in X-ray medical imaging and advances in detector developments have always been closely related. Similarly, a strong connection exists between innovations in synchrotron imaging and their implementation on table-top X-ray tube setups. The transfer of phase-based imaging to X-ray tubes can provide table-top setups with improved contrast between areas of low attenuation differences, by exploiting the unit decrement of the real part of the refractive index. Medical imaging is a potential application for such a system. Originally developed for synchrotron experiments, the novel generation of hybrid photon counting detectors is becoming increasingly popular due to their unique characteristics, such as small pixel size, negligible dark noise, fast counting and adjustable energy thresholds. Furthermore, novel room temperature semiconductor materials such as Cd(Zn)Te can provide higher quantum efficiency. In the first part of this article we review phase-contrast techniques and recent research towards medical applications. In the second part we present results and evaluate the potential of combining a table-top Talbot grating interferometry system with latest generation hybrid photon counting detectors. [ABSTRACT FROM AUTHOR]

Published

2016

7. Towards clinical grating-interferometry mammography

Author

Andreas Boss, Cornelia Leo, Marco Stampanoni, Sven Prevrhal, Bernd David, Konstantins Jefimovs, Zhentian Wang, Carolina Arboleda, Udo Van Stevendaal, Magda Marcon, Gad Singer, Thomas Koehler, Ewald Roessl, Rahel A. Kubik-Huch, Kristina Lång, Serafino Forte, Norbert Kuhn, University of Zurich, and Arboleda, Carolina

Subjects

medicine.medical_specialty, 610 Medicine & health, Context (language use), Mammography, Phase contrast, Interferometry, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, 2741 Radiology, Nuclear Medicine and Imaging, Medicine, Radiology, Nuclear Medicine and imaging, Medical physics, Breast, medicine.diagnostic_test, 10042 Clinic for Diagnostic and Interventional Radiology, business.industry, Attenuation, Grating interferometer, General Medicine, medicine.disease, 3. Good health, Visualization, 030220 oncology & carcinogenesis, Radiology, business, Grating interferometry

Abstract

Objectives Grating-interferometry-based mammography (GIM) might facilitate breast cancer detection, as several research works have demonstrated in a pre-clinical setting, since it is able to provide attenuation, differential phase contrast, and scattering images simultaneously. In order to translate this technique to the clinics, it has to be adapted to cover a large field-of-view within a clinically acceptable exposure time and radiation dose. Methods We set up a grating interferometer that fits into a standard mammography system and fulfilled the aforementioned conditions. Here, we present the first mastectomy images acquired with this experimental device. Results and conclusion Our system performs at a mean glandular dose of 1.6 mGy for a 5-cm-thick, 18%-dense breast, and a field-of-view of 26 × 21 cm2. It seems to be well-suited as basis for a clinical-environment device. Further, dark-field signals seem to support an improved lesion visualization. Evidently, the effective impact of such indications must be evaluated and quantified within the context of a proper reader study. Key Points • Grating-interferometry-based mammography (GIM) might facilitate breast cancer detection, since it is sensitive to refraction and scattering and thus provides additional tissue information. • The most straightforward way to do grating-interferometry in the clinics is to modify a standard mammography device. • In a first approximation, the doses given with this technique seem to be similar to those of conventional mammography.

Published

2019

8. Sensitivity-based optimization for the design of a grating interferometer for clinical X-ray phase contrast mammography

Author

Gerhard Martens, Carolina Arboleda, Matthias Bartels, Ewald Roessl, Zhentian Wang, Udo Van Stevendaal, Thomas Koehler, Pablo Villanueva-Perez, Marco Stampanoni, University of Zurich, and Arboleda, Carolina

Subjects

Wave propagation, Image quality, Computer science, Phase contrast microscopy, Physics::Medical Physics, Phase (waves), 610 Medicine & health, 02 engineering and technology, Grating, 3107 Atomic and Molecular Physics, and Optics, 030218 nuclear medicine & medical imaging, law.invention, 170 Ethics, 03 medical and health sciences, 0302 clinical medicine, Optics, law, medicine, Mammography, Figure of merit, 10237 Institute of Biomedical Engineering, Sensitivity (control systems), medicine.diagnostic_test, business.industry, Phase-contrast imaging, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, Interferometry, 0210 nano-technology, business

Abstract

An X-ray grating interferometer (GI) suitable for clinical mammography must comply with quite strict dose, scanning time and geometry limitations, while being able to detect tumors, microcalcifications and other abnormalities. Such a design task is not straightforward, since obtaining optimal phase-contrast and dark-field signals with clinically compatible doses and geometrical constraints is remarkably challenging. In this work, we present a wave propagation based optimization that uses the phase and dark-field sensitivities as figures of merit. This method was used to calculate the optimal interferometer designs for a commercial mammography setup. Its accuracy was validated by measuring the visibility of polycarbonate samples of different thicknesses on a Talbot-Lau interferometer installed on this device and considering some of the most common grating imperfections to be able to reproduce the experimental values. The optimization method outcomes indicate that small grating pitches are required to boost sensitivity in such a constrained setup and that there is a different optimal scenario for each signal type.

Published

2017