Your search keyword '"Alessandro Olivo"' showing total 65 results

1. Technical Note: Practical implementation strategies of cycloidal computed tomography

Author

Fabio A. Vittoria, Alessandro Olivo, Marco Endrizzi, Charlotte K. Hagen, Oriol Roche i Morgó, Roche i Morgo, O., Vittoria, F., Endrizzi, M., Olivo, A., and Hagen, C. K.

Subjects

Scanner, Offset (computer science), Computer science, Image quality, Field of view, phase contrast, Phantoms, Imaging, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Sampling (signal processing), Computer vision, spatial resolution, Tomography, Image resolution, Pixel, Phantoms, Imaging, business.industry, X-Rays, Detector, General Medicine, micro computed tomography, X-Ray Computed, Radiography, cycloidal computed tomography, 030220 oncology & carcinogenesis, structured illumination, Artificial intelligence, Tomography, X-Ray Computed, business

Abstract

Purpose: Cycloidal computed tomography is a novel imaging concept which combines a highly structured x-ray beam, offset lateral under-sampling, and mathematical data recovery to obtain high-resolution images efficiently and flexibly, even with relatively large source focal spots and detector pixels. The method reduces scanning time and, potentially, delivered dose compared to other sampling schemes. This study aims to present and discuss several implementation strategies for cycloidal computed tomography (CT) in order to increase its ease of use and facilitate uptake within the imaging community. Methods: The different implementation strategies presented are step-and-shoot, continuous unidirectional, continuous back-and-forth, and continuous pixel-wise scanning. In step-and-shoot scans the sample remains stationary while frames are acquired, whereas in all other cases the sample moves through the scanner continuously. The difference between the continuous approaches is the trajectory by which the sample moves within the field of view. Results: All four implementation strategies are compatible with a standard table-top x-ray setup. With the experimental setup applied here, step-and-shoot acquisitions yield the best spatial resolution (around 30µm), but are the most time-consuming (1.4h). Continuous unidirectional and back-and-forth images have resolution between 30 and 40µm, and are faster (35min). Continuous pixel-wise images are equally time-efficient, although technical challenges caused a small loss in image quality with a resolution of about 50µm. Conclusion: The authors show that cycloidal CT can be implemented in a variety of ways with high quality results. They believe this posits cycloidal CT as a powerful imaging alternative to more time-consuming and less flexible methods in the field.

Published

2021

2. Tracking based, high-resolution single-shot multimodal x-ray imaging in the laboratory enabled by the sub-pixel resolution capabilities of the MoNCH detector

Author

Rolf Brönnimann, E.S. Dreier, Anna Bergamaschi, GK Kallon, Ulrik Lund Olsen, Alessandro Olivo, and Marco Endrizzi

Subjects

010302 applied physics, Physics and Astronomy (miscellaneous), Pixel, business.industry, Attenuation, Detector, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, 02 engineering and technology, Grating, 021001 nanoscience & nanotechnology, 01 natural sciences, Sample (graphics), Differential phase, Optics, PHASE-CONTRAST, 0103 physical sciences, Dither, 0210 nano-technology, business, Sub-pixel resolution

Abstract

The simultaneous retrieval of x-ray attenuation, phase, and scattering using multimodal imaging techniques is finding increasing use in a range of applications, from medicine to materials science. Most techniques rely on the mechanical movement of an optical element (e.g., a grating or a mask) to obtain the multimodal images. While single-shot approaches exist, they typically employ detector pixels smaller than the grating period, often with low detection efficiency, and are limited in resolution unless either the sample or the optical element is displaced in various positions and multiple frames are collected. In this paper, we replace mechanical motion with the MoNCH detector's capability to reach sub-pixel resolutions by interpolating between neighboring pixels collecting the charge generated by a single x-ray event. This enabled us to obtain the pilot demonstration of a laboratory-based high-resolution, single-shot multimodal imaging technique capable of simultaneously retrieving attenuation, directional differential phase, and scatter images, without any mechanical movement. We show that our proof-of-concept setup enables a single-shot resolution of 19.5mu m and that the resulting images provide sufficient information to produce a reliable sample thickness map. Furthermore, we demonstrate that the setup is capable of producing single-shot directional scattering images, while leaving open the option to further increase the resolution by using sample dithering.

Published

2020

3. Cycloidal Computed Tomography

Author

Alessandro Olivo, Fabio A. Vittoria, Marco Endrizzi, Charlotte K. Hagen, and Oriol Roche i Morgó

Subjects

Physics, medicine.diagnostic_test, Pixel, business.industry, Detector, Process (computing), General Physics and Astronomy, Computed tomography, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Sample (graphics), Optics, Cycloid, 0103 physical sciences, medicine, Spatial frequency, 010306 general physics, 0210 nano-technology, business, Image resolution

Abstract

A general concept is presented for increasing the in-slice spatial resolution in computed tomography in a flexible manner and with relatively large source focal spots and detector pixels. The flexibility is a result of probing the sample with an array of thin beamlets shaped by a mask. Provided that the mask apertures are smaller than the combined blur of the x-ray source and detector and that no significant overlap between beamlets occurs, this introduces higher spatial frequencies into the image-formation process. The application of a cycloidal acquisition scheme, by which the sample is simultaneously rotated and translated, facilitates an efficient exploitation of these frequencies and their reconstruction into high-resolution tomographic images. Additionally, a preliminary study of the signal-to-noise ratio versus the delivered dose reveals significant dose-saving potential.

Published

2020

4. Simplified retrieval method for Edge Illumination X-ray phase contrast imaging allowing multi-modal imaging with fewer input frames

Author

Alessandro Olivo, Alberto Bravin, Paul C. Diemoz, Marco Endrizzi, Ian Buchanan, Alberto Mittone, Buchanan, I, Mittone, A, Bravin, A, Diemoz, P, Endrizzi, M, and Olivo, A

Subjects

Physics, Beam diameter, Pixel, Dynamic range, business.industry, Monte Carlo method, Detector, Phase-contrast imaging, FIS/07 - FISICA APPLICATA (A BENI CULTURALI, AMBIENTALI, BIOLOGIA E MEDICINA), 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Dark field microscopy, Atomic and Molecular Physics, and Optics, 010309 optics, Optics, X-Ray Phase-Contrast Imaging, 0103 physical sciences, 0210 nano-technology, business, phase retrieval, Edge Illumination, X-rays, phase contrast imaging

Abstract

We present data from an implementation of Edge Illumination (EI) that uses a detector aperture designed for increasing dynamic range, suitable for clinically relevant X-ray energies and demonstrated here using synchrotron radiation. By utilising a sufficiently large crosstalk between pixels, this implementation enables single-scan imaging for phase and absorption, and double-scan for phase, absorption and dark field imaging. The presence of the detector mask enables a direct comparison between conventional EI and beam tracking (BT), which we conduct through Monte Carlo and analytical modelling in the case of a single-scan being used for the retrieval of all three contrasts. In the present case, where the X-ray beam width is comparable to the pixel size, we provide an analysis on best-positioning of the beam on the detector for accurate signal retrieval. Further, we demonstrate an application of this method by distinguishing different concentrations of microbubbles via their dark field signals at high energy using an EI system.

Published

2020

5. Energy sensitive X-ray phase contrast imaging with a CdTe-Timepix3 detector

Author

C. Navarrete, Michael Fiederle, M. Schuetz, Carlos Avila, Gerardo Roque, Alessandro Olivo, S. Procz, and Julian Fey

Subjects

Photon, Materials science, Pixel, business.industry, Detector, Phase-contrast imaging, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Photon counting, Semiconductor detector, 010309 optics, Optics, X-Ray Phase-Contrast Imaging, 0103 physical sciences, 0210 nano-technology, business, Energy (signal processing)

Abstract

The Timepix3 is a photon counting semiconductor detector that enables to simultaneously measure the energy and time of arrival of each incident X- ray photon. These properties, along with the high spatial resolution and high efficiency, due to the CdTe sensor material, can be exploited for several imaging applications, such as X-ray phase contrast imaging (XPCI).XPCI relies on the phase shift suffered by X-rays when traversing the sample. This study focuses on the free-space propagation XPCI and single mask edge illumination XPCI methods, which are two approaches that are well suited for laboratory implementations.Since both techniques are highly sensitive to charge-sharing, the Timepix3 energy and time information for each photon are used to minimize this effect by using pixel clustering methods. In addition, the performance of both XPCI techniques across a 30kVp source spectrum is studied using the energy-resolving capabilities of the detector. In both cases, the phase contrast and signal-to-noise ratio (SNR) are assessed as a function of different energy. Finally, it is demonstrated that phase contrast enhancement is feasible with pixel clustering and energy-selection for both XPCI techniques.

Published

2019

6. Effective modeling of high-energy laboratory-based x-ray phase contrast imaging utilizing absorption masks or gratings

Author

GK Kallon, Ian Buchanan, Joachim Schulz, Marco Endrizzi, Thomas Beckenbach, and Alessandro Olivo

Subjects

010302 applied physics, Materials science, business.industry, Detector, Phase-contrast imaging, General Physics and Astronomy, Experimental data, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Power (physics), Optics, X-Ray Phase-Contrast Imaging, 0103 physical sciences, 0210 nano-technology, business, Absorption (electromagnetic radiation), Quality assurance, Beam (structure)

Abstract

Model refinements for the edge illumination x-ray phase contrast imaging method have been developed to improve simulation accuracy for high energy, polychromatic beams. High-energy x rays are desirable in imaging due to their penetrative power and, for biological samples, their lower dose deposition rate. Accurate models of such scenarios are required for designing appropriate imaging systems and to predict signal strength in complex settings such as clinical imaging or industrial quality assurance. When using optical components appropriate for high-energy x rays in a non-synchrotron setting, system performance was observed to deviate from that predicted by existing models. In this work, experimental data utilizing increasing thicknesses of a known filter material are used to illustrate the limitations of existing models and as validation for the new modeling features. Angular filtration of the cone beam was observed to be the most significant effect; however, specific features of the source and detector are also shown to affect system performance. We conclude by showing that a significantly improved agreement between experimental and simulated data is obtained with the refined model compared to previously existing ones.

Published

2020

7. Optimal and automated mask alignment for use in edge illumination X-ray differential-phase and dark-field imaging techniques

Author

Marco Endrizzi, Alessandro Olivo, Lorenzo Massimi, and Adam Doherty

Subjects

010302 applied physics, Physics, Nuclear and High Energy Physics, business.industry, Detector, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Dark field microscopy, Differential phase, Optical axis, Superposition principle, Optics, Position (vector), X-Ray Phase-Contrast Imaging, 0103 physical sciences, 0210 nano-technology, business, Instrumentation, Order of magnitude

Abstract

Edge illumination X-ray phase-contrast imaging makes use of two absorbing masks for precise beam shaping and analysis. As the system is being translated to clinical and industrial environments, a robust quantitative algorithm is required to keep the masks precisely aligned without the need of an expert operator. We present a model for how the illumination on the detector varies as one mask is moved relative to the rest of the system. This model is based on a superposition of known illumination patterns associated with misalignment in each degree of freedom. Through inversion of this model, quantitative estimates of the degree of misalignment can be obtained, and hence can show the position of optimal alignment. The precision of alignment achievable through model inversion was tested, showing at least an order of magnitude improvement when compared to the established mask alignment procedure. Precision of the alignment along the optical axis, and around the three rotational degrees of freedom were found to be [ ± 0 . 78 μ m , ± 0 . 17 mdeg, ± 5 . 08 mdeg, ± 2 . 39 mdeg] respectively, whereas the established procedure would be limited to [ ± 42 . 5 μ m , ± 6 . 69 mdeg, ± 348 mdeg, ± 195 mdeg]. Furthermore, the model allows the decomposition of residuals into random and systematic components, the latter enabling accurate evaluation of imperfections in the masks’ structure which have now become the main limiting factor in the final degree of alignment.

Published

2020

8. Spectral X-ray phase contrast imaging with a CdTe photon-counting detector

Author

Alessandro Olivo, Michael Fiederle, Gerardo Roque, S. Procz, Michael Kilian Schütz, Julian Fey, Carlos Navarrete, and Carlos Avila

Subjects

Physics, Nuclear and High Energy Physics, Photon, Pixel, Image quality, business.industry, Detector, Phase-contrast imaging, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Charge sharing, 010309 optics, Optics, X-Ray Phase-Contrast Imaging, 0103 physical sciences, 0210 nano-technology, business, Instrumentation, Energy (signal processing)

Abstract

The present study focuses on the implementation of two X-ray phase contrast imaging (XPCI) techniques: free-space propagation (FSP) and single mask edge illumination (SM-EI) with a microfocus polychromatic X-ray source and a Timepix3 photon-counting detector with a CdTe sensor. This detector offers high spatial resolution, high detection efficiency and it is able to simultaneously record information about Time-over-Threshold (ToT) and Time-of-Arrival (ToA) for each X-ray photon. All these features play a key role in enabling an improvement of XPCI image quality, especially through spectral analysis, since it is possible to measure the energy of each incident X-ray photon. Measurements of phase contrast and contrast-to-noise ratio (CNR) are presented for different energy bins within the typical spectrum of soft X-ray imaging. It is shown that a significant enhancement of XPCI image quality can be obtained, for both implemented techniques, by performing pixel clustering to correct for charge sharing and by introducing some degree of energy-weighting.

Published

2020

9. Single-Shot X-Ray Phase-Contrast Computed Tomography with Nonmicrofocal Laboratory Sources

Author

Paul C. Diemoz, Luca Urbani, Charlotte K. Hagen, Alessandro Olivo, M. Minuti, R. Bellazzini, P De Coppi, and Marco Endrizzi

Subjects

Physics, business.industry, Detector, X-ray, General Physics and Astronomy, Field of view, 02 engineering and technology, 021001 nanoscience & nanotechnology, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Optics, Feature (computer vision), Attenuation coefficient, 0210 nano-technology, business, Constant (mathematics), Refractive index

Abstract

We present a method that enables performing x-ray phase-contrast imaging (XPCI) computed tomography with a laboratory setup using a single image per projection angle, eliminating the need to move optical elements during acquisition. Theoretical derivation of the method is presented, and its validity conditions are provided. The object is assumed to be quasihomogeneous, i.e., to feature a ratio between the refractive index and the linear attenuation coefficient that is approximately constant across the field of view. The method is experimentally demonstrated on a plastics phantom and on biological samples using a continuous rotation acquisition scheme achieving scan times of a few minutes. Moreover, we show that such acquisition times can be further reduced with the use of a high-efficiency photon-counting detector. Thanks to its ability to substantially simplify the image-acquisition procedure and greatly reduce collection times, we believe this method represents a very important step towards the application of XPCI to real-world problems.

Published

2017

10. Large field-of-view asymmetric masks for high-energy x-ray phase imaging with standard x-ray tube

Author

Marco Endrizzi, Alberto Astolfo, Ian Haig, Benjamin Price, and Alessandro Olivo

Subjects

Physics, business.industry, Instrumentation, Detector, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Phase-contrast imaging, 02 engineering and technology, 021001 nanoscience & nanotechnology, X-ray tube, 01 natural sciences, Refraction, Sample (graphics), law.invention, 010309 optics, Optics, law, Aliasing, X-Ray Phase-Contrast Imaging, 0103 physical sciences, 0210 nano-technology, business, ComputingMethodologies_COMPUTERGRAPHICS

Abstract

We report on a new approach to large field-of-view laboratory-based X-ray phase-contrast imaging. The method is based upon the asymmetric mask design that enables the retrieval of the absorption, refraction and ultra-small- angle scattering properties of the sample without the need to move any component of the imaging system. The sample is scanned through the imaging system, which also removes possible aliasing problems that might arise from partial sample illumination when using the edge illumination technique. This concept can be extended to any desired number of apertures providing, at the same time, intensity projections at complementary illumination conditions. Experimental data simultaneously acquired at seven different illumination fractions are presented along with the results obtained from a numerical model that incorporates the actual detector performance. The ultimate shape of the illumination function is shown to be significantly dependent on these detector-specific characteristics. Based on this concept, a large field-of-view system was designed, which is also capable to cope with relatively high (100 kVp) X-ray energies. The imaging system obtained in this way, where the asymmetric mask design enables the data to be collected without moving any element of the instrumentation, adapts particularly well to those situations in medical, industrial and security imaging where the sample has to be scanned through the system.

Published

2016

11. The Dexela 2923 CMOS X-ray detector: A flat panel detector based on CMOS active pixel sensors for medical imaging applications

Author

Magdalena B. Szafraniec, Robert D. Speller, Anastasios C. Konstantinidis, and Alessandro Olivo

Subjects

Nuclear and High Energy Physics, medicine.medical_specialty, X-ray detector, DQE, Digital X-ray detector, 01 natural sciences, Noise (electronics), Flat panel detector, 030218 nuclear medicine & medical imaging, Detective quantum efficiency, 03 medical and health sciences, 0302 clinical medicine, Optics, 0103 physical sciences, Wide dynamic range, medicine, Medical physics, Instrumentation, Physics, 010308 nuclear & particles physics, Dynamic range, business.industry, Detector, Radiography, CMOS, CMOS APS, business, Mammography

Abstract

Complementary metal-oxide-semiconductors (CMOS) active pixel sensors (APS) have been introduced recently in many scientific applications. This work reports on the performance (in terms of signal and noise transfer) of an X-ray detector that uses a novel CMOS APS which was developed for medical X-ray imaging applications. For a full evaluation of the detector's performance, electro-optical and X-ray characterizations were carried out. The former included measuring read noise, full well capacity and dynamic range. The latter, which included measuring X-ray sensitivity, presampling modulation transfer function (pMTF), noise power spectrum (NPS) and the resulting detective quantum efficiency (DQE), was assessed under three beam qualities (28 kV, 50 kV (RQA3) and 70 kV (RQA5) using W/Al) all in accordance with the IEC standard. The detector features an in-pixel option for switching the full well capacity between two distinct modes, high full well (HFW) and low full well (LFW). Two structured CsI:Tl scintillators of different thickness (a thin one for high resolution and a thicker one for high light efficiency) were optically coupled to the sensor array to optimize the performance of the system for different medical applications. The electro-optical performance evaluation of the sensor results in relatively high read noise (∼360 e -), high full well capacity (∼1.5×10 6 e -) and wide dynamic range (∼73 dB) under HFW mode operation. When the LFW mode is used, the read noise is lower (∼165) at the expense of a reduced full well capacity (∼0.5×10 6 e -) and dynamic range (∼69 dB). The maximum DQE values at low frequencies (i.e. 0.5 lp/mm) are high for both HFW (0.69 for 28 kV, 0.71 for 50 kV and 0.75 for 70 kV) and LFW (0.69 for 28 kV and 0.7 for 50 kV) modes. The X-ray performance of the studied detector compares well to that of other mammography and general radiography systems, obtained under similar experimental conditions. This demonstrates the suitability of the detector for both mammography and general radiography, with the use of appropriate scintillators. The high DQE values obtained under low mammographic exposures (up to 0.65 for 22.3 μGy) matches the demand for high detectability in imaging of the dense breast. © 2012 Elsevier B.V.

Published

2012

12. Technical Note: Modification of the standard gain correction algorithm to compensate for the number of used reference flat frames in detector performance studies

Author

Anastasios C. Konstantinidis, Robert D. Speller, and Alessandro Olivo

Subjects

Pixel, Computer science, Fixed-pattern noise, Detector, Quantum noise, X-ray detector, Subtraction, Normalization (image processing), Image processing, General Medicine, Transfer function, Spectral line, Detective quantum efficiency, Optical transfer function, Image sensor, Algorithm

Abstract

PURPOSE: The x-ray performance evaluation of digital x-ray detectors is based on the calculation of the modulation transfer function (MTF), the noise power spectrum (NPS), and the resultant detective quantum efficiency (DQE). The flat images used for the extraction of the NPS should not contain any fixed pattern noise (FPN) to avoid contamination from nonstochastic processes. The "gold standard" method used for the reduction of the FPN (i.e., the different gain between pixels) in linear x-ray detectors is based on normalization with an average reference flat-field. However, the noise in the corrected image depends on the number of flat frames used for the average flat image. The aim of this study is to modify the standard gain correction algorithm to make it independent on the used reference flat frames. METHODS: Many publications suggest the use of 10-16 reference flat frames, while other studies use higher numbers (e.g., 48 frames) to reduce the propagated noise from the average flat image. This study quantifies experimentally the effect of the number of used reference flat frames on the NPS and DQE values and appropriately modifies the gain correction algorithm to compensate for this effect. RESULTS: It is shown that using the suggested gain correction algorithm a minimum number of reference flat frames (i.e., down to one frame) can be used to eliminate the FPN from the raw flat image. This saves computer memory and time during the x-ray performance evaluation. CONCLUSIONS: The authors show that the method presented in the study (a) leads to the maximum DQE value that one would have by using the conventional method and very large number of frames and (b) has been compared to an independent gain correction method based on the subtraction of flat-field images, leading to identical DQE values. They believe this provides robust validation of the proposed method.

Published

2011

13. Beam tracking phase tomography with laboratory sources

Author

Charlotte K. Hagen, Paul C. Diemoz, Anna Zamir, Alessandro Olivo, GK Kallon, Marco Endrizzi, and Fabio A. Vittoria

Subjects

Physics, Scattering, business.industry, Attenuation, Detector, Measure (physics), Phase (waves), 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Optics, Attenuation coefficient, 0103 physical sciences, Tomography, 010306 general physics, 0210 nano-technology, business, Instrumentation, Refractive index, Mathematical Physics

Abstract

An X-ray phase-contrast laboratory system is presented, based on the beam-tracking method. Beam-tracking relies on creating micro-beamlets of radiation by placing a structured mask before the sample, and analysing them by using a detector with sufficient resolution. The system is used in tomographic configuration to measure the three dimensional distribution of the linear attenuation coefficient, difference from unity of the real part of the refractive index, and of the local scattering power of specimens. The complementarity of the three signals is investigated, together with their potential use for material discrimination.

Published

2018

14. Design and realization of a coded-aperture based X-ray phase contrast imaging for homeland security applications

Author

Alessandro Olivo, Robert D. Speller, Peter R. T. Munro, and Konstantin Ignatyev

Subjects

Physics, Nuclear and High Energy Physics, business.industry, Detector, Phase-contrast imaging, Digital imaging, Phase (waves), Field (computer science), Optics, X-Ray Phase-Contrast Imaging, Systems design, Coded aperture, business, Instrumentation

Abstract

X-ray phase contrast imaging solves the basic problem of conventional X-ray imaging, i.e. low image contrast arising from small absorption differences. For years X-ray phase contrast imaging was thought to be restricted to synchrotron radiation facilities, but a new approach was recently developed at UCL which makes synchrotron-like phase effects achievable with conventional sources, by introducing two separate sets of appropriately designed coded-apertures at either side of the imaged object. Although most proposed applications of X-ray phase contrast imaging are focused on medical aspects, substantial advantages can be gained in other fields, including security inspections. In this case the system has to be based around higher X-ray energies, which has an impact on the system design. This paper describes such a design. A previously developed and experimentally validated simulation program was used to estimate the image contrast that can be expected from a range of details of interest in security inspections imaged under various conditions, including beam spectrum, detector characteristics, coded-aperture design, source-to-sample and sample-to-detector distances, etc.—while taking into account the interplay between these different parameters. The conditions providing maximum image contrast were chosen and used in the ultimate system design.

Published

2009

15. Deconvolution of x-ray phase contrast images as a way to retrieve phase information lost due to insufficient resolution

Author

Robert D. Speller and Alessandro Olivo

Subjects

Radiological and Ultrasound Technology, Phantoms, Imaging, business.industry, X-Rays, Detector, Phase-contrast imaging, Phase (waves), Image processing, Filter (signal processing), Imaging phantom, Radiographic Image Enhancement, Optics, Image Processing, Computer-Assisted, Image noise, Radiology, Nuclear Medicine and imaging, Deconvolution, Radiology, business, Algorithms, Mathematics

Abstract

When free-space propagation x-ray phase contrast imaging is implemented outside synchrotron radiation facilities, the combined effect of detector resolution and source size swamps the fine phase contrast fringes, often making them almost undetectable. In an attempt to mitigate this effect, a simple deconvolution procedure based on division in the Fourier space plus multiplication by an appropriate filter was applied to experimental x-ray phase contrast images of a simple geometric phantom. The filter parameter was varied in order to assess its impact on the level of retrieved phase signal. The deconvolved images were compared to simulated ones obtained under different resolution conditions, showing that this simple procedure provided signals equivalent to those that would be obtained with a detector with three times better resolution. By accepting an increase in the overall image noise, the method also appears to bring up secondary phase contrast fringes, which are not visible in the unprocessed signal.

Published

2009

16. Phase contrast imaging of breast tumours with synchrotron radiation

Author

L. Rigon, Robert D. Speller, Sarah Vinnicombe, K.C. Cheung, Alessandro Olivo, and M. Ibison

Subjects

Radiation, Materials science, medicine.diagnostic_test, business.industry, Image quality, Breast imaging, Detector, Resolution (electron density), Phase-contrast imaging, Synchrotron radiation, Breast Neoplasms, medicine, Humans, Radiographic Image Interpretation, Computer-Assisted, Mammography, Female, Nuclear medicine, business, Absorption (electromagnetic radiation), Synchrotrons, Biomedical engineering

Abstract

Even though the potential of phase contrast (PC) imaging has been demonstrated in a number of biological tissue samples, the availability of free-space propagation phase contrast images of real breast tumours is still limited. The aim of this study was to obtain phase contrast images of two different pathological breast specimens containing tumours of differing morphological type at two synchrotron radiation (SR) facilities, and to assess any qualitative improvements in the evaluation and characterisation of the masses through the use of phase contrast imaging. A second aim was to assess the effects of parameters such as detector resolution, beam energy and sample-to-detector distance on image quality using the same breast specimens, as to date these effects have been modelled and discussed only for geometric phantoms. At each synchrotron radiation facility a range of images was acquired with different detectors and by varying the above parameters. Images of the same samples were also acquired with the absorption-based approach to allow a direct comparison and estimation of the advantages specifically ascribable to the PC technique.

Published

2009

17. Modelling of a novel x-ray phase contrast imaging technique based on coded apertures

Author

Alessandro Olivo and Robert D. Speller

Subjects

Optics and Photonics, Diffusion (acoustics), Image quality, Computer science, Aperture, Phase contrast microscopy, Wasps, Synchrotron radiation, law.invention, Optics, law, Image Interpretation, Computer-Assisted, Animals, Computer Simulation, Radiology, Nuclear Medicine and imaging, Radiological and Ultrasound Technology, business.industry, X-Rays, Detector, Phase-contrast imaging, Bremsstrahlung, Filter (signal processing), Image Enhancement, X-Ray Phase-Contrast Imaging, Tomography, business, Algorithms, Synchrotrons

Abstract

X-ray phase contrast imaging is probably the most relevant among emerging x-ray imaging techniques, and it has the proven potential of revolutionizing the field of diagnostic radiology. Impressive images of a wide range of samples have been obtained, mostly at synchrotron radiation facilities. The necessity of relying on synchrotron radiation has prevented to a large extent a widespread diffusion of phase contrast imaging, thus precluding its transfer to clinical practice. A new technique, based on the use of coded apertures, was recently developed at UCL. This technique was demonstrated to provide intense phase contrast signals with conventional x-ray sources and detectors. Unlike other attempts at making phase contrast imaging feasible with conventional sources, the coded-aperture approach does not impose substantial limitations and/or filtering of the radiation beam, and it therefore allows, for the first time, exposures compatible with clinical practice. The technique has been thoroughly modelled, and this paper describes the technique in detail by going through the different steps of the modelling. All the main factors influencing image quality are discussed, alongside the viability of realizing a prototype suitable for clinical use. The model has been experimentally validated and a section of the paper shows the comparison between simulated and experimental results.

Published

2007

18. Polychromatic phase contrast imaging as a basic step towards a widespread application of the technique

Author

Robert D. Speller and Alessandro Olivo

Subjects

Physics, Point spread function, Nuclear and High Energy Physics, Image quality, business.industry, Detector, Phase-contrast imaging, Context (language use), Optics, Monochromatic color, Divergence (statistics), business, Instrumentation, Feature detection (computer vision)

Abstract

Phase contrast imaging (PCI) is probably the most exciting amongst emerging X-ray imaging techniques, as it has the potential to remove some of the main limitations of conventional radiology. As a consequence, significant effort is currently directed towards developing the technique for the first clinical implementations. In recent years, PCI has been widely experimented, but its use has been mainly restricted to synchrotron radiation (SR) facilities. Source-related limitations are in fact the most relevant in this context, and the fact that most phase techniques require monochromatic radiation makes these limitations even more severe. Amongst the different techniques, free-space propagation is the most suited to a polychromatic implementation. A detailed simulation, based on Fresnel/Kirchoff diffraction integrals, was devised to describe this imaging modality. This simulation accounts for source dimensions, beam spectrum and divergence and detector point spread function, and can thus be applied to any X-ray imaging system. In particular, by accepting these parameters as input, along with ones describing the sample, the model can be used to optimize the geometry of the set-up, i.e. to assess the source-to-sample and sample-to-detector distances that maximize feature detection. The simulation was validated experimentally by acquiring a range of images of different samples with a laboratory X-ray source. Good agreement was found between simulated and experimental data in all cases. In order to maximize the generality of the results, all acquisitions were carried out using a polychromatic source and an energy-resolving detector. This effectively allowed the recording of a range of monochromatic and polychromatic images in a single acquisition, as an assortment of the former can be created by integrating different parts of the acquired spectra. The most notable result obtained in this study is that in most practical cases polychromatic PCI can provide the same image quality as its monochromatic counterpart, which provides an important step in the wider application of phase contrast using conventional sources.

Published

2007

19. Laboratory implementation of edge illumination X-ray phase-contrast imaging with energy-resolved detectors

Author

Gloria Spandre, Pasquale Delogu, Fabio A. Vittoria, Paul C. Diemoz, Ronaldo Bellazzini, A. Vincenzi, Alessandro Olivo, L. De Ruvo, D. Basta, Marco Endrizzi, Massimo Marenzana, Charlotte K. Hagen, Alessandro Brez, and GK Kallon

Subjects

Physics, Geometrical optics, business.industry, Image quality, RETRIEVAL, X-ray imaging, Detector, Phase-contrast imaging, Author Keywords:edge illumination, phase contrast, energy-resolved detectors, geometrical optics KeyWords Plus:CODED-APERTURE, ABSORPTION, RESOLUTION, WAVE, Photon counting, Optics, X-Ray Phase-Contrast Imaging, Medical imaging, business, Image resolution

Abstract

Edge illumination (EI) X-ray phase-contrast imaging (XPCI) has potential for applications in different fields of research, including materials science, non-destructive industrial testing, small-animal imaging, and medical imaging. One of its main advantages is the compatibility with laboratory equipment, in particular with conventional non-microfocal sources, which makes its exploitation in normal research laboratories possible. In this work, we demonstrate that the signal in laboratory implementations of EI can be correctly described with the use of the simplified geometrical optics. Besides enabling the derivation of simple expressions for the sensitivity and spatial resolution of a given EI setup, this model also highlights the EI’s achromaticity. With the aim of improving image quality, as well as to take advantage of the fact that all energies in the spectrum contribute to the image contrast, we carried out EI acquisitions using a photon-counting energy-resolved detector. The obtained results demonstrate that this approach has great potential for future laboratory implementations of EI.

Published

2015

20. Experimental validation of a simple model capable of predicting the phase contrast imaging capabilities of any x-ray imaging system

Author

Robert D. Speller and Alessandro Olivo

Subjects

Point spread function, Diffraction, Image quality, Computer science, Phase contrast microscopy, Information Storage and Retrieval, Synchrotron radiation, Models, Biological, Sensitivity and Specificity, Spectral line, law.invention, Optics, X-Ray Diffraction, law, Image Interpretation, Computer-Assisted, Computer Simulation, Radiology, Nuclear Medicine and imaging, Divergence (statistics), Feature detection (computer vision), Radiological and Ultrasound Technology, Conventional radiology, business.industry, Detector, Phase-contrast imaging, X-ray, Reproducibility of Results, Image Enhancement, Refractometry, Tomography, business, Algorithms

Abstract

Phase contrast (PC) imaging is one of the most exciting emerging x-ray imaging techniques, with the potential of removing some of the main limitations of conventional radiology. After extensive experimentation carried out particularly at synchrotron radiation (SR) facilities, the scientific community agrees that it is now time to translate these ideas towards the first clinical implementations. In this framework, a complete model, based on Fresnel/Kirchoff diffraction integrals, was devised. This model accounts for source dimensions, beam spectrum and divergence and detector point spread function (PSF), and can thus be applied to any x-ray imaging system. In particular, by accepting in input the above parameters along with the ones describing the sample, the model can be used to optimize the geometry of the set-up, i.e. to assess the source-to-sample and sample-to-detector distances which maximize feature detection. The model was evaluated by acquiring a range of images of different samples with a laboratory source, and a good agreement was found between simulated and experimental data in all cases. In order to maximize the generality of the results, all acquisitions were carried out using a polychromatic source and an energy-resolving detector; in this way, a range of monochromatic images could be obtained as well as polychromatic images, which can be created by integrating different parts of the acquired spectra. One of the most notable results obtained is that in many practical cases polychromatic PC imaging can provide the same image quality as its monochromatic counterpart. This is an important step in the wider application of PC using conventional sources.

Published

2006

21. A multilayer edge-on single photon counting silicon microstrip detector for innovative imaging techniques in diagnostic radiology

Author

Francesco Montanari, R. Longo, Silvia Pani, Anna Bergamaschi, Alessandro Olivo, D. Dreossi, E. Vallazza, L. Rigon, Fulvia Arfelli, and Edoardo Castelli

Subjects

Physics, medicine.medical_specialty, Photon, Physics::Instrumentation and Detectors, Detector, Contrast resolution, Synchrotron radiation, Sample (graphics), Photon counting, Microstrip, medicine, Radiology, Instrumentation, Image resolution

Abstract

A three-layer detector prototype, obtained by stacking three edge-on single photon counting silicon microstrip detectors, has been developed and widely tested. This was done in the framework of the Synchrotron Radiation for Medical Physics/Frontier Radiology (SYRMEP/FRONTRAD) collaboration activities, whose aim is to improve the quality of mammographic examinations operating both on the source and on the detector side. The active surface of the device has been fully characterized making use of an edge-scanning technique and of a well-collimated laminar synchrotron radiation beam. The obtained data (interlayer distances, channel correspondence, etc.) have then been used to combine information coming from each detector layer, without causing any loss in spatial and contrast resolution of the device. Contrast and spatial resolution have also been separately evaluated for each detector layer. Moreover, imaging techniques (phase contrast, refraction, and scatter imaging), resulting in an increased visibility of low absorbing details, have been implemented, and their effectiveness has been tested on a biological sample. Finally, the possibility of simultaneously acquiring different kind of images with the different detector layers is discussed. This would result in maximizing the information extracted from the sample, while at the same time the high absorption efficiency of the detector device would allow a low dose delivery.

Published

2003

22. Signal-to-noise ratio evaluation in dual-energy radiography with synchrotron radiation

Author

S Fabbri, A. Tuffanelli, Silvia Pani, Mauro Gambaccini, Michele Marziani, Renata Longo, Alessandro Olivo, Angelo Taibi, Fabbri, S., Taibi, A., Longo, Renata, Olivo, A., Pani, Silvia, Tuffanelli, A., and Gambaccini, M.

Subjects

Quality Control, Materials science, Image quality, Radiography, Synchrotron radiation, syncrotron radiation, Sensitivity and Specificity, Imaging phantom, NO, law.invention, Radiography, Dual-Energy Scanned Projection, X ray imaging, DUAL-ENERGY MAMMOGRAPHY, IMAGE-QUALITY, DETECTOR, Optics, law, Radiology, Nuclear Medicine and imaging, Stochastic Processes, Radiological and Ultrasound Technology, Phantoms, Imaging, business.industry, Detector, Plate detector, equipment and supplies, Synchrotron, Equipment Failure Analysis, Radiographic Image Enhancement, Feasibility Studies, business, Algorithms, Synchrotrons, Mammography

Abstract

Dual-energy radiography is an effective technique that allows removal of contrast between pairs of materials in order to display details of interest on a uniform background. In mammographic images the detection of small nodules is often impeded by obscuring background 'clutter' resulting from the contrast between normal tissues (glandular and adipose) in their neighbourhood. We consider whether it could be possible to apply dual-energy radiography to the breast, which is hypothetically principally composed of three tissues, glandular, adipose and cancerous, in order to remove the contrast due to the distribution of normal tissues and, as a consequence, to enhance the intrinsic contrast of the pathology. The purpose of this work is to test the limitations of dual-energy radiography on a three-component phantom under optimum conditions of the source and detector. We use a synchrotron monochromatic beam, produced at the ELETTRA synchrotron facility (Trieste, Italy), and an imaging plate detector, in order to acquire two images at low and high energies of a phantom composed of polyethylene, plexiglas and water. For evaluation of the potential of this procedure we studied the signal-to-noise ratio (SNR) of polyethylene and water on a set of images obtained by applying the dual-energy procedure. We found that the SNR of polyethylene and water is around the detectability threshold (according to Rose's criteria) at the contrast cancellation angles. Finally we evaluated the air entrance dose required for this double exposure, resulting in 0.81 mGy for the low-energy image and 0.01 mGy for the high-energy image. To obtain the same image quality for a standard breast of 5.5 cm, mean glandular doses of 3.50 mGy and 0.03 mGy at 17 keV and at 34 keV, respectively, are required.

Published

2002

23. Simple and robust synchrotron and laboratory solutions for high-resolution multimodal X-ray phase-based imaging

Author

Ian K. Robinson, Christoph Rau, GK Kallon, Fabio A. Vittoria, Paul C. Diemoz, Marco Endrizzi, Charlotte K. Hagen, D. Basta, Anna Zamir, Ulrich Wagner, and Alessandro Olivo

Subjects

Physics, History, Pixel, business.industry, Detector, Phase (waves), Phase-contrast imaging, Synchrotron radiation, Synchrotron, Differential phase, Computer Science Applications, Education, law.invention, Optics, law, business, Absorption (electromagnetic radiation)

Abstract

Edge illumination X-ray phase contrast imaging techniques are capable of quantitative retrieval of differential phase, absorption and X-ray scattering. We have recently developed a series of approaches enabling high-resolution implementations, both using synchrotron radiation and laboratory-based set-ups. Three-dimensional reconstruction of absorption, phase and dark-field can be achieved with a simple rotation of the sample. All these approaches share a common trait which consists in the use of an absorber that shapes the radiation field, in order to make the phase modulations introduced by the sample detectable. This enables a well-defined and high-contrast structuring of the radiation field as well as an accurate modelling of the effects that are related to the simultaneous use of a wide range of energies. Moreover, it can also be adapted for use with detectors featuring large pixel sizes, which could be desirable when a high detection efficiency is important.

Published

2017

24. Laboratory-based edge-illumination phase-contrast imaging: Dark-field retrieval and high-resolution implementations

Author

Ian K. Robinson, T. P. Millard, Alessandro Olivo, Fabio A. Vittoria, Charlotte K. Hagen, Paul C. Diemoz, Marco Endrizzi, Ulrich Wagner, and Christoph Rau

Subjects

Physics, business.industry, Detector, Phase-contrast imaging, Phase (waves), Translation (geometry), Dark field microscopy, law.invention, Optics, Sampling (signal processing), Achromatic lens, law, Medical imaging, business

Abstract

Edge illumination is an X-ray phase-contrast imaging technique capable of quantitative retrieval of phase and amplitude images. The retrieval of the ultra-small-angle X-ray scattering was recently developed and implemented with the area-imaging counterpart of an edge-illumination system, sometimes referred to as coded-aperture setup. This is an incoherent and achromatic technique, well suited for translation of the potential of X-ray phase contrast imaging into efficient laboratory-scale setups. We report on recent advances of these developments along two main directions. One relates to the expansion of the technique with respect to the data analysis and corrections that are required when non-ideal optical elements are used and optimized sampling strategies. The second is directed towards high-resolution and high-energy implementations. A laboratory-based prototype for high-energy X-ray phase-contrast microscopy was built and its performance was modelled and experimentally characterized.

Published

2014

25. Optimization of sensitivity, dose and spatial resolution in edge illumination X-ray phase-contrast imaging

Author

Paul C. Diemoz, Fabio A. Vittoria, Alessandro Olivo, T. P. Millard, Charlotte K. Hagen, and Marco Endrizzi

Subjects

Engineering, Optics, business.industry, X-Ray Phase-Contrast Imaging, Detector, Range (statistics), Sensitivity (control systems), Photonics, Edge (geometry), business, Image resolution, Sample (graphics)

Abstract

Edge illumination (EI) X-ray phase-contrast imaging has great potential for applications in a wide range of research, industrial and clinical fields. The optimization of the EI experimental setup for a given application is therefore essential, in order to take full advantage of the capabilities of the technique. In this work, we analyze the dependence of the angular sensitivity, spatial resolution and dose delivered to the sample upon the various experimental parameters, and describe possible strategies to optimize them. The obtained results will be important for the design of future EI experimental setups, in particular enabling their tailoring to specific applications.

Published

2014

26. Low-dose x-ray phase contrast tomography: Experimental setup, image reconstruction and applications in biomedicine

Author

Charlotte K. Hagen, Rolf H. Jager, Anna Zamir, Marco Endrizzi, Paul C. Diemoz, Alessandro Olivo, and Fiona Kennedy

Subjects

Engineering, Optics, Tomographic reconstruction, business.industry, Detector, Medical imaging, X-ray, Phase-contrast imaging, Iterative reconstruction, Tomography, business, Biomedicine, Biomedical engineering

Abstract

An unmet demand for high resolution tomographic imaging modalities providing enhanced soft tissue contrast exists in a number of biomedical disciplines. X-ray phase contrast imaging (XPCi) methods can provide a solution: contrast is driven by phase (refraction) effects rather than attenuation effects, the formers being much larger than the latters for weakly attenuating materials and energies typically used for biomedical imaging. However, the majority of the existing XPCi methods suffer from drawbacks affecting their implementation outside specialized facilities such as synchrotrons and therefore their applicability to biomedical research. The Edge Illumination (EI) XPCi method has the potential to overcome or at least mitigate most of these drawbacks. Its major strengths are its simple setup, compatibility with commercially available x-ray tubes and potential for low-dose imaging. EI XPCi has recently been implemented as a tomographic modality, and it was demonstrated that the method can provide quantitatively accurate volumetric images acquired with low entrance doses. This paper explains the experimental requirements for tomographic EI XPCi, outlines the image reconstruction process and discusses potential applications in biomedicine. As an example, first experimental images of an atherosclerotic plaque specimen are presented.

Published

2014

27. Simultaneous implementation of low dose and high sensitivity capabilities in differential phase contrast and dark-field imaging with laboratory x-ray sources

Author

Marco Endrizzi, Fabio A. Vittoria, Alessandro Olivo, Charlotte K. Hagen, T. P. Millard, and Paul C. Diemoz

Subjects

Physics, Image formation, Photon, Optics, Aperture, business.industry, X-Ray Phase-Contrast Imaging, Physics::Medical Physics, Detector, Phase-contrast imaging, Sensitivity (control systems), business, Phase retrieval

Abstract

We present a development of the laboratory-based implementation of edge-illumination (EI) x-ray phase contrast imaging (XPCI) that simultaneously enables low-dose and high sensitivity. Lab-based EI-XPCI simplifies the set-up with respect to other methods, as it only requires two optical elements, the large pitch of which relaxes the alignment requirements. Albeit in the past it was erroneously assumed that this would reduce the sensitivity, we demonstrate quantitatively that this is not the case. We discuss a system where the pre-sample mask open fraction is smaller than 50%, and a large fraction of the created beamlets hits the apertures in the detector mask. This ensures that the majority of photons traversing the sample are detected i.e. used for image formation, optimizing dose delivery. We show that the sensitivity depends on the dimension of the part of each beamlet hitting the detector apertures, optimized in the system design. We also show that the aperture pitch does not influence the sensitivity. Compared to previous implementations, we only reduced the beamlet fraction hitting the absorbing septa on the detector mask, not the one falling inside the apertures: the same number of x-rays per second is thus detected, i.e. the dose is reduced, but not at the expense of exposure time. We also present an extension of our phase-retrieval algorithm enabling the extraction of ultra-small-angle scattering by means of only one additional frame, with all three frames acquired within dose limits imposed by e.g. clinical mammography, and easy adaptation to lab-based phase-contrast x-ray microscopy implementations.

Published

2014

28. Edge-illumination X-ray phase contrast imaging: matching the imaging method to the detector technology

Author

A. Brez, Paul C. Diemoz, Renata Longo, Diego Dreossi, R. Bellazzini, Pasquale Delogu, Marco Endrizzi, Luigi Rigon, Gloria Spandre, Alessandro Olivo, Fulvia Arfelli, Charlotte K. Hagen, L. De Ruvo, Massimo Marenzana, A. Vincenzi, Peter R. T. Munro, F. Lopez, Fabio A. Vittoria, M., Endrizzi, P. C., Diemoz, C. K., Hagen, F. A., Vittoria, P. R. T., Munro, Rigon, Luigi, D., Dreossi, Arfelli, Fulvia, F. C. M., Lopez, Longo, Renata, M., Marenzana, P., Delogu, A., Vincenzi, L., De Ruvo, G., Spandre, A., Brez, R., Bellazzini, and A., Olivo

Subjects

Detection of defect, Computer science, business.industry, Detector, Phase-contrast imaging, Phase (waves), Data processing methods, Detection of defects, Inspection with x-rays, X-ray radiography and digital radiography (DR), Optics, Simplicity (photography), X-Ray Phase-Contrast Imaging, Scalability, Inspection with x-ray, Sensitivity (control systems), Phase retrieval, business, Instrumentation, Mathematical Physics

Abstract

X-Ray Phase Contrast Imaging (XPCI) has been arguably the hottest topic in X-ray imaging research over the last two decades, due to the significant advantages it can bring to medicine, biology, material science and many other areas of application. Considerable progress has recently been achieved, in terms of the first in vivo implementations at synchrotrons (notably at Elettra in Trieste), and of new XPCI methods working with conventional sources. Among the latter, edge-illumination (EI) is possibly one of the most promising in terms of mainstream translation, due to set-up simplicity, scalability and flux efficiency compared to other approaches. EI is indeed the only method working with a completely incoherent source: however, it was recently demonstrated that neither the ability to perform quantitative phase retrieval, nor the method's phase sensitivity are affected by the source's incoherence. Here its implementation with different detector technologies is discussed.

Published

2014

29. X-ray phase-contrast imaging with polychromatic sources and the concept of effective energy

Author

Peter R. T. Munro and Alessandro Olivo

Subjects

Physics, business.industry, Detector, Phase (waves), Physics::Optics, Grating, Atomic and Molecular Physics, and Optics, Differential phase, Optics, X-Ray Phase-Contrast Imaging, Coded aperture, business, Phase retrieval, Absorption (electromagnetic radiation)

Abstract

Grating-based quantitative polychromatic x-ray phase imaging is currently a very active area of research. It has already been shown that, in such systems, the retrieved differential phase depends upon the spectral properties of the source, the gratings, the detector, and the sample. In this paper, we show that the retrieved sample absorption also depends upon the spectral properties of the gratings. Further, we compare the spectral dependence of both retrieved phase and absorption for the grating interferometer and coded aperture techniques. These results enable us to conclude that in both cases quantitative phase imaging systems cannot be described by an effective energy which is independent of the sample. This has important implications for applications where an absolute measure of phase is important and in tomography.

Published

2013

30. High-speed single photon counting read out electronics for a digital detection system for clinical synchrotron radiation mammography

Author

C. Venanzi, Silvia Pani, Renata Longo, Alessandro Olivo, D. Dreossi, Anna Bergamaschi, E. Vallazza, Luigi Rigon, Fulvia Arfelli, Edoardo Castelli, Bergamaschi, A, Arfelli, Fulvia, Dreossi, D, Longo, Renata, Olivo, A, Pani, S, Rigon, Luigi, Vallazza, E, Venanzi, C, and Castelli, Edoardo

Subjects

Physics, Nuclear and High Energy Physics, medicine.medical_specialty, Digital mammography, Pixel, medicine.diagnostic_test, business.industry, Breast imaging, Image quality, Detector, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Photon counting, Optics, Application-specific integrated circuit, medicine, Mammography, Medical physics, business, Instrumentation

Abstract

The SYRMEP beam line is currently in the upgrading phase for mammographic examinations on patients at Elettra in Trieste. At the same time, a digital detection system, suitable for in -vivo breast imaging, is under development; it consists of a silicon laminar detector array operating in single photon counting mode. The duration of a clinical examination should not exceed a few seconds. Fast read out electronics is therefore necessary with the aim of avoiding losses in image contrast in presence of high counting rates. A custom ASIC working with 100% efficiency for rates up to 100 kHz per pixel has been designed and tested, and other solutions based on commercially available ASICs are currently under test. Several detector prototypes have been assembled, and images of mammographic test objects have been acquired. Image quality, efficiency and contrast losses have been evaluated in all cases as a function of the counting rate.

Published

2004

31. X-ray performance evaluation of the dexela cmos aps x-ray detector using monochromatic synchrotron radiation in the mammographic energy range

Author

P. Liaparinos, Steve Naday, Spencer Gunn, Alessandro Olivo, Nicola Sodini, Anastasios C. Konstantinidis, Diego Dreossi, Magdalena B. Szafraniec, Luigi Rigon, Alan McArthur, Robert D. Speller, Giuliana Tromba, Konstantinidis, Anastasios C., Szafraniec, Magdalena B., Rigon, Luigi, Tromba, Giuliana, Dreossi, Diego, Sodini, Nicola, Liaparinos, Panagiotis F., Naday, Steve, Gunn, Spencer, Mcarthur, Alan, Speller, Robert D., and Olivo, Alessandro

Subjects

Physics, CMOS sensor, Nuclear and High Energy Physics, Physics::Instrumentation and Detectors, business.industry, synchrotron radiation, Monte Carlo method, Detector, Complementary metal-oxide-semiconductor (CMOS), X-ray detector, Synchrotron radiation, Scintillator, Detective quantum efficiency, Nuclear Energy and Engineering, Optical transfer function, digital mammography, Optoelectronics, image quality, Electrical and Electronic Engineering, business

Abstract

Digital detectors based on complementary metal-oxide-semiconductors (CMOS) active pixel sensor (APS) technology have been introduced recently in many scientific applications. This work is focused on the X-ray performance evaluation of a novel CMOS APS detector in low energy medical imaging applications using monochromatic synchrotron radiation (i.e., 17-35 keV), which also allows studying how the performance varies with energy. The CMOS sensor was coupled to a Thallium-activated structured cesium iodide (CsI:Tl) scintillator and the detector's X-ray performance evaluation was carried out in terms of sensitivity, presampling modulation transfer function (pMTF), normalized noise power spectrum (NNPS) and the resulting detective quantum efficiency (DQE). A Monte Carlo simulation was used to validate the experimentally measured low frequency DQE. Finally, the effect of iodine's secondary generated K-fluorescence X-rays on pMTF and DQE results was evaluated. Good agreement (within 5%) was observed between the Monte Carlo and experimentally measured low frequency DQE results. A CMOS APS detector was characterized for the first time over a wide range of low energies covering the mammographic spectra. The detector's performance is limited mainly by the detectability of the scintillator. Finally, we show that the current data could be used to calculate the detector's pMTF, NNPS and DQE for any mammographic spectral shape within the investigated energies.

Published

2013

32. Improved sensitivity at synchrotrons using edge illumination X-ray phase-contrast imaging

Author

Alberto Bravin, Alessandro Olivo, Paul C. Diemoz, Ian K. Robinson, Robert D. Speller, C. E. Zapata, Marco Endrizzi, Res Complex Harwell, Didcot OX11 0FA, Oxon, England, UCL, Dept Med Phys & Bioengn, London WC1E 6BT, England, European Synchrotron Radiation Facility (ESRF), London Ctr Nanotechnol, London WC1H 0AH, England, Diemoz, P, Endrizzi, M, Zapata, C, Bravin, A, Speller, R, Robinson, I, and Olivo, A

Subjects

medicine.medical_specialty, Image quality, Astrophysics::High Energy Astrophysical Phenomena, Data processing method, FIS/07 - FISICA APPLICATA (A BENI CULTURALI, AMBIENTALI, BIOLOGIA E MEDICINA), Synchrotron radiation, 01 natural sciences, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Optics, 0103 physical sciences, medicine, Medical physics, Sensitivity (control systems), Instrumentation, Mathematical Physics, 010302 applied physics, Physics, [PHYS]Physics [physics], business.industry, Computerized Tomography (CT) and Computed Radiography (CR), Detector, Bremsstrahlung, Industrial computed tomography, Image reconstruction in medical imaging, Refraction, X-Ray Phase-Contrast Imaging, X-ray radiography and digital radiography (DR), Data processing methods, business

Abstract

International audience; The application of the X-ray phase-contrast 'edge illumination' principle to the highly coherent beams available at synchrotron radiation facilities is presented here. We show that, in this configuration, the technique allows achieving unprecedented angular sensitivity, of the order of few nanoradians. The results are obtained at beamlines of two different synchrotron radiation facilities, using various experimental conditions. In particular, different detectors and X-ray energies (12 keV and 85 keV) were employed, proving the flexibility of the method and the broad range of conditions over which it can be applied. Furthermore, the quantitative separation of absorption and refraction information, and the application of the edge illumination principle in combination with computed tomography, are also demonstrated. Thanks to its extremely high phase sensitivity and its flexible applicability, this technique will both improve the image quality achievable with X-ray phase-contrast imaging and allow tackling areas of application which remain unexplored until now

Published

2013

33. Silicon detectors for digital radiography

Author

R. Rosei, M. Prest, A. Savoia, Giuliana Tromba, V. Bonvicini, A. Vacchi, Fulvia Arfelli, L. Dalla Palma, F. Tomasini, Alberto Bravin, Edoardo Castelli, Renata Longo, M. Di Michiel, Alessandro Olivo, M. Sessa, Guido Barbiellini, Giovanni Cantatore, P. Poropat, Arfelli, F, Barbiellini, G, Bonvicini, V, Bravin, A, Cantatore, G, Castelli, E, dalla Palma, L, di Michiel, M, Longo, R, Olivo, A, Poropat, P, Prest, M, Rosei, R, Savoia, A, Sessa, M, Tomasini, F, Tromba, G, Vacchi, A, Arfelli, Fulvia, Barbiellini, G., Bonvicini, V., Bravin, A., Cantatore, Giovanni, Castelli, Edoardo, dalla Palma, L., di Michiel, M., Longo, Renata, Olivo, A., Poropat, P., Prest, M., Rosei, R., Savoia, A., Sessa, M., Tomasini, F., Tromba, G., and Vacchi, A.

Subjects

Nuclear and High Energy Physics, medicine.medical_specialty, Digital mammography, Silicon, mammography, silicon strip detector, FIS/07 - FISICA APPLICATA (A BENI CULTURALI, AMBIENTALI, BIOLOGIA E MEDICINA), Synchrotron radiation, chemistry.chemical_element, Flat panel detector, Optics, SYRMEP, digital mammography, medicine, Medical physics, Instrumentation, synchrotron light, Digital radiography, Physics, Silicon detectors, digital radiography, X-ray, Pixel, business.industry, Detector, digital silicon detector, chemistry, Monochromatic color, business

Abstract

The SYRMEP Collaboration (SYnchrotron Radiation for MEdical Physics) is conducting a research project in digital mammography and plans to use a monochromatic X-ray beam provided by Elettra, the synchrotron radiation facility in operation in Trieste (Italy), in conjunction with a novel silicon pixel detector. A set of silicon strip detectors was arranged to form a vector of pixels. This prototype with a sensitive area of 24 mm2 (i.e. 2 × 48 pixels of 0.5 × 0.5 mm2) has been used to produce images with X-rays both from a 109Cd source and a standard radiological tube.

Published

1995

34. 'Edge illumination' in X-ray Phase Contrast Imaging

Author

Paul C. Diemoz, Peter R. T. Munro, Konstantin Ignatyev, Cesar E. Zapata, T. P. Millard, Alessandro Olivo, Charlotte K. Hagen, Robert D. Speller, and Magdalena B. Szafraniec

Subjects

Physics, Optics, Pixel, business.industry, X-Ray Phase-Contrast Imaging, Detector, Phase (waves), Image processing, Coded aperture, business, Phase retrieval, Sensitivity (electronics)

Abstract

In the late '90s, the concept of "edge illumination" was developed at ELETTRA in Italy as an alternative method to increase the phase sensitivity of an imaging system. The main idea was to be able to reproduce the fine angular selection of "analyzer" crystals without actually using a crystal, as this would allow employing the method with divergent and polychromatic (i.e. conventional) x-ray sources. It was observed that this could be achieved by illuminating only the edges of the detector pixels, and that the method's sensitivity could be progressively increased by illuminating smaller pixel fractions closer to its physical edge. A few years later the idea was adapted for use with a conventional source by means of two sets of x-ray masks ("coded aperture" masks), which enabled obtaining the same effect for each row (or column) of pixels of an area detector illuminated by a cone beam. This article reviews the method and presents recent examples of application.

Published

2012

35. Evaluation of a novel wafer-scale CMOS APS X-ray detector for use in mammography

Author

Mary Yip, Robert D. Speller, Thalis Anaxagoras, Anastasios C. Konstantinidis, Nigel M. Allinson, Alessandro Olivo, Kristina Bliznakova, Kevin Wells, and Yi Zheng

Subjects

Detective quantum efficiency, Physics, CMOS sensor, Pixel, Image quality, business.industry, Optical transfer function, Detector, X-ray detector, Computer vision, Artificial intelligence, business, Image resolution

Abstract

The most important factors that affect the image quality are contrast, spatial resolution and noise. These factors and their relationship are quantitatively described by the Contrast-to-Noise Ratio (CNR), Signal-to-Noise Ratio (SNR), Modulation Transfer Function (MTF), Noise Power Spectrum (NPS) and Detective Quantum Efficiency (DQE) parameters. The combination of SNR, MTF and NPS determines the DQE, which represents the ability to visualize object details of a certain size and contrast at a given dose. In this study the performance of a novel large area Complementary Metal-Oxide-Semiconductor (CMOS) Active Pixel Sensor (APS) X-ray detector, called DynAMITe (Dynamic range Adjustable for Medical Imaging Technology), was investigated and compared to other three digital mammography systems (namely a) Large Area Sensor (LAS), b) Hamamatsu C9732DK, and c) Anrad SMAM), in terms of physical characteristics and evaluation of the image quality. DynAMITe detector consists of two geometrically superimposed grids: a) 2560 × 2624 pixels at 50 μm pitch, named Sub-Pixels (SP camera) and b) 1280 × 1312 pixels at 100 μm pitch, named Pixels (P camera). The X-ray performance evaluation of DynAMITe SP detector demonstrated high DQE results (0.58 to 0.64 at 0.5 lp/mm). Image simulation based on the X-ray performance of the detectors was used to predict and compare the mammographic image quality using ideal software phantoms: a) one representing two three dimensional (3-D) breasts of various thickness and glandularity to estimate the CNR between simulated microcalcifications and the background, and b) the CDMAM 3.4 test tool for a contrast-detail analysis of small thickness and low contrast objects. The results show that DynAMITe SP detector results in high CNR and contrast-detail performance. © 2012 IEEE.

Published

2012

36. X-ray Phase Contrast Imaging with coded apertures for next generation baggage scanning systems

Author

Robert D. Speller, Peter R. T. Munro, Konstantin Ignatyev, and Alessandro Olivo

Subjects

High contrast, business.industry, Computer science, Test data generation, Visibility (geometry), Detector, Phase-contrast imaging, Field (computer science), Optics, X-Ray Phase-Contrast Imaging, X ray refraction, Computer vision, Artificial intelligence, business

Abstract

X-ray Phase Contrast Imaging (XPCi) is a novel method which was proven to enhance the visibility of all details compared to conventional, absorption-based x-ray imaging. Here we propose the application of such a methodology to baggage scanners, a field in which XPCi had not been tested before, and we demonstrate improved detail visibility on a range of samples representing difficult cases in security inspections. A working prototype system has been built, and the results obtained by imaging several test objects mimicking possible components of threat objects. Test objects were also imaged with additional absorbing layers, to show that the method can be used with cluttered environment of baggage in realistic conditions. In all cases, all details were clearly detected with high contrast and high signal-to-noise ratio. Our laboratory-based system uses a conventional X-ray source and a commercially available X-ray detector for data generation. The system can be scaled up by using larger coded apertures.

Published

2010

37. First X-ray phase contrast images obtained with conventional X-ray source under exposure conditions compatible with real-world applications

Author

Alessandro Olivo, Robert D. Speller, Peter R. T. Munro, and Konstantin Ignatyev

Subjects

Physics, Optics, Pixel, business.industry, Detector, Medical imaging, Phase-contrast imaging, Sensitivity (control systems), Absorption (electromagnetic radiation), business, Collimated light, Coherence (physics)

Abstract

X-ray phase contrast imaging (XPCi) is a novel technique that allows detecting small variations in structure and composition of objects that would be undetectable when employing conventional X-ray absorption imaging. We have recently proposed a modification of the technique, called coded-aperture XPCi, which allows recording phase contrast images using conventional laboratory X-ray sources. Unlike other methods based on conventional sources, the coded-aperture approach does not require any collimation or aperturing of the emitted beam to increase the source coherence, which would result in suppressing the source output thus leading to excessively long exposure times. This opens up the possibilities of using XPCi in various applications from medical imaging to security applications. Here we will present the results obtained with the laboratory coded-aperture XPCi setup that show drastic improvement in sensitivity compared to conventional absorption imaging.

Published

2010

38. A novel x-ray imaging technique based on coded apertures making phase contrast imaging feasible with conventional sources

Author

Alessandro Olivo and Robert D. Speller

Subjects

Physics, Interferometry, Optics, Pixel, business.industry, Detector, Phase-contrast imaging, Synchrotron radiation, Coded aperture, Photonics, Grating, business

Abstract

X-ray phase contrast imaging (XPCi) overcomes the main limitation of absorption-based x-ray imaging i.e. poor image contrast due to small absorption differences, and was proven capable to produce high contrast images of objects invisible to conventional methods. The problem so far was that XPCi was only feasible with synchrotron radiation sources (SR), which prevented any application of the technique outside the research domain. XPCi images can be produced outside SR only by means of microfocal sources, which result in dramatically increased exposure times. XPCi images with conventional sources were also obtained by means of a grating (or shearing) interferometer, but this still requires the source to be spatially coherent unless an absorption grid is placed in close contact with the source itself. By doing this, the output of the source is dramatically reduced, resulting in exposure times only marginally improved over those obtained with microfocal sources. We have developed a new technique, based on coded apertures, which overcomes all the above limitations and allows intense XPCi signals to be achieved with source sizes fully compatible with current state-of-the-art X-ray sources, without requiring any filtering/focusing/grating element to be placed in contact with the source thus suppressing its output. A pre-sample coded aperture system with a fill factor of 0.5 is used instead, which means that the increase in exposure time over conventional methods is only of a factor of 2. The technique was fully modelled and a proof-of-concept experiment carried out. The obtained results are in full agreement with the model, and demonstrate that image contrast increases comparable to those obtained with SR can be achieved with a focal spot of 100 micron. A larger scale imaging prototype aimed at homeland security is currently under development, and future applications aimed at medical, scientific and industrial imaging are currently being studied.

Published

2008

39. Edge on silicon microstrip detectors for medical imaging

Author

Fulvia Arfelli, Alessandro Olivo, Edoardo Castelli, Anna Bergamaschi, Silvia Pani, Luigi Rigon, Renata Longo, D. Dreossi, Bergamaschi, A, Arfelli, Fulvia, Dreossi, D, Longo, Renata, Olivo, A, Pani, S, Rigon, Luigi, and Castelli, Edoardo

Subjects

Physics, Nuclear and High Energy Physics, Digital mammography, Physics::Instrumentation and Detectors, business.industry, Physics::Medical Physics, Detector, Synchrotron radiation, Synchrotron light source, STRIPS, Refraction, law.invention, Optics, law, Medical imaging, business, Instrumentation, Digital radiography

Abstract

Silicon microstrip detectors in the edge on geometry, i.e. oriented with the strips parallel to the incoming beam, allow a high absorption efficiency for X-rays in the 10–100 keV energy range. In medical imaging, this results in a significant reduction of the dose given to the patient with respect to conventional screen-film systems. This geometrical configuration was first proposed in the early 90s and since then it has been applied to several medical imaging projects. In this short review, an overview of some medical imaging applications using edge on detectors will be presented, focusing the attention on the main characteristics of the detection systems. The studies performed in Trieste in order to optimize such detectors for digital mammography with synchrotron radiation will be described in detail. In particular, novel imaging techniques (phase contrast, refraction and scatter imaging, computed tomography) implemented and tested at the Trieste synchrotron light source will be shortly discussed.

Published

2005

40. Effect of spatial coherence on application of in-line phase contrast imaging to synchrotron radiation mammography

Author

Silvia Pani, Edoardo Castelli, Anna Bergamaschi, Luigi Rigon, Alessandro Olivo, T Rokvic, Tiqiao Xiao, Renata Longo, D. Dreossi, C. Venanzi, Xiao, Tq, Bergamaschi, A, Dreossi, D, Longo, Renata, Olivo, A, Pani, S, Rigon, Luigi, Rokvic, T, Venanzi, C, and Castelli, Edoardo

Subjects

Physics, Nuclear and High Energy Physics, Pixel, Physics::Instrumentation and Detectors, Image quality, business.industry, Detector, Phase-contrast imaging, Edge enhancement, Photon energy, 01 natural sciences, 030218 nuclear medicine & medical imaging, 010309 optics, 03 medical and health sciences, 0302 clinical medicine, Optics, 0103 physical sciences, business, Instrumentation, Image resolution, Coherence (physics)

Abstract

Effect of spatial coherence on the application of in-line phase contrast imaging (IL-PCI) to synchrotron radiation (SR) mammography is investigated experimentally at SYRMEP/ELETTRA. Factors that are related to spatial coherence and IL-PCI image quality, which include vertical and horizontal beam, photon energy, slit width, sample–detector distance and detector resolution, are analyzed. The experimental results demonstrate that better IL-PCI image quality could be achieved in the vertical beam. As for the slit width, the spatial coherence for horizontal beam remains almost the same until the slit width is gradually closed to 5 mm. For mammography applications of IL-PCI, slit width of 100 mm could be employed and high-enough image quality can still be obtained. Lower photon energy results in better coherence and correspondingly better IL-PCI image quality. By compromising the dose and image quality, photon energy of ∼19 keV is recommended for SR mammography. To preserve the edge enhancement resulting from good coherence of SR, an appropriate sample–detector distance and a practical detector should be selected. The optimum sample–detector distance highly depends on detector resolution. For high-resolution film, the best IL-PCI imaging quality is obtained at a closer sample–detector distance. For an X-ray CCD with pixel size of 14 μm, about 1.5 m is needed to achieve optimum image quality. The large pixel size of the detector will deteriorate the edge-enhancing efficiency and results in lower IL-PCI imaging quality. In practice, the spatial resolution and sensitivity of the detectors should be compromised.

Published

2005

41. A digital detector for breast computed tomography at the SYRMEP beamline

Author

Silvia Pani, F. Bruni, Alessandro Olivo, Anna Bergamaschi, Renata Longo, D. Dreossi, C. Venanzi, Edoardo Castelli, Venanzi, C, Bergamaschi, A, Bruni, F, Dreossi, D, Longo, Renata, Olivo, A, Pani, S, and Castelli, Edoardo

Subjects

Physics, Nuclear and High Energy Physics, Tomographic reconstruction, Digital mammography, Physics::Instrumentation and Detectors, business.industry, Physics::Medical Physics, Contrast resolution, Detector, Synchrotron radiation, Synchrotron light source, Photon counting, Optics, Beamline, business, Instrumentation

Abstract

A silicon strip detector in edge on configuration with a single photon counting read-out electronics was developed for the MATISSE (MAmmographic and Tomographic Imaging with Silicon detectors and Synchrotron radiation at Elettra) project. MATISSE is an experiment aiming at a pre-clinical phase of breast computed tomography examinations at the SYRMEP (SYnchrotron Radiation for MEdical Physics) beamline at the Elettra synchrotron light source in Trieste (Italy). A monochromatic beam in the energy range 8-35 keV is available at SYRMEP. The MATISSE detector is side illuminated, thus allowing direct conversion of X-rays with a high efficiency. The read-out electronics operates in single photon counting mode, maximizing the contrast resolution of the images. Thanks to the characteristics of the radiation spectrum and to the high efficiency of the detector, the dose delivered in a tomographic examination results comparable to the one delivered in planar conventional mammography. Detector prototypes have been assembled and tested with promising results that will be presented in this contribution.

Published

2005

42. A digital detection system for Synchrotron Radiation breast Tomography

Author

Alessandro Olivo, R. Longo, Edoardo Castelli, Silvia Pani, D. Dreossi, C. Venanzi, Anna Bergamaschi, Venanzi, C, Bergamaschi, A, Dreossi, D, Longo, Renata, Olivo, A, Pani, E, and Castelli, Edoardo

Subjects

Physics, Optics, Tomographic reconstruction, Beamline, business.industry, Detector, Synchrotron radiation, Monochromatic color, Tomography, Radiation, business, Photon counting

Abstract

A silicon strip detector in edge-on configuration with a single photon counting (SPC) read-out electronics was developed for the MATISSE (MAmmographic and Tomographic Imaging with Silicon detectors and Synchrotron radiation [SR] at Elettra) project. MATISSE is an experiment of the interdisciplinary sector of the INFN (Istituto Nazionale di Fisica Nucleare), aiming at a preclinical phase of tomomammographic examinations at SYRMEP (Synchrotron Radiation for Medical Physics) beamline of Elettra, the Trieste SR facility. With a high intensity SR source it is possible to obtain practically monochromatic laminar beams, in the energy range 8-35 keV. The MATISSE detector is side illuminated, thus allowing direct, high efficiency, conversion of X-rays. The read out electronics operates in SPC mode, maximizing the signal-to-noise ratio of the images. Thanks to the characteristics of the radiation source and to the high efficiency of the detector, the dose delivered in a tomographic examination results comparable to the one delivered in planar conventional mammography. Detector prototypes have been assembled and tested with promising results. New tests and first tomographic images of phantoms and 'in vitro' samples have been planned in the next months at the SYRMEP beamline.

Published

2004

43. Data acquisition, processing and control for the SYRMEP/FRONTRAD experiment

Author

Diego Pontoni, Luigi Rigon, M Fabrizioli, Edoardo Castelli, Alessandro Olivo, Alberto Bravin, A. Vacchi, E. Vallazza, Alexander Rashevsky, R. Longo, Fulvia Arfelli, M. Prest, P. Poropat, Giovanni Cantatore, Silvia Pani, V. Bonvicini, Giuliana Tromba, Arfelli, F, Bonvicini, V, Bravin, A, Cantatore, G, Castelli, E, Fabrizioli, M, Longo, R, Olivo, A, Pani, S, Pontoni, D, Poropat, P, Prest, M, Rashevsky, A, Rigon, L, Tromba, G, Vacchi, A, and Vallazza, E

Subjects

Data acquisition, processing, imaging, Computer science, business.industry, Detector, Process (computing), FIS/07 - FISICA APPLICATA (A BENI CULTURALI, AMBIENTALI, BIOLOGIA E MEDICINA), Multiprocessing, Synchrotron light source, Data acquisition, Stack (abstract data type), Ionization chamber, business, Computer hardware, Computer Automated Measurement and Control

Abstract

The SYRMEP/FRONTRAD experiment is performing a R&D program in order to assess the performances of a scanning X-ray detector operating at the ELETTRA Synchrotron light source, in an energy range optimized for mammographic imaging. The detector itself consists of a stack of silicon detectors positioned edge-on with respect to the X-ray beam direction. The data acquisition system must perform several tasks: from the control of the motors during the scanning procedure, to the collection of the data that are recorded on CAMAC modules and refer to the slots of the image while it is forming. The system has to process the data during the scan and to store them on a local disk. In addition, the environmental conditions (global dose measured by an ionization chamber, temperature, dark current of the detector and status of the electronics power supplies) have to be monitored and the proper action taken. We have implemented a multiprocessing system using TCP/IP and RPC to manage the tasks. The overall control is done by a GUI built using the Tcl/Tk package.

Published

2002

44. Virtual edge illumination and one dimensional beam tracking for absorption, refraction, and scattering retrieval

Author

Alessandro Olivo, Ian K. Robinson, Fabio A. Vittoria, Ulrich Wagner, Marco Endrizzi, Christoph Rau, and Paul C. Diemoz

Subjects

Physics, Optics, Physics and Astronomy (miscellaneous), Image quality, Scattering, business.industry, Detector, business, Absorption (electromagnetic radiation), Refraction, Signal, Beam (structure), Interpolation

Abstract

We propose two different approaches to retrieve x-ray absorption, refraction, and scattering signals using a one dimensional scan and a high resolution detector. The first method can be easily implemented in existing procedures developed for edge illumination to retrieve absorption and refraction signals, giving comparable image quality while reducing exposure time and delivered dose. The second method tracks the variations of the beam intensity profile on the detector through a multi-Gaussian interpolation, allowing the additional retrieval of the scattering signal.

Published

2014

45. Experimental evaluation of a simple algorithm to enhance the spatial resolution inscanned radiographic systems

Author

Fulvia Arfelli, Edoardo Castelli, Alessandro Olivo, Renata Longo, R. H. Menk, P. Poropat, Giovanni Cantatore, E. Vallazza, Giuliana Tromba, Silvia Pani, Luigi Rigon, M. Prest, Olivo, A, Rigon, Luigi, Arfelli, Fulvia, Cantatore, Giovanni, Longo, Renata, Menk, Rh, Pani, S, Prest, M, Poropat, P, Tromba, G, Vallazza, E, and Castelli, Edoardo

Subjects

Point spread function, medicine.medical_specialty, Digital mammography, Computer science, Image quality, Synchrotron radiation, Image processing, Breast Neoplasms, Iterative reconstruction, Radiation, Convolution, Breast cancer, SYRMEP/FRONTRAD, silicon pixel detector, deconvolution algorithm, medicine, Image Processing, Computer-Assisted, Mammography, Humans, Medical physics, Computer vision, Image sensor, Radiometry, Image resolution, Models, Statistical, medicine.diagnostic_test, Pixel, business.industry, Contrast resolution, Detector, General Medicine, medicine.disease, Real image, Deconvolution, Artificial intelligence, business, Sub-pixel resolution, Algorithms, Pixel detector

Abstract

In order to ensure an early diagnosis of breast cancer, an imaging system must fulfil extremely stringent requirements in terms of dynamic range, contrast resolution and spatial resolution. Furthermore, in order to reduce the dose delivered to the patient, a high efficiency of the detector device should be provided. In this paper the SYRMEP/FRONTRAD (SYnchrotron Radiation for MEdical Physics/FRONTier RADiology) mammography project, based on synchroton radiation and a novel solid state pixel detector, is briefly described. Particular relevance is given to the fact that the radiographic image is obtained by means of a scanning technique, which allows the possibility of utilizing a scanning step smaller than the pixel size. With this procedure, a convolution between the real image and the detector point spread function (PSF) is actually acquired: by carefully measuring the detector PSF, it is possible to apply a post-processing procedure (filtered deconvolution), which reconstructs images with enhanced spatial resolution. The image acquisition modality and the deconvolution algorithm are herein described, and some test object images, with spatial resolution enhanced by means of the filtered deconvolution procedure, are presented. As discussed in detail in this paper, this procedure allows us to obtain a spatial resolution determined by the scanning step, rather than by the pixel size.

Published

2000

46. Preliminary results with a three-layer linear array silicon pixel detector

Author

Fulvia Arfelli, Edoardo Castelli, Silvia Pani, Alberto Bravin, E. Vallazza, Ludovico Dalla Palma, Andrea Vacchi, Alexander Rashevsky, Giovanni Cantatore, Renata Longo, Luigi Rigon, V. Bonvicini, Alessandro Olivo, M. Prest, Giuliana Tromba, and P. Poropat

Subjects

Physics, Optics, Tilt (optics), Pixel, Stack (abstract data type), business.industry, Detector, Synchrotron radiation, Monochromatic color, business, Image resolution, Photon counting

Abstract

A linear array silicon pixel detector has been developed to perform digital radiology with synchrotron radiation: in this communication we present the first results obtained using a three layer prototype at the Elettra Synchrotron Radiation Facility (Trieste, Italy). High efficiency (about 85% at 20 keV) is achieved by means of an Si strip detector irradiated in an 'edge-on' geometry: the pixel dimensions are 200 X 300 micrometer2. To obtain a sensitive area of about 50 X 1 mm2 stack of three layers has been assembled. Images are obtained by means of scanning techniques and their spatial resolution is determined by the scanning step. Detectors are read-out by dedicated, low noise VLSI CMOS chips in single photon counting mode. The distance between each detector layer has been measured to be 115 plus or minus 10 micrometer and the layers are parallel within a maximum tilt angle of 0.08 degrees. Cross-talk effects were found to be always smaller than 2% of the counts of the neighboring layers. The MTF in the scan direction has been evaluated. The acquisition time needed to acquire an image of a mammographic test object is about 6 minutes. The mean glandular dose is about 30% of the dose delivered at the conventional mammographic unit for the same test object while the detail visibility is comparable. These preliminary results indicate that a large area linear array silicon pixel detector can be developed: using this detector and a monochromatic synchrotron radiation beam the delivered mean glandular dose is significantly reduced when compared to conventional mammographic examinations.© (1999) COPYRIGHT SPIE--The International Society for Optical Engineering. Downloading of the abstract is permitted for personal use only.

Published

1999

47. Improvements in the field of radiological imaging at the SYRMEP beamline

Author

Alberto Bravin, E. Vallazza, Fulvia Arfelli, Giuliana Tromba, Silvia Pani, P. Poropat, Edoardo Castelli, Andrea Vacchi, M. Prest, Alessandro Olivo, Ralf Hendrik Menk, Renata Longo, V. Bonvicini, Alexander Rashevsky, Giovanni Cantatore, Ludovico Dalla Palma, Luigi Rigon, Arfelli, F, Bonvicini, V, Bravin, A, Cantatore, G, Castelli, E, Dalla Palma, L, Longo, R, Menk, R, Olivo, A, Pani, S, Poropat, P, Prest, M, Rashevsky, A, Rigon, L, Tromba, G, Vacchi, A, and Vallazza, E

Subjects

Engineering, Digital mammography, business.industry, Contrast resolution, Detector, Digital imaging, FIS/07 - FISICA APPLICATA (A BENI CULTURALI, AMBIENTALI, BIOLOGIA E MEDICINA), radiology, synchrotron, Digital image, Optics, Beamline, business, Image resolution, Digital radiography

Abstract

One major goal of modern radiology is the improvement of image quality and subsequently the development of sophisticated radiographic methods which are capable of detecting low contrast and small size details in organic samples in particular in mammography where the requirements on contrast resolution and spatial resolution are extremely high. Significant improvements in image quality have been achieved by the SYRMEP (SYnchrotron Radiation for MEdical Physics) collaboration which has designed and built a beamline devoted to medical physics at the synchrotron radiation facility ELETTRA in Trieste (Italy). The detection system developed for digital mammography consists of a silicon pixel detector with a pixel size of 200 X 300 micrometers 2 used in the `edge on' configuration in order to achieve a high conversion efficiency. The detector is equipped with a low noise VLSI amplifier chain; at present. Recently, a multilayer detector prototype has been implemented, consisting of a stack of three single silicon strip layers. This set-up provides a larger sensitive area and subsequently a reduction of the exposure time. Digital images of mammographic phantoms and of in vitro full breast tissue samples show a higher contrast resolution and lower absorbed dose when compared to conventional mammographic images. Besides, further promising studies have been initiated developing novel imaging methods based on the phase effects evidenced by the high degree of coherence of the SR source. At the SYRMEP beamline several experiments have been carried out in order to exploit the potentials of two different techniques, Phase Contrast and Diffraction Enhanced Imaging, respectively. Images showing better detail visibility and enhanced contrast were produced with dose lower or comparable to the conventional one.

Published

1999

48. At the frontiers of digital mammography: SYRMEP

Author

Silvia Pani, Renata Longo, L. Dalla Palma, Edoardo Castelli, Alessandro Olivo, Alberto Bravin, Giuliana Tromba, E. Vallazza, P. Poropat, Alexander Rashevsky, V. Bonvicini, Diego Pontoni, Giovanni Cantatore, M. Prest, Fulvia Arfelli, A. Vacchi, M. Di Michiel, Arfelli, F, Bonvicini, V, Bravin, A, Cantatore, G, Castelli, E, Dalla Palma, L, Di Michiel, M, Longo, R, Olivo, A, Pani, S, Pontoni, D, Poropat, P, Prest, M, Rashevsky, A, Tromba, G, Vacchi, A, Vallazza, E, Arfelli, Fulvia, V., Bonvicini, A., Bravin, Cantatore, Giovanni, Castelli, Edoardo, L., DALLA PALMA, M., DI MICHIEL, Longo, Renata, A., Olivo, S., Pani, D., Pontoni, P., Poropat, M., Prest, A., Rashevsky, G., Tromba, A., Vacchi, and E., Vallazza

Subjects

Nuclear and High Energy Physics, medicine.medical_specialty, single photon counting, Photon, Digital mammography, Physics::Instrumentation and Detectors, mammography, Physics::Medical Physics, FIS/07 - FISICA APPLICATA (A BENI CULTURALI, AMBIENTALI, BIOLOGIA E MEDICINA), Synchrotron radiation, law.invention, X-ray, Optics, SYRMEP, law, digital mammography, medicine, Mammography, Medical physics, Instrumentation, silicon detector, synchrotron light, Physics, medicine.diagnostic_test, business.industry, Detector, Synchrotron, Photon counting, Beamline, business

Abstract

The SYRMEP (SYnchrotron Radiation for MEdical Physics) collaboration is presently taking data at a beamline at the synchrotron ELETTRA in Trieste to study the performances of a digital silicon pixel imaging system for mammography. Images are obtained with a scanning technique in the energy range 15–30 keV. The readout electronics operates in a single photon counting mode with a photon rate of about 10 6 /( mm 2 s ) , which is still 4 times lower than the maximum rate reachable with the present beamline configuration. Two different detector layouts have been designed, the first one consisting of a single-layer silicon microstrip detector positioned edge-on with respect to the beam, and the second innovative one represented by a matrix of these detectors stacked to cover the full beam dimension (100×4 mm 2 ) . We present here the results obtained with a single-layer detector and a double-layer detector (both 5 cm wide) with mammographic phantoms and human breast tissue.

Published

1998

49. SYRMEP front-end and read-out electronics

Author

Alberto Bravin, E. Vallazza, Alexander Rashevsky, P. Cristaudo, Giuliana Tromba, Silvia Pani, Giovanni Cantatore, Renata Longo, P. Poropat, F. Tomasini, M. Di Michiel, M. Prest, Diego Pontoni, A. Vacchi, Fulvia Arfelli, Edoardo Castelli, V. Bonvicini, Alessandro Olivo, Arfelli, F, Bonvicini, V, Bravin, A, Cantatore, G, Castelli, E, Cristaudo, P, Di Michiel, M, Longo, R, Olivo, A, Pani, S, Pontoni, D, Poropat, P, Prest, M, Rashevsky, A, Tomasini, F, Tromba, G, Vacchi, A, Vallazza, E, Arfelli, Fulvia, Cantatore, Giovanni, Castelli, Edoardo, DI MICHIEL, M, Longo, Renata, and Vallazza, E.

Subjects

Physics, Nuclear and High Energy Physics, monochromatic X-ray, Digital mammography, Silicon detector, business.industry, Detector, Electrical engineering, FIS/07 - FISICA APPLICATA (A BENI CULTURALI, AMBIENTALI, BIOLOGIA E MEDICINA), Modular design, Front and back ends, SYRMEP, digital mammography, Electronic, scanning image, Electronics, business, Instrumentation, Electronic circuit, Voltage, Computer Automated Measurement and Control

Abstract

The SYRMEP approach to digital mammography implies the use of a monochromatic X-ray beam from a synchrotron source and a slot of superimposed silicon microstrip detectors as a scanning image receptor. The microstrips are read by 32-channel chips mounted on 7-layer hybrid circuits which receive control signals and operating voltages from a MASTER-SLAVE configuration of cards. The MASTER card is driven by the CIRM, a dedicated CAMAC module whose timing function can be easily excluded to obtain data-storage-only units connected to different MASTERs: this second-level modular expansion capability fully achieves the tasks of an electronics system able to follow the SYRMEP detector growth till the final size of seven thousands of channels.

Published

1998

50. An 'edge-on' silicon strip detector for X-ray imaging

Author

Alberto Bravin, Silvia Pani, R. Longo, Edoardo Castelli, P. Poropat, Alexander Rashevsky, Diego Pontoni, G. Barbiellini, N. Zampa, M. Prest, Fulvia Arfelli, Giovanni Cantatore, M. Di Michiel, Alessandro Olivo, Giuliana Tromba, A. Vacchi, V. Bonvicini, Arfelli, F, Barbiellini, G, Bonvicini, V, Bravin, A, Cantatore, G, Castelli, E, Di Michiel, M, Longo, R, Olivo, A, Pani, S, Pontoni, D, Poropat, P, Prest, M, Rashevsky, A, Tromba, G, Vacchi, A, Zampa, N, Arfelli, Fulvia, Cantatore, Giovanni, Castelli, Edoardo, DI MICHIEL, M, Longo, Renata, and Zampa, N.

Subjects

Nuclear and High Energy Physics, Silicon, Physics::Instrumentation and Detectors, X-ray detector, FIS/07 - FISICA APPLICATA (A BENI CULTURALI, AMBIENTALI, BIOLOGIA E MEDICINA), chemistry.chemical_element, Particle detector, law.invention, SYRMEP, law, Nuclear electronics, digital mammography, readout ASIC, Electrical and Electronic Engineering, silicon detector, Capacitive coupling, Physics, business.industry, Detector, Biasing, silicon strip detector, X-ray imaging, Capacitor, Nuclear Energy and Engineering, chemistry, Optoelectronics, business

Abstract

A silicon strip detector for the SYRMEP (SYncrotron Radiation for MEdical Physics) experiment has been designed and realised. The main features of this detector are AC-coupling through integrated coupling capacitors, DC biasing by means of a gated punch-through structure, bulk contact on the junction side through a forward-biased p/sup +/ implant and integrated fan-in on active silicon. Results of laboratory tests of the detector parameters, allowing a thorough evaluation of the technological solutions employed, are presented. The functionality of the detectors and the charge collection linearity have been tested with different /spl gamma/ sources, using a hybrid, low-noise front-end electronics.

Published

1997