Silicon detectors for combined MR–PET and MR–SPECT imaging

Studen, Andrej; Brzezinski, Karol; Chesi, E.; Cindro, V.; Clinthorne, N.H.; Cochran, Eric W.; Grosicar, Borut; Grkovski, Milan; Honscheid, K.; Kagan, H.; Lacasta, C.; Llosá, G.; Mikuž, M.; Staňková, Věra; Weilhammer, P.; Žontar, D.

doi:10.1016/j.nima.2012.08.040

Cited by 3 publications

(1 citation statement)

References 8 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the approach investigated by our group [17][18][19], high resistivity silicon sensors segmented to individual pads were chosen as the detector material for the insert, offering excellent spatial [20] and energy resolution [21]. Silicon-based detectors should be insensitive to operation in a magnetic field [22], enabling the employment of PET inserts for MRI [23] and, due to their segmentation, are not expected to be susceptible to mis-localization of annihilation photons (depth-ofinteraction (DOI) effect).…”

Section: Introductionmentioning

confidence: 99%

Evaluation of a high resolution silicon PET insert module

Grkovski

Brzezinski²,

Cindro

et al. 2015

Nuclear Instruments and Methods in Physics Research Section A:

View full text Add to dashboard Cite

a b s t r a c tConventional PET systems can be augmented with additional detectors placed in close proximity of the region of interest. We developed a high resolution PET insert module to evaluate the added benefit of such a combination. The insert module consists of two back-to-back 1 mm thick silicon sensors, each segmented into 1040 1 mm 2 pads arranged in a 40 by 26 array. A set of 16 VATAGP7.1 ASICs and a custom assembled data acquisition board were used to read out the signal from the insert module.Data were acquired in slice (2D) geometry with a Jaszczak phantom (rod diameters of 1.2-4.8 mm) filled with 18 F-FDG and the images were reconstructed with ML-EM method. Both data with full and limited angular coverage from the insert module were considered and three types of coincidence events were combined.The ratio of high-resolution data that substantially improves quality of the reconstructed image for the region near the surface of the insert module was estimated to be about 4%. Results from our previous studies suggest that such ratio could be achieved at a moderate technological expense by using an equivalent of two insert modules (an effective sensor thickness of 4 mm).

show abstract

Section: Introductionmentioning

confidence: 99%

Evaluation of a high resolution silicon PET insert module

Grkovski

Brzezinski²,

Cindro

et al. 2015

Nuclear Instruments and Methods in Physics Research Section A:

View full text Add to dashboard Cite

show abstract

A multiscale X-ray phase-contrast tomography dataset of a whole human left lung

et al. 2022

View full text Add to dashboard Cite

Technological advancements in X-ray imaging using bright and coherent synchrotron sources now allows the decoupling of sample size and resolution while maintaining high sensitivity to the microstructures of soft, partially dehydrated tissues. The continuous developments in multiscale X-ray imaging resulted in hierarchical phase-contrast tomography, a comprehensive approach to address the challenge of organ-scale (up to tens of centimeters) soft tissue imaging with resolution and sensitivity down to the cellular level. Using this technique, we imaged ex vivo an entire human left lung at an isotropic voxel size of 25.08 μm along with local zooms down to 6.05–6.5 μm and 2.45–2.5 μm in voxel size. The high tissue contrast offered by the fourth-generation synchrotron source at the European Synchrotron Radiation Facility reveals the complex multiscale anatomical constitution of the human lung from the macroscopic (centimeter) down to the microscopic (micrometer) scale. The dataset provides comprehensive organ-scale 3D information of the secondary pulmonary lobules and delineates the microstructure of lung nodules with unprecedented detail.

show abstract

A versatile laboratory setup for high resolution X-ray phase contrast tomography and scintillator characterization

Dierks

Stjärneblad

Wallentin

2023

XST

View full text Add to dashboard Cite

BACKGROUND: X-ray micro-tomography (μCT) is a powerful non-destructive 3D imaging method applied in many scientific fields. In combination with propagation-based phase-contrast, the method is suitable for samples with low absorption contrast. Phase contrast tomography has become available in the lab with the ongoing development of micro-focused tube sources, but it requires sensitive and high-resolution X-ray detectors. The development of novel scintillation detectors, particularly for microscopy, requires more flexibility than available in commercial tomography systems. OBJECTIVE: We aim to develop a compact, flexible, and versatile μCT laboratory setup that combines absorption and phase contrast imaging as well as the option to use it for scintillator characterization. Here, we present details on the design and implementation of the setup. METHODS: We used the setup for μCT in absorption and propagation-based phase contrast mode, as well as to study a perovskite scintillator. RESULTS: We show the 2D and 3D performance in absorption and phase contrast mode, as well as how the setup can be used for testing new scintillator materials in a realistic imaging environment. A spatial resolution of around 1.3μm is measured in 2D and 3D. CONCLUSIONS: The setup meets the needs for common absorption μCT applications and offers the increased contrast in the phase contrast mode. The availability of a versatile laboratory μCT setup allows not only for easy access to tomographic measurements, but also enables a prompt monitoring and feedback beneficiary for advances in scintillator fabrication.

show abstract

Silicon detectors for combined MR–PET and MR–SPECT imaging

Cited by 3 publications

References 8 publications

Evaluation of a high resolution silicon PET insert module

Evaluation of a high resolution silicon PET insert module

A multiscale X-ray phase-contrast tomography dataset of a whole human left lung

A versatile laboratory setup for high resolution X-ray phase contrast tomography and scintillator characterization

Contact Info

Product

Resources

About