Projects / Programmes source: ARIS

Limited angle PET system

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Research activity

Code Science Field Subfield
2.06.00  Engineering sciences and technologies  Systems and cybernetics   

Code Science Field
2.06  Engineering and Technology  Medical engineering  
Keywords
positron emission tomography, time-of-flight measurement, limited angle tomography, silicon photomultipliers, detector integration
Evaluation (metodology)
source: COBISS
Evaluation of bibliographic research performance indicators according to ARIS methodology
Points
10,444.41
A''
1,949.84
A'
5,172.22
A1/2
6,892.43
CI10
30,395
CImax
1,214
h10
81
A1
37.2
A3
14.71
Data for the last 5 years (citations for the last 10 years) on October 15, 2025; Data for score A3 calculation refer to period 2020-2024
Data for ARIS tenders ( 04.04.2019 – Programme tender, archive )
Citations Citations for bibliographic records in COBIB.SI that are linked to records in citation databases
source: WoS source: Scopus source: COBISS
Database Linked records Citations Pure citations Average pure citations
WoS  594  18,461  16,558  27.88 
Scopus  600  25,403  23,354  38.92 
Organisations (5) , Researchers (24)
0106  Jožef Stefan Institute
no. Code Name and surname Research area Role Period No. of publications
1.  39132  PhD Dania Consuegra Rodriguez  Physics  Researcher  2024 - 2025  10 
2.  29519  PhD Rok Dolenec  Physics  Researcher  2024 - 2025  98 
3.  11598  PhD Samo Korpar  Physics  Researcher  2024 - 2025  879 
4.  08725  PhD Peter Križan  Physics  Researcher  2024 - 2025  1,070 
5.  53458  Andrej Lozar  Physics  Researcher  2025  31 
6.  16354  PhD Rok Pestotnik  Physics  Head  2024 - 2025  767 
7.  51913  PhD Gašper Razdevšek  Physics  Researcher  2024 - 2025  12 
8.  33990  PhD Andrej Seljak  Physics  Researcher  2024 - 2025  62 
9.  21552  PhD Andrej Studen  Physics  Researcher  2024 - 2025  150 
0312  University Medical Centre Ljubljana
no. Code Name and surname Research area Role Period No. of publications
1.  22346  PhD Luka Ležaič  Human reproduction  Researcher  2024 - 2025  254 
2.  29364  PhD Sebastijan Rep  Human reproduction  Researcher  2024 - 2025  128 
3.  24691  PhD Petra Tomše  Cardiovascular system  Researcher  2024 - 2025  134 
4.  15442  PhD Maja Trošt  Neurobiology  Researcher  2024 - 2025  479 
5.  20484  PhD Katja Zaletel  Metabolic and hormonal disorders  Researcher  2024 - 2025  443 
0406  University of Ljubljana, Veterinary Faculty
no. Code Name and surname Research area Role Period No. of publications
1.  18117  PhD Modest Vengušt  Veterinarian medicine  Researcher  2024 - 2025  133 
0782  University of Ljubljana, Faculty of Mechanical Engineering
no. Code Name and surname Research area Role Period No. of publications
1.  54860  Simon Bogić    Technical associate  2024 - 2025  28 
2.  18580  PhD Andrej Kitanovski  Process engineering  Researcher  2024 - 2025  567 
3.  50695  PhD Katja Klinar  Process engineering  Researcher  2024 - 2025  128 
4.  50822  PhD Nada Petelin  Process engineering  Researcher  2025  58 
5.  34418  PhD Urban Tomc  Process engineering  Researcher  2024 - 2025  118 
1538  University of Ljubljana, Faculty of Electrical Engineering
no. Code Name and surname Research area Role Period No. of publications
1.  59600  Tina Perko  Electronic components and technologies  Researcher  2024 - 2025 
2.  18185  PhD Andrej Trost  Electronic components and technologies  Researcher  2024 - 2025  346 
3.  24026  MSc Damjan Zadnik  Computer science and informatics  Researcher  2024 - 2025 
4.  13143  PhD Andrej Žemva  Electronic components and technologies  Researcher  2024 - 2025  662 
Abstract
Positron emission tomography (PET) is a crucial diagnostic tool in modern medicine, providing three-dimensional imaging of functional processes within the body. This method detects two gamma rays originating from the point of annihilation of the positron emitted by a radio-labeled agent and utilizes them to follow physiological processes in humans. In Time-Of-Flight PET, gamma rays' arrival time is measured, in addition to their position, to improve the accuracy of imaging. State-of-the-art scanners have a coincidence timing resolution between 200 ps and 500 ps FWHM, which significantly enhances contrast in imaging large objects. However, next-generation PET scanners require substantial improvements in timing accuracy to enhance sensitivity. We propose a PET device with limited angular coverage consisting of four-panel detectors with a coincidence time resolution of about 100 ps FWHM. This project aims to develop and validate this device to be useful in next-generation PET scanners, enabling various applications from devices with limited angular coverage to total body PET devices. The technology has many competitive advantages, including dramatically reduced PET apparatus costs, and making diagnostics more accessible to healthcare systems.
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