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Analysis of institutional authors

Sanchez, FCorresponding AuthorSoriano, AAuthorGonzalez, AAuthorHernandez, LAuthorRodríguez-álvarez, Mj AuthorBenlloch, JmAuthor

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October 31, 2024
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ALBIRA: A small animal PET/SPECT/CT imaging system

Publicated to:Medical Physics. 40 (5): 51906- - 2013-05-01 40(5), DOI: 10.1118/1.4800798

Authors: Sanchez, F; Orero, A; Soriano, A; Correcher, C; Conde, P; Gonzalez, A; Hernandez, L; Moliner, L; Rodriguez-Alvarez, M J; Vidal, L F; Benlloch, J M; Chapman, S E; Leevy, W M

Affiliations

Ctr Invest Principe Felipe, ONCOVISION - Author
Notre Dame Integrated Imaging Facil - Author
Univ Politecn Valencia, CIEMAT, Ctr Mixto CSIC, Inst Instrumentac Imagen Mol I3M - Author

Abstract

Purpose: The authors have developed a trimodal PET/SPECT/CT scanner for small animal imaging. The gamma ray subsystems are based on monolithic crystals coupled to multianode photomultiplier tubes (MA-PMTs), while computed tomography (CT) comprises a commercially available microfocus x-ray tube and a CsI scintillator 2D pixelated flat panel x-ray detector. In this study the authors will report on the design and performance evaluation of the multimodal system. Methods: X-ray transmission measurements are performed based on cone-beam geometry. Individual projections were acquired by rotating the x-ray tube and the 2D flat panel detector, thus making possible a transaxial field of view (FOV) of roughly 80 mm in diameter and an axial FOV of 65 mm for the CT system. The single photon emission computed tomography (SPECT) component has a dual head detector geometry mounted on a rotating gantry. The distance between the SPECT module detectors can be varied in order to optimize specific user requirements, including variable FOV. The positron emission tomography (PET) system is made up of eight compact modules forming an octagon with an axial FOV of 40 mm and a transaxial FOV of 80 mm in diameter. The main CT image quality parameters (spatial resolution and uniformity) have been determined. In the case of the SPECT, the tomographic spatial resolution and system sensitivity have been evaluated with a Tc-99m solution using single-pinhole and multi-pinhole collimators. PET and SPECT images were reconstructed using three-dimensional (3D) maximum likelihood and ordered subset expectation maximization (MLEM and OSEM) algorithms developed by the authors, whereas the CT images were obtained using a 3D based FBP algorithm. Results: CT spatial resolution was 85 mu m while a uniformity of 2.7% was obtained for a water filled phantom at 45 kV. The SPECT spatial resolution was better than 0.8 mm measured with a Derenzo-like phantom for a FOV of 20 mm using a 1-mm pinhole aperture collimator. The full width at half-maximum PET radial spatial resolution at the center of the field of view was 1.55 mm. The SPECT system sensitivity for a FOV of 20 mm and 15% energy window was 700 cps/MBq (7.8 x 10(-2)%) using a multi-pinhole equipped with five apertures 1 mm in diameter, whereas the PET absolute sensitivity was 2% for a 350-650 keV energy window and a 5 ns timing window. Several animal images are also presented. Conclusions: The new small animal PET/SPECT/CT proposed here exhibits high performance, producing high-quality images suitable for studies with small animals. Monolithic design for PET and SPECT scintillator crystals reduces cost and complexity without significant performance degradation. (c) 2013 American Association of Physicists in Medicine.

Keywords

AlgorithmAnimalAnimal experimentAnimalsArticleCalibrationCesium iodideComputed tomography scannerComputer assisted tomographyCrystalsCtDevicesEquipmentEquipment designFiltrationFlat-panel x-ray detectorGamma radiationGamma raysImage processingImage processing, computer-assistedImage qualityImage reconstructionImage resolutionInformation processingIntegrated pet/spect/ct scannerIntegrated petspectct scannerMaximum likelihoodMaximum principleMiceModulation transfer functionMouseMulti-anode photomultiplier tubesMulti-pinhole collimatorsMultimodal imagingNonhumanNuclear medicineOptimizationOrdered subset expectation maximizationsParticle beamsPerformance evaluationPet scannerPhantomsPhotomultipliersPinhole spectPositron emission tomographyPositron emission tomography (pet)Positron-emission tomographyPriority journalRadionuclide imagingRatRatsScanningScintillationScintillation countersSensitivity and specificitySensorSingle photon emission computed tomographySingle photon emission computer tomographySmall animal imagingSpect scannerTomography, emission-computed, single-photonTomography, x-ray computedX ray detectorsX ray tubeX ray tubesX rays

Quality index

Bibliometric impact. Analysis of the contribution and dissemination channel

The work has been published in the journal Medical Physics due to its progression and the good impact it has achieved in recent years, according to the agency WoS (JCR), it has become a reference in its field. In the year of publication of the work, 2013, it was in position 25/122, thus managing to position itself as a Q1 (Primer Cuartil), in the category Radiology, Nuclear Medicine & Medical Imaging.

From a relative perspective, and based on the normalized impact indicator calculated from World Citations provided by WoS (ESI, Clarivate), it yields a value for the citation normalization relative to the expected citation rate of: 2.58. This indicates that, compared to works in the same discipline and in the same year of publication, it ranks as a work cited above average. (source consulted: ESI Nov 14, 2024)

This information is reinforced by other indicators of the same type, which, although dynamic over time and dependent on the set of average global citations at the time of their calculation, consistently position the work at some point among the top 50% most cited in its field:

  • Weighted Average of Normalized Impact by the Scopus agency: 2.49 (source consulted: FECYT Feb 2024)
  • Field Citation Ratio (FCR) from Dimensions: 45.5 (source consulted: Dimensions Jul 2025)

Specifically, and according to different indexing agencies, this work has accumulated citations as of 2025-07-04, the following number of citations:

  • WoS: 77
  • Scopus: 88
  • Europe PMC: 30

Impact and social visibility

From the perspective of influence or social adoption, and based on metrics associated with mentions and interactions provided by agencies specializing in calculating the so-called "Alternative or Social Metrics," we can highlight as of 2025-07-04:

  • The use of this contribution in bookmarks, code forks, additions to favorite lists for recurrent reading, as well as general views, indicates that someone is using the publication as a basis for their current work. This may be a notable indicator of future more formal and academic citations. This claim is supported by the result of the "Capture" indicator, which yields a total of: 84 (PlumX).

It is essential to present evidence supporting full alignment with institutional principles and guidelines on Open Science and the Conservation and Dissemination of Intellectual Heritage. A clear example of this is:

  • The work has been submitted to a journal whose editorial policy allows open Open Access publication.

Leadership analysis of institutional authors

This work has been carried out with international collaboration, specifically with researchers from: United States of America.

There is a significant leadership presence as some of the institution’s authors appear as the first or last signer, detailed as follows: First Author (Sánchez Romero, Francisco Javier) .

the author responsible for correspondence tasks has been Sánchez Romero, Francisco Javier.