2019
DOI: 10.1002/mp.13724
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A second‐generation virtual‐pinhole PET device for enhancing contrast recovery and improving lesion detectability of a whole‐body PET/CT scanner

Abstract: Purpose We have developed a second‐generation virtual‐pinhole (VP) positron emission tomography (PET) device that can position a flat‐panel PET detector around a patient's body using a robotic arm to enhance the contrast recovery coefficient (CRC) and detectability of lesions in any region‐of‐interest using a whole‐body PET/computed tomography (CT) scanner. Methods We constructed a flat‐panel VP‐PET device using 32 high‐resolution detectors, each containing a 4 × 4 MPPC array and 16 × 16 LYSO crystals of 1.0 ×… Show more

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Cited by 14 publications
(5 citation statements)
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“…A separate preliminary study we conduct shows that the events from different detector layers all contribute, although differently in terms of their resolution property and statistical quantity, towards improving the image quality. This finding is consistent with the image resolution and SNR improvement reported on virtual pinhole PET [36,45] and zoom-in PET [37] when events with variable resolution properties are involved.…”
Section: E What Enables the High Resolutionsupporting
confidence: 89%
“…A separate preliminary study we conduct shows that the events from different detector layers all contribute, although differently in terms of their resolution property and statistical quantity, towards improving the image quality. This finding is consistent with the image resolution and SNR improvement reported on virtual pinhole PET [36,45] and zoom-in PET [37] when events with variable resolution properties are involved.…”
Section: E What Enables the High Resolutionsupporting
confidence: 89%
“…The proposed insert will induce additional attenuation in the whole-body scanner FOV, which will degrade the PET performance characteristics in terms of the sensitivity and spatial resolution of the whole-body PET modality by opaque LORs and scattering at the insert, thus, an accurate attenuation correction must be implemented. However, placing a PET insert inside a whole-body PET scanner opens up the possibility of recording PET-PET coincidences between the insert and scanner, which could be used to improve the spatial resolution outside the insert FOV through the virtual pinhole effect (Tai et al 2008, Mathews et al 2013, Jiang et al 2019.…”
Section: Discussionmentioning
confidence: 99%
“…The axial FOV of the scanner is 220 mm. The integration of the flatpanel detector with the scanner, including readout electronics and data acquisition were described and can be found in [30].…”
Section: Experimental Verification Of the Concept Using Existing Flat-panel Detectormentioning
confidence: 99%
“…Approaches that bring the benefits of organ-specific PET to a clinical PET/CT scanner have emerged in recent years and been independently validated [22][23][24][25], including multi-resolution PET [26,27], zoom-in PET [28], and virtual-pinhole PET (VP-PET) [23]. We previously developed several prototype VP-PET insert systems and demonstrated its ability to improve the image resolution of a clinical PET/CT scanner without compromising its whole-body imaging capability [29,30]. Although the VP-PET insert technique enables zoom-in imaging for an organ-of-interest, it does not directly benefit whole-body cancer staging where the location of a distant metastasis, and thus the "target" region to zoom-in on, is unknown.…”
Section: Introductionmentioning
confidence: 99%