Positron emission tomography with additional <i>γ</i>
-ray detectors for multiple-tracer imaging

Fukuchi, Tetsuo; Okauchi, Takashi; Shigeta, Mika; Yamamoto, Seiichi; Watanabe, Yasuyoshi; Enomoto, Shuichi

doi:10.1002/mp.12149

Cited by 25 publications

(15 citation statements)

References 16 publications

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“…These can be detected with additional gammaray detectors allowing the detection of multiple PET isotopes within the same system. 43 Despite its lower global availability, there are an increasing number of PET scanners and radiotracers becoming available in clinics worldwide, due to the superior sensitivity and spatial resolution. Finally, the recent breakthrough in the PET imaging field of the clinical total-body scanner technology should be highlighted.…”

Section: Positron Emission Tomography (Pet)mentioning

confidence: 99%

Radiolabelling of nanomaterials for medical imaging and therapy

2021

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Section: Positron Emission Tomography (Pet)mentioning

confidence: 99%

Radiolabelling of nanomaterials for medical imaging and therapy

2021

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“…In PET, however, all photons emitted during positron annihilation have the same 511 keV energy, making multi-radionuclide imaging not currently possible with standard scanners. Interestingly, many PET radionuclides also emit characteristic gamma rays, and it is therefore possible to simultaneously detect multiple PET isotopes with additional gamma-ray detectors by locating triple-coincidence events [16].…”

Section: Radionuclide Imagingmentioning

confidence: 99%

Nuclear imaging of liposomal drug delivery systems: A critical review of radiolabelling methods and applications in nanomedicine

Man

Gawne

Rosales

2019

Advanced Drug Delivery Reviews

124

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The integration of nuclear imaging with nanomedicine is a powerful tool for efficient development and clinical translation of liposomal drug delivery systems. Furthermore, it may allow highly efficient imaging-guided personalised treatments. In this article, we critically review methods available for radiolabelling liposomes. We discuss the influence that the radiolabelling methods can have on their biodistribution and highlight the often-overlooked possibility of misinterpretation of results due to decomposition in vivo. We stress the need for knowing the biodistribution/pharmacokinetics of both the radiolabelled liposomal components and free radionuclides in order to confidently evaluate the images, as they often share excretion pathways with intact liposomes (e.g. phospholipids, metallic radionuclides) and even show significant tumour uptake by themselves (e.g. some radionuclides). Finally, we describe preclinical and clinical studies using radiolabelled liposomes and discuss their impact in supporting liposomal drug development and clinical translation in several diseases, including personalised nanomedicine approaches.

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“…A second method is simultaneous imaging of a pure positron emitter and a positron emitter coemitting prompt gammas (Andreyev and Celler 2011, Gonzalez et al 2011, Andreyev et al 2014. The development of a small-animal multi-isotope PET based on this principle was reported recently (Fukuchi et al 2017). This method has the disadvantage that it requires modifications to the scanner's electronics to detect three gammas in coincidence and that a large number of quite bulky additional gamma detectors need to be added to reach a reasonable sensitivity for the scarce triple coincidences.…”

Section: Introductionmentioning

confidence: 99%

Positron range-free and multi-isotope tomography of positron emitters

Beekman¹,

Kamphuis²,

Koustoulidou³

et al. 2021

Phys. Med. Biol.

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Despite improvements in small animal PET instruments, many tracers cannot be imaged at sufficiently high resolutions due to positron range, while multi-tracer PET is hampered by the fact that all annihilation photons have equal energies. Here we realize multi-isotope and sub-mm resolution PET of isotopes with several mm positron range by utilizing prompt gamma photons that are commonly neglected. A PET-SPECT-CT scanner (VECTor/CT, MILabs, The Netherlands) equipped with a high-energy cluster-pinhole collimator was used to image 124 I and a mix of 124 I and 18 F in phantoms and mice. In addition to positrons (mean range 3.4 mm) 124 I emits large amounts of 603 keV prompt gammas that-aided by excellent energy discrimination of NaI-were selected to reconstruct 124 I images that are unaffected by positron range. Photons detected in the 511 keV window were used to reconstruct 18 F images. Images were reconstructed iteratively using an energy dependent matrix for each isotope. Correction of 18 F images for contamination with 124 I annihilation photons was performed by Monte Carlo based range modelling and scaling of the 124 I prompt gamma image before subtracting it from the 18 F image. Additionally, prompt gamma imaging was tested for 89 Zr that emits very high-energy prompts (909 keV). In Derenzo resolution phantoms 0.75 mm rods were clearly discernable for 124 I, 89 Zr and for simultaneously acquired 124 I and 18 F imaging. Image quantification in phantoms with reservoirs filled with both 124 I and 18 F showed excellent separation of isotopes and high quantitative accuracy. Mouse imaging showed uptake of 124 I in tiny thyroid parts and simultaneously injected 18 F-NaF in bone structures. The ability to obtain PET images at sub-mm resolution both for isotopes with several mm positron range and for multi-isotope PET adds to many other unique capabilities of VECTor's clustered pinhole imaging, including simultaneous sub-mm PET-SPECT and theranostic high energy SPECT.

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Positron emission tomography with additional γ -ray detectors for multiple-tracer imaging

Cited by 25 publications

References 16 publications

Radiolabelling of nanomaterials for medical imaging and therapy

Radiolabelling of nanomaterials for medical imaging and therapy

Nuclear imaging of liposomal drug delivery systems: A critical review of radiolabelling methods and applications in nanomedicine

Positron range-free and multi-isotope tomography of positron emitters

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