In vivo biodistribution and accumulation of 89Zr in mice

Abou, Diane S.; Ku, Thomas W.; Smith‐Jones, Peter

doi:10.1016/j.nucmedbio.2010.12.011

Cited by 233 publications

(267 citation statements)

References 19 publications

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“…However, 89 Zr-labeling of an anti-HER2-Fab showed much better in vivo stability and tumor uptake compared with 124 I-labeling (45). There are a number of options for potential improvement as the usage of smaller constructs with rapid blood clearance (46), amino acid preloading (47), infusion of cold renal-blocking agents (48), introduction of metabolizable linkages facilitating excretion of radiometabolites (44), or infusion of DFO to capture free 89 Zr (49), which need to be evaluated in the future.…”

Section: Discussionmentioning

confidence: 99%

Immuno-PET Imaging of Engineered Human T Cells in Tumors

et al. 2016

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Sensitive in vivo imaging technologies applicable to the clinical setting are still lacking for adoptive T-cell-based immunotherapies, an important gap to fill if mechanisms of tumor rejection or escape are to be understood. Here, we propose a highly sensitive imaging technology to track human TCR-transgenic T cells in vivo by directly targeting the murinized constant TCR beta domain (TCRmu) with a zirconium-89 ( 89 Zr)-labeled anti-TCRmu-F(ab') 2 fragment. Binding of the labeled or unlabeled F(ab') 2 fragment did not impair functionality of transgenic T cells in vitro and in vivo. Using a murine xenograft model of human myeloid sarcoma, we monitored by Immuno-PET imaging human central memory T cells (T CM ), which were transgenic for a myeloid peroxidase (MPO)-specific TCR. Diverse T-cell distribution patterns were detected by PET/CT imaging, depending on the tumor size and rejection phase. Results were confirmed by IHC and semiquantitative evaluation of T-cell infiltration within the tumor corresponding to the PET/CT images. Overall, these findings offer a preclinical proof of concept for an imaging approach that is readily tractable for clinical translation.

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Section: Discussionmentioning

confidence: 99%

Immuno-PET Imaging of Engineered Human T Cells in Tumors

et al. 2016

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“…[ 32 ] Bone uptake (4.0 ± 0.7% ID/g) might indicate (partial) release of 89 Zr in circulation, as free 89 Zr is known to deposit in the mineralized constituents of the bone, where it is assumed to be chelated by phosphate constituents and epiphysis. [ 33,34 ] However, in humans injected with 89 Zr-DFO-labeled antibodies minimal 89 Zr bone-uptake is observed. [ 35 ] The faster metabolism of mice together with their less specifi c peptidases involving rapid degradation of 89 Zr-DFO are likely the root cause for the 89 Zr bone uptake in mice as observed in both this work as well as in studies with 89 Zr-DFOlabeled antibodies.…”

Section: Blood Kinetics and Biodistributionmentioning

confidence: 99%

⁸⁹Zr‐ and Fe‐Labeled Polymeric Micelles for Dual Modality PET and T₁‐Weighted MR Imaging

Starmans

Hummelink

Rossin

et al. 2015

Adv Healthcare Materials

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In this study, a new Zr- and Fe -labeled micelle nanoplatform ( Zr/Fe-DFO-micelles) for dual modality position emission tomography/magnetic resonance (PET/MR) imaging is investigated. The nanoplatform consists of self-assembling amphiphilic diblock copolymers that are functionalized with Zr-deferoxamine ( Zr-DFO) and Fe -deferoxamine (Fe-DFO) for PET and MR purposes, respectively. Zr displays favorable PET imaging characteristics with a 3.3 d half-life suitable for imaging long circulating nanoparticles. The nanoparticles are modified with Fe-DFO as MR T -contrast label instead of commonly used Gd -based chelates. As these micelles are cleared by liver and spleen, any long term Gd- related toxicity such as nephrogenic systemic fibrosis is avoided. As a proof of concept, an in vivo PET/MR study in mice is presented showing tumor targeting of Zr/Fe-DFO-micelles through the enhanced permeability and retention (EPR) effect of tumors, yielding high tumor-to-blood (10.3 ± 3.6) and tumor-to-muscle (15.3 ± 8.1) ratios at 48 h post injection. In vivo PET images clearly delineate the tumor tissue and show good correspondence with ex vivo biodistribution results. In vivo magnetic resonance imaging (MRI) allows visualization of the intratumoral distribution of the Zr/Fe-DFO-micelles at high resolution. In summary, the Zr/Fe-DFO-micelle nanoparticulate platform allows EPR-based tumor PET/MRI, and, furthermore, holds great potential for PET/MR image guided drug delivery.

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“…However, there would be an obligate reduction in radioactivity at proliferation sites where the cells migrate away. An additional limitation and a potential pitfall is that small amounts of 89 Zr will be released after cell death, resulting in accumulation of 89 Zr in the bone due to chelation by hydroxylapatite (36), in addition to clearance from the kidneys. However, this is a slow process that occurs as the labeled cells die as compared with live cells homing to the bone marrow.…”

mentioning

confidence: 99%

⁸⁹Zr-Oxine Complex PET Cell Imaging in Monitoring Cell-based Therapies

Sato¹,

Wu²,

Asiedu³

et al. 2015

Radiology

128

177

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Purpose:To develop a clinically translatable method of cell labeling with zirconium 89 ( 89 Zr) and oxine to track cells with positron emission tomography (PET) in mouse models of cell-based therapy. Materials andMethods:This study was approved by the institutional animal care committee. 89Zr-oxine complex was synthesized in an aqueous solution. Cell labeling conditions were optimized by using EL4 mouse lymphoma cells, and labeling efficiency was examined by using dendritic cells (DCs) (n = 4), naïve (n = 3) and activated (n = 3) cytotoxic T cells (CTLs), and natural killer (NK) (n = 4), bone marrow (n = 4), and EL4 (n = 4) cells. The effect of ] cells, n = 4) and by measuring the tumor size (n = 6). Two-way analysis of variance was used to compare labeling conditions, the Wilcoxon test was used to assess cell survival and proliferation, and Holm-Sidak multiple tests were used to assess tumor growth and perform biodistribution analyses. Results:89 Zr-oxine complex was synthesized at a mean yield of 97.3% 6 2.8 (standard deviation). It readily labeled cells at room temperature or 4°C in phosphate-buffered saline (labeling efficiency range, 13.0%-43.9%) and was stably retained (83.5% 6 1.8 retention on day 5 in DCs). Labeling did not affect the viability of DCs and CTLs when compared with nonlabeled control mice (P . .05), nor did it affect functionality. 89Zr-oxine complex enabled extended cell tracking for 7 days. Labeled tumor-specific CTLs accumulated in the tumor (4.6% on day 7) and induced tumor regression (P , .05 on day 7). Conclusion:We have developed a 89Zr-oxine complex cell tracking technique for use with PET that is applicable to a broad range of cell types and could be a valuable tool with which to evaluate various cell-based therapies.q RSNA, 2015

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In vivo biodistribution and accumulation of 89Zr in mice

Cited by 233 publications

References 19 publications

Immuno-PET Imaging of Engineered Human T Cells in Tumors

Immuno-PET Imaging of Engineered Human T Cells in Tumors

⁸⁹Zr‐ and Fe‐Labeled Polymeric Micelles for Dual Modality PET and T₁‐Weighted MR Imaging

⁸⁹Zr-Oxine Complex PET Cell Imaging in Monitoring Cell-based Therapies

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In vivo biodistribution and accumulation of 89Zr in mice

Cited by 233 publications

References 19 publications

Immuno-PET Imaging of Engineered Human T Cells in Tumors

Immuno-PET Imaging of Engineered Human T Cells in Tumors

89Zr‐ and Fe‐Labeled Polymeric Micelles for Dual Modality PET and T1‐Weighted MR Imaging

89Zr-Oxine Complex PET Cell Imaging in Monitoring Cell-based Therapies

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Product

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⁸⁹Zr‐ and Fe‐Labeled Polymeric Micelles for Dual Modality PET and T₁‐Weighted MR Imaging

⁸⁹Zr-Oxine Complex PET Cell Imaging in Monitoring Cell-based Therapies