ImmunoPET, [64Cu]Cu-DOTA-Anti-CD33 PET-CT, Imaging of an AML Xenograft Model

Madabushi, Srideshikan Sargur; Brooks, Jamison; Zuro, Darren; Kumar, Bijender; Sanchez, James F.; Parra, Liliana Echavarria; Orellana, Marvin; Vishwasrao, Paresh; Nair, Indu; Chea, Junie; Poku, Kofi; Bowles, Nicole; Miller, Aaron David; Ebner, Todd; Molnar, Justin; Rosenthal, Joseph; Vallera, Daniel A.; Wong, Jeffrey Y.C.; Stein, Anthony S.; Colcher, David; Shively, John E.; Yazaki, Paul J.; Song, Hui

doi:10.1158/1078-0432.ccr-19-1106

Cited by 17 publications

(8 citation statements)

References 45 publications

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“…Therefore, the GVHD mouse model in allogeneic BMT settings using TMI would enable us to further understand the role of radiation-induced gut damage in GVHD. (iv) A recent study using an anti-CD33-PET imaging modality showed that AML disease localizes mostly in the skeletal system and is highly heterogeneous (41). The PET-guided functional TMI (fTMI) could allow localized radiation boosts to sites of high disease burden to enhance increased tumor cell killing without damaging the entire skeletal system(11,42).…”

Section: Discussionmentioning

confidence: 99%

Review of Palliative Radiation Therapy Patterns of Practice for Adrenal Metastases in British Columbia

Parhar

Livergant

Lefresne

2021

International Journal of Radiation Oncology*Biology*Physics

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Section: Discussionmentioning

confidence: 99%

Review of Palliative Radiation Therapy Patterns of Practice for Adrenal Metastases in British Columbia

Parhar

Livergant

Lefresne

2021

International Journal of Radiation Oncology*Biology*Physics

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“…In two recent studies, researchers reported the feasibility and satisfactory treatment efficacy of 90 Y-rituximab in patients with relapsed or refractory NHL. , Furthermore, several preclinical and clinical studies have reported the superior effectiveness of pRIT or RIT in treating lymphomas by targeting several targets, such as CD20, , CD38, and CD45 . CD33 is another alternative target for RIT of hematological malignancies , and for immunoPET imaging . Continuous innovation of the pRIT systems and incorporation of immunoPET techniques may reinvigorate the enthusiasm for managing hematologic malignancies with nuclear medicine approaches.…”

Section: Immunopet Imaging-guided Advanced Therapeuticsmentioning

confidence: 99%

“…913 CD33 is another alternative target for RIT of hematological malignancies 914,915 and for immunoPET imaging. 916 Continuous innovation of the pRIT systems and incorporation of immunoPET techniques may reinvigorate the enthusiasm for managing hematologic malignancies with nuclear medicine approaches. Readers are recommended to refer to an excellent review parsing RIT for more information.…”

Section: Immunopet Imaging-guided Advanced Therapeuticsmentioning

confidence: 99%

ImmunoPET: Concept, Design, and Applications

et al. 2020

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Immuno-positron emission tomography (immunoPET) is a paradigmshifting molecular imaging modality combining the superior targeting specificity of monoclonal antibody (mAb) and the inherent sensitivity of PET technique. A variety of radionuclides and mAbs have been exploited to develop immunoPET probes, which has been driven by the development and optimization of radiochemistry and conjugation strategies. In addition, tumor-targeting vectors with a short circulation time (e.g., Nanobody) or with an enhanced binding affinity (e.g., bispecific antibody) are being used to design novel immunoPET probes. Accordingly, several immunoPET probes, such as 89 Zr-Df-pertuzumab and 89 Zr-atezolizumab, have been successfully translated for clinical use. By noninvasively and dynamically revealing the expression of heterogeneous tumor antigens, immunoPET imaging is gradually changing the theranostic landscape of several types of malignancies. ImmunoPET is the method of choice for imaging specific tumor markers, immune cells, immune checkpoints, and inflammatory processes. Furthermore, the integration of immunoPET imaging in antibody drug development is of substantial significance because it provides pivotal information regarding antibody targeting abilities and distribution profiles. Herein, we present the latest immunoPET imaging strategies and their preclinical and clinical applications. We also emphasize current conjugation strategies that can be leveraged to develop next-generation immunoPET probes. Lastly, we discuss practical considerations to tune the development and translation of immunoPET imaging strategies.

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“…PDCs with a toxic payload attached, DM4 in the case of CX-2009, aim at delivering selectively their payload to tumors via widely expressed antigens, such as CD166. We evaluated the potential of CX-2009 by performing 89 Zr-immuno-PET and biodistribution studies in a CD166-positive H292 lung cancer mouse model in comparison with its radiolabeled benchmark compounds, the Probody therapeutic without DM4 (CX-191), the unmasked antibody drug conjugate (ADC) CX-1031, and the parental mAb CX-090 at three different doses (10,110, or 510 µg) and different time points (24,72, and 168 hours post-injection (p.i.)). Tumor uptake was similar for all constructs at 72 hrs p.i.…”

Section: Discussionmentioning

confidence: 99%

“…the different experimental groups, being 264 ± 145 mm 3 . As a first step, the biodistribution of [89 Zr]Zr-CX-2009 was assessed as a function of dose (10, 110, or 510 µg; Figure3Aand TableS1) and time(24,72, and 168 h p.i. ; Figure3Band TableS2).…”

mentioning

confidence: 99%

89Zr-immuno-PET in translational development of biopharmaceuticals

Chomet¹

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Biologicals gained attention over the past decades thanks to their therapeutic success especially in oncology. Positron Emission Tomography (PET) with Zirconium-89 is attractive thanks to 89Zr half-life (78.41h) matching the biological half-life of monoclonal antibodies (mAbs). We provide an overview of 89Zr-immuno-PET imaging using current and emerging radiolabeling tools and preclinical imaging to facilitate translation to the clinic of new antibody constructs. By improving the radiochemistry toolbox and better understanding quantification using preclinical PET cameras, new opportunities can be translated in the clinic. Chapter 1 introduces the current position of PET and 89Zr-immuno-PET imaging, in the context of biopharmaceuticals development while Chapter 2 gives an overview of current radiolabeling methods of biopharmaceuticals with 89Zr, 64Cu and 68Ga but also less common radiometals: 52Mn, 86Y, 66Ga, 44Sc, and 18F as in [18F]AlF. Chelator-radionuclide pairs and radiolabeling conditions are discussed along with recent preclinical and clinical trends. Chapter 3 evaluates with 89Zr-immuno-PET, CX-2009, a Probody Drug Conjugate (PDC) with a toxic DM4 payload attached. Probody® therapeutics possess antigen binding domains masked by peptide caps, only removed in the tumor environment by tumor-associated proteases, locally overexpressed. Probodies aim at widening the therapeutic window while PDCs at delivering selectively their payload to tumors via widely expressed antigens. We evaluated CX-2009 in CD166-positive lung cancer mice in comparison with its Probody, unmasked antibody drug conjugate, and parental mAb derivatives. Tumor uptake was similar for all constructs 72h p.i. demonstrating that CX-2009 can target CD166-expressing tumors and thus supporting clinical evaluation of Probody® therapeutics. In chapter 4, the novel octadentate chelator DFO* was studied in depth and compared with desferrioxamine (DFO), current standard for 89Zr-immuno-PET, DFOSq, also reported as potential successor of DFO and DFO*Sq included to evaluate the extra hydroxamate or squaramide group contribution to 89Zr complexation. [89Zr]Zr-DFO*-NCS-trastuzumab and [89Zr]Zr-DFO*Sq-trastuzumab showed excellent stability in vitro, superior to their [89Zr]Zr-DFO counterparts. In breast cancer mice, DFO* derivatives were more stable than DFO derivatives especially in bones. DFOSq did not outperform the DFO derivative, suggesting that Sq is not improving in vivo stability. Cetuximab, directed against the Epidermal-Growth-Factor-Receptor was used in xenograft mice and again DFO* was superior over DFO regarding bone uptake. In an intratibial bone metastasis model, [89Zr]Zr-DFO*-trastuzumab, [89Zr]Zr-DFO-trastuzumab, [89Zr]Zr-DFO*-B12 and [89Zr]Zr-DFO-B12 (non-targeting control mAb) were evaluated and the DFO*-conjugate appeared superior over the DFO-conjugate with a tumour-specific signal in bone tumors. Chapter 5, provides in-depth comparison between PET imaging and ex vivo biodistribution quantification. We performed phantom studies with a NanoScan PET/CT and PET/MR with the most used PET radionuclides (11C, 68Ga, 18F and 89Zr). The cameras performed similarly: the highest recovery coefficient being with 18F, followed by 11C and 89Zr and finally 68Ga. Both scanners were evaluated after injection of [18F]FDG and [89Zr]Zr-DFO-NCS-trastuzumab in breast cancer mice and performed equally well regarding tumor quantification with PET-assessed uptake lower than ex vivo values. In brains, [18F]FDG-PET/ex vivo ratios were excellent suggesting that brain is suitable for quantitative imaging of 18F-tracers but not for 89Zr-radiolabeled-mAbs, probably due to poor brain penetration. In kidney and liver more disparities were observed. Preclinical cameras and ex vivo biodistribution quantification, requires fully described standardised protocols for reliability, reproducibility and inter-study comparisons. This research offers a state-of-the-art overview and promising developments regarding 89Zr-immuno-PET imaging. It provides new insights on preclinical studies including quantification with preclinical scanners and new tools for radiolabeling biologicals confirming 89Zr-immuno-PET imaging potential to evaluate new constructs. In vitro and in vivo superiority of the new chelator DFO* over the gold standard for clinical 89Zr-immuno-PET, DFO, was confirmed in various models, especially regarding bone uptake. DFO* is thus considered as the successor of DFO for clinical applications.

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ImmunoPET, [64Cu]Cu-DOTA-Anti-CD33 PET-CT, Imaging of an AML Xenograft Model

Cited by 17 publications

References 45 publications

Review of Palliative Radiation Therapy Patterns of Practice for Adrenal Metastases in British Columbia

Review of Palliative Radiation Therapy Patterns of Practice for Adrenal Metastases in British Columbia

ImmunoPET: Concept, Design, and Applications

89Zr-immuno-PET in translational development of biopharmaceuticals

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