The α-Camera: A Quantitative Digital Autoradiography Technique Using a Charge-Coupled Device for Ex Vivo High-Resolution Bioimaging of α-Particles

Bäck, Tom; Jacobsson, Lars

doi:10.2967/jnumed.110.077578

Cited by 100 publications

(80 citation statements)

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“…27 Cryosections of spleen and femur from leukemia-bearing mice treated with 211 At-B10-30F11 were imaged with the a-camera technique at various time points after radiolabeled injections. At the 3-hour time point, a-camera imaging revealed that 211 At was distributed throughout the spleen and bone marrow, with some variability that correlates with suborgan architecture.…”

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confidence: 99%

Anti-CD45 radioimmunotherapy using 211At with bone marrow transplantation prolongs survival in a disseminated murine leukemia model

Orozco

Bäck

Kenoyer

et al. 2013

Blood

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Key Points• Astatination of anti-CD45antibody via a closodecaborate compound yields a stable conjugate that targets radiation to hematologic organs.• 211 At-anti-CD45 radioimmunotherapy combined with bone marrow transplantation prolongs survival in a disseminated murine leukemia model.Despite aggressive chemotherapy combined with hematopoietic stem cell transplantation (HSCT), many patients with acute myeloid leukemia (AML) relapse. Radioimmunotherapy (RIT) using monoclonal antibodies labeled with b-emitting radionuclides has been explored to reduce relapse. b emitters are limited by lower energies and nonspecific cytotoxicity from longer path lengths compared with a emitters such as 211 At, which has a higher energy profile and shorter path length. We evaluated the efficacy and toxicity of anti-CD45 RIT using 211 At in a disseminated murine AML model. Biodistribution studies in leukemic SJL/J mice showed excellent localization of 211 At-anti-murine CD45 mAb (30F11) to marrow and spleen within 24 hours (18% and 79% injected dose per gram of tissue [ID/g], respectively), with lower kidney and lung uptake (8.4% and 14% ID/g, respectively). In syngeneic HSCT studies, 211 At-B10-30F11 RIT improved the median survival of leukemic mice in a dose-dependent fashion (123, 101, 61, and 37 days given 24, 20, 12, and 0 mCi, respectively). This approach had minimal toxicity with nadir white blood cell counts >2.7 K/mL 2 weeks after HSCT and recovery by 4 weeks. These data suggest that 211 At-anti-CD45 RIT in conjunction with HSCT may be a promising therapeutic option for AML. (Blood. 2013;121(18):3759-3767) IntroductionAcute myeloid leukemia (AML) is an aggressive malignancy with few treatments producing prolonged remissions in high-risk patients. Hematopoietic stem cell transplantation (HSCT) may offer the best chance for a cure, but it has been associated with high rates of treatment-related mortality and relapse. Investigators have escalated chemotherapy and/or radiation doses to decrease relapse, but this strategy has been associated with substantial toxicity yielding no significant improvement in overall survival. 1 Monoclonal antibodies (mAbs) targeting hematologic-specific antigens have been used in radioimmunotherapy (RIT) studies as a means to deliver higher radiation doses prior to HSCT. [2][3][4][5][6] One such target is CD45, a cell surface antigen highly expressed on hematologic tissues (;200 000 binding sites per cell) with minimal expression on nonhematologic tissues. 7,8 CD45 is not extensively internalized after mAb binding, 9,10 further making anti-CD45 RIT a viable approach for therapy of high-risk AML. In particular, anti-CD45 mAb coupled to 131 I has been shown to deliver an average twofold to threefold higher radiation-absorbed dose to spleen and bone marrow than to nonleukemic normal organs, and it can be safely administered to high-risk patients with acute leukemia or myelodysplastic syndrome in conjunction with standard high-dose chemotherapy and 12Gy totalbody irradiation. 5,11 Favorable results ...

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Anti-CD45 radioimmunotherapy using 211At with bone marrow transplantation prolongs survival in a disseminated murine leukemia model

Orozco

Bäck

Kenoyer

et al. 2013

Blood

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“…Repeated sampling of peritoneal fluid has also been reported ). In principle, measurements or images of biopsies from organs of interest would be valuable (Bäck et al, 2010), but the increased dosimetric accuracy gained must be weighed against the discomfort such invasive procedures cause the patient. Simple, non-invasive methods using uptake probes can also provide important information on the pharmacokinetics for an individual www.intechopen.com patient.…”

Section: Radiation Dosimetry In the Clinical Situationmentioning

confidence: 99%

Intraperitoneal Radionuclide Therapy – Clinical and Pre-Clinical Considerations

Elgqvist¹,

Lindegren²,

Albertsson³

2012

Ovarian Cancer - Clinical and Therapeutic Perspectives

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“…The a-camera system consisted of a cooled, high-sensitivity charge-coupled device (SXV-H9; Starlight Xpress Ltd.), coupled to a photographic lens (60 mm f/2.8 Micro-Nikkor; Nikon Corp.) (12). Specimens to be imaged (i.e., tissue sections on a scintillating sheet) were placed on an adjustable stand below the photographic lens.…”

Section: A-camera Imagesmentioning

confidence: 99%

“…The excised biologic samples were snap-frozen and cryosectioned as previously described (12). Ten to 20 pairs of consecutive sections were analyzed for each sample: one section for a-camera imaging and the other section for staining with hematoxylin and eosin (H&E) (in some cases, 3 consecutive sections were analyzed [ Fig.…”

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Ex Vivo Activity Quantification in Micrometastases at the Cellular Scale Using the α-Camera Technique

et al. 2013

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Targeted a-therapy (TAT) appears to be an ideal therapeutic technique for eliminating malignant circulating, minimal residual, or micrometastatic cells. These types of malignancies are typically infraclinical, complicating the evaluation of potential treatments. This study presents a method of ex vivo activity quantification with an a-camera device, allowing measurement of the activity taken up by tumor cells in biologic structures a few tens of microns. Methods: We examined micrometastases from a murine model of ovarian carcinoma after injection of a radioimmunoconjugate labeled with 211 At for TAT. At different time points, biologic samples were excised and cryosectioned. The activity level and the number of tumor cells were determined by combined information from 2 adjacent sections: one exposed to the a-camera and the other stained with hematoxylin and eosin. The time-activity curves for tumor cell clusters, comprising fewer than 10 cells, were derived for 2 different injected activities (6 and 1 MBq). Results: High uptake and good retention of the radioimmunoconjugate were observed at the surface of tumor cells. Dosimetric calculations based on the measured time-integrated activity indicated that for an injected activity of 1 MBq, isolated tumor cells received at least 12 Gy. In larger micrometastases (#100 mm in diameter), the activity uptake per cell was lower, possibly because of hindered penetration of radiolabeled antibodies; however, the mean absorbed dose delivered to tumor cells was above 30 Gy, due to cross-fire irradiation. Conclusion: Using the a-camera, we developed a method of ex vivo activity quantification at the cellular scale, which was further applied to characterize the behavior of a radiolabeled antibody administered in vivo against ovarian carcinoma. This study demonstrated a reliable measurement of activity. This method of activity quantification, based on experimentally measured data, is expected to improve the relevance of small-scale dosimetry studies and thus to accelerate the optimization of TAT. On the basis of the characteristics of the a-particle, targeted a-therapy (TAT) has been acknowledged as a potentially efficient therapeutic technique (1) for decades. a-particles have a short range in tissue, making the irradiation specific, and a high linear energy transfer, making them highly cytotoxic (2). These properties make them suitable for the treatment of hematologic malignancies or minimal residual or micrometastatic diseases (3,4). The first clinical trials using TAT have been started for the treatment of leukemia (5,6), ovarian carcinoma (7), and residual tumor cells after surgery of malignant brain tumors (8).Micrometastatic diseases are infraclinical and hardy or not localized with in vivo imaging techniques. Thus, targeted radionuclide therapies of tumor cells or micrometastases require complex evaluations. Activity quantification of micrometric lesions by imaging is difficult in patients because of the limited spatial resolution. Only rough estimations of the activity of...

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The α-Camera: A Quantitative Digital Autoradiography Technique Using a Charge-Coupled Device for Ex Vivo High-Resolution Bioimaging of α-Particles

Cited by 100 publications

References 17 publications

Anti-CD45 radioimmunotherapy using 211At with bone marrow transplantation prolongs survival in a disseminated murine leukemia model

Anti-CD45 radioimmunotherapy using 211At with bone marrow transplantation prolongs survival in a disseminated murine leukemia model

Intraperitoneal Radionuclide Therapy – Clinical and Pre-Clinical Considerations

Ex Vivo Activity Quantification in Micrometastases at the Cellular Scale Using the α-Camera Technique

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