Feasibility study of quantitative radioactivity monitoring of tumor tissues inoculated into mice with a planar positron imaging system (PPIS)

The motivations and methodology for high-throughput PET imaging of small animals in cancer research

Over the last decade, small-animal PET imaging has become a vital platform technology in cancer research. With the development of molecularly targeted therapies and drug combinations requiring evaluation of different schedules, the number of animals to be imaged within a PET experiment has increased. This paper describes experimental design requirements to reach statistical significance, based on the expected change in tracer uptake in treated animals as compared to the control group, the number of groups that will be imaged, and the expected intra-animal variability for a given tracer. We also review how high-throughput studies can be performed in dedicated small-animal PET, high-resolution clinical PET systems and planar positron imaging systems by imaging more than one animal simultaneously. Customized beds designed to image more than one animal in large-bore small-animal PET scanners are described. Physics issues related to the presence of several rodents within the field of view (i.e. deterioration of spatial resolution and sensitivity as the radial and the axial offsets increase, respectively, as well as a larger effect of attenuation and the number of scatter events), which can be assessed by using the NEMA NU 4 image quality phantom, are detailed.

Monitoring of 2-deoxy-2-[18F]fluoro-D-glucose uptake in tumor-bearing mice using high-sensitivity projection imaging: compared with PET imaging

OBJECTIVE

To investigate the feasibility of using high-sensitivity projection [F]fluoro-deoxyglucose imaging to monitor chemotherapeutic efficacy in BALB/c mice bearing CT-26 tumor implants.

METHODS

A planar positron imaging system (PPIS)-4800 and a microPET R4 were used for projection and tomographic imaging, respectively. Six disks filled with different volumes of F-FDG solution were scanned by PPIS for calibration check. Tumor-bearing mice were treated with saline (control) or cyclophosphamide by intraperitoneal injections. Tumor responses were evaluated by both PPIS and microPET imaging.

RESULTS

The disk-activity ratios obtained from PPIS were 1.00: 1.30: 1.98: 2.48: 2.73: 3.53 with corresponding volume ratios of 1.0: 1.5: 2.0: 2.5: 3.0: 3.5. PPIS imaging in tumor-bearing mice showed that the tumor/non-tumor ratios were 1.62, 2.12, 3.03, 4.46, and 3.61 on days 7, 10, 13, 17, and 20, respectively, after tumor inoculation. In addition, PPIS was used to monitor the chemotherapeutic effect of cyclophosphamide on tumor-bearing mice. The correlation coefficients between the tumor sizes and tumor/non-tumor ratios for microPET and PPIS were 0.63 and 0.72, respectively, in the control group, and were 0.98 and 0.81, respectively, in the cyclophosphamide-treated group.

CONCLUSION

This study showed that PPIS imaging is a feasible modality for monitoring tumor responses. These results suggest that PPIS, a potential high-throughput screening imaging system, may be used for the preclinical evaluation of tumor response to new anticancer drugs using murine tumor models.

Development of double-stranded siRNA labeling method using positron emitter and its in vivo trafficking analyzed by positron emission tomography

Pharmacokinetic study of small interfering RNA (siRNA) is an important issue for the development of siRNAs for use as a medicine. For this purpose, a novel and favorable positron emitter-labeled siRNA was prepared by amino group-modification using N-succinimidyl 4-[fluorine-18] fluorobenzoate ([(18)F]SFB), and real-time analysis of siRNA trafficking was performed by using positron emission tomography (PET). Naked [(18)F]-labeled siRNA or cationic liposome/[(18)F]-labeled siRNA complexes were administered to mice, and differential biodistribution of the label was imaged by PET. The former was cleared quite rapidly from the bloodstream and excreted from the kidneys; but in contrast, the latter tended to accumulate in the lungs. We also confirmed the biodistribution of fluorescence-labeled naked siRNA and cationic liposome/siRNA complexes by use of a near-infrared fluorescence imaging system. As a result, a similar biodistribution was observed, although quantitative data were obtained only by planar positron imaging system (PPIS) analysis but not by fluorescence in vivo imaging. Our results indicate that PET imaging of siRNA provides important information for the development of siRNA medicines.