Abstract
PET imaging is a widely applicable but a very expensive technology. On-site synthesis is one important contributor to the high cost. In this report, we demonstrated the feasibility of a synthesis-free method for PET imaging of brown adipose tissue (BAT) and translocator protein 18 kDa (TSPO) via a combination of disulfiram, an FDA approved drug for alcoholism, and 64CuCl2 (termed 64Cu-Dis). In this method, a step-wise injection protocol of 64CuCl2 and disulfiram was used to accomplish the purpose of synthesis-free. Specifically, disulfiram, an inactive 64Cu ligand, was first injected to allow it to metabolize into diethyldithiocarbamate (DDC), a strong 64Cu ligand, which can chelate 64CuCl2 from the following injection to form the actual PET tracer in situ. Our blocking studies, western blot, and tissue histological imaging suggested that the observed BAT contrast was due to 64Cu-Dis binding to TSPO, which was further confirmed as a specific biomarker for BAT imaging using [18F]-F-DPA, a TSPO-specific PET tracer. Our studies, for the first time, demonstrated that TSPO could serve as a potential imaging biomarker for BAT. We believe that our strategy could be extended to other targets while significantly reducing the cost of PET imaging.
Highlights
We demonstrated the feasibility of a synthesis-free Positron emission tomography (PET) imaging method for brown adipose tissue (BAT)
In our previous report[3], we have demonstrated that a top-down screening approach could be used for seeking near infrared fluorescence (NIRF) imaging probes for BAT
We screened 38 NIRF dyes resulting in two hits that we further optimized for high BAT selectivity[3]
Summary
We demonstrated the feasibility of a synthesis-free PET imaging method for brown adipose tissue (BAT) With this method, the cost of PET imaging could be dramatically reduced, allowing for a widespread application of this technology. In spite of the fact that investigations of BAT have been ongoing for 70 years, it had been assumed that BAT disappears from the body of adults and has no significant physiological relevance in adult humans[9, 12,13,14] This “non-existence” assumption is partially due to the lack of proper imaging methods to “see” the small BAT depots in vivo, as only 3%-8% of BAT depots in adults could be clearly visualized with [18F]-FDG (the most used imaging method) if no cold or drug stimulation is applied[6, 15,16,17]. An imaging probe that can consistently report on BAT mass is highly desirable
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