A prototype modular detector design for high resolution positron emission mammography imaging

Current challenges facing us in developing dedicated position emission tomography (PET) system for metabolic breast mammography (PEM) and small animal (ANIPET) are to achieve high spatial resolution (less than 2 mm) and high efficiency. It is also crucial to extend the sensitive areas of PEM detectors to their periphery in order to overcome the difficulty in imaging near a patientʹs chest wall. This limitation of the periphery dead region was revealed in the clinical trials of our previously developed PEM-I system. In the new study, we developed prototype detectors by using position-sensitive photomultiplier tubes (PS-PMTs) and pixelated bismuth germanate (BGO) crystals with depth encoding scheme to detect and localize gamma rays. The procedures in crystal processing include cutting, polishing, encapsulating, separating, and re-gluing. We also developed front-end electronic circuits including high-voltage dividers, anode resistor chains, position readout circuits, and last dynode timing circuits. Methods for combining four PS-PMTs with simple X+, X-, Y+, Y- outputs have been developed to further simplify the position recording. The detectors were constructed in the structure of array (two in the system)-module (four in each array)-unit (four in each module). The basic unit of one crystal and one PS-PMT can be field replaceable. Our new prototype detectors show that the proposed PEM-II system has a spatial resolution of 1.8 mm (versus 2.8 mm in PEMI), a timing resolution of 10.3 ns (versus 12 ns in PEM-I), and a field-of-view of 88 mm * 88 mm (versus 64 mm * 56 mm in PEM-I). Compared with our previous PEM-I system, it demonstrates that the design improves the spatial resolution, enhances the detector field-of-view, and significantly reduces the peripheral dead regions.