Another Wavelength: Kelsea Cronin

There are many challenges in SPECT (Single photon emission computed tomography) imaging because of the fundamental tradeoffs inherent in the detector physics. By combining multiple detector types some of these limitations can be mitigated. I started my work by modeling a system with multiple detectors with different SPECT configurations to compare it to systems with one of these SPECT technologies. This simulation provides a quantitative way to evaluate each detectors advantages and weaknesses as standalone systems and as an integrated system. From this work I have determined an optimized imager for high energy and spatial resolution without sacrificing sensitivity or field of view. This design involves integrating two different SPECT detector types: the quantum imaging detector (iQID) and a CdTe crossed-strip semiconductor detector. The iQID scintillation detector can achieve excellent spatial resolution while also delivering high sensitivity, but with limited energy resolution. This compliments the semiconductor detector's ability to achieve excellent energy and spatial resolution, but at limited count rates and with a smaller detector area. My current work is designing and constructing the combined imaging device into a rotating gantry imager. The end design will be used to image rodents over a range of high energies.