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A method for fabricating a scintillator array for a radiation detector of an imaging system includes fabricating a scintillator array including a plurality of scintillators arranged side by side, each of the scintillators separated from adjacent scintillators such that a gap is defined therebetween,

A method for fabricating a scintillator array for a radiation detector of an imaging system includes fabricating a scintillator array including a plurality of scintillators arranged side by side, each of the scintillators separated from adjacent scintillators such that a gap is defined therebetween, each of the scintillators having a geometric shape defined by a plurality of external surfaces, fabricating a pre-formed reflector having a plurality of cavities defined therein, each cavity having a geometric shape substantially similar to each scintillator geometric shape, and coupling the scintillator array and the pre-formed detector such that each respective scintillator is positioned at least partially within at least one respective reflector cavity.

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What is claimed is: 1. A method for fabricating a scintillator array for a radiation detector of an imaging system, said method comprising: fabricating a scintillator array including a plurality of scintillators arranged side by side, each of the scintillators separated from adjacent scintillators

What is claimed is: 1. A method for fabricating a scintillator array for a radiation detector of an imaging system, said method comprising: fabricating a scintillator array including a plurality of scintillators arranged side by side, each of the scintillators separated from adjacent scintillators such that a gap is defined therebetween, each of the scintillators having a geometric shape defined by a plurality of external surfaces; fabricating a pre-formed molded reflector having a plurality of cavities defined therein, each cavity having a geometric shape substantially similar to each scintillator geometric shape the pre-formed reflector fabricated from at least one of a thermo set material and a thermo plastic material, the thermo set and thermo plastic material each including at least one of a titanium dioxide, a tungsten oxide material, a tantalum oxide material, a molybdenum oxide material, and a lead oxide material; and coupling the scintillator array and the pre-formed reflector such that each respective scintillator is positioned at least partially within at least one respective reflector cavity. 2. A method in accordance with claim 1 further comprising fabricating a pre-formed reflector from at least one of a thermo set material and a thermo plastic material, wherein the thermo set material and a thermo plastic material include at least one of a titanium dioxide and a chrome oxide. 3. A method in accordance with claim 1 further comprising coupling the scintillator array and the pre-formed reflector using an adhesive material. 4. A method in accordance with claim 1 further comprising fabricating a pre-formed reflector including a titanium dioxide and a plurality of interstitial plates formed integrally with the pre-formed reflector, the interstitial plates including at least one of a tungsten material, a tantalum material, a molybdenum material, and a lead material. 5. A method in accordance with claim 1 further comprising fabricating a pre-formed reflector including a plurality of collimators formed integrally with the pre-formed reflector. 6. A method in accordance with claim 1 further comprising fabricating a pre-formed reflector including a plurality of collimators and a plurality of interstitial plates formed integrally with the pre-formed reflector. 7. A radiation detector comprising: a scintillator array comprising a plurality of scintillators arranged side by side, each of said scintillators separated from adjacent scintillators such that a gap is defined therebetween, each of said scintillators having a geometric shape defined by a plurality of external surfaces; and a pre-formed molded reflector fabricated from at least one of a thermo set material and a thermo plastic material, the thermo set and thermo plastic material each including at least one of a titanium dioxide, a tungsten oxide material, a tantalum oxide material, a molybdenum oxide material, and a lead oxide material, said reflector comprising a plurality of cavities defined therein, each said cavity having a geometric shape substantially similar to each said scintillator geometric shape, said scintillator array coupled to said pre-formed reflector such that each said respective scintillator is positioned at least partially within at least one respective reflector cavity. 8. A radiation detector in accordance with claim 7 wherein said pre-formed reflector comprises at least one of a thermo set material and a thermo plastic material, said thermo set material and said thermo plastic material comprising at least one of a titanium dioxide and a chrome oxide. 9. A radiation detector in accordance with claim 7 further comprising an adhesive material positioned between said scintillator array and said pre-formed reflector, said adhesive configured to couple said scintillator array and said pre-formed reflector. 10. A radiation detector in accordance with claim 8 wherein said pre-formed reflector further comprises a titanium dioxide and a plurality of interstitial plates formed integrally with said pre-formed reflector, said interstitial plates comprising at least one of a tungsten material, a tantalum material, a molybdenum material, and a lead material. 11. A radiation detector in accordance with claim 8 wherein said pre-formed reflector further comprises a plurality of collimators formed integrally with said pre-formed reflector. 12. A radiation detector in accordance with claim 8 wherein said pre-formed reflector further comprises a plurality of collimators and a plurality of interstitial plates formed integrally with said pre-formed reflector. 13. A computed tomography (CT) imaging system comprising: a radiation source; a radiation detector comprising: a scintillator array comprising a plurality of scintillators arranged side by side, each of said scintillators separated from adjacent scintillators such that a gap is defined therebetween, each of said scintillators having a geometric shape defined by a plurality of external surfaces; and a pre-formed molded reflector fabricated from at least one of a thermo set material and a thermo plastic material, the thermo set and thermo plastic material each including at least one of a titanium dioxide, a tungsten oxide material, a tantalum oxide material, a molybdenum oxide material, and a lead oxide material, said reflector comprising a plurality of cavities defined therein, each said cavity having a geometric shape substantially similar to each said scintillator geometric shape, said scintillator array coupled to said pre-formed reflector such that each said respective scintillator is positioned at least partially within at least one respective reflector cavity; and a computer operationally coupled to said radiation source and said radiation detector. 14. A CT imaging system in accordance with claim 13 wherein said pre-formed reflector comprises at least one of a thermo set material and a thermo plastic material, said thermo set material and said thermo plastic material comprising at least one of a titanium dioxide and a chrome oxide. 15. A CT imaging system in accordance with claim 13 wherein said pre-formed reflector further comprises a titanium dioxide and a plurality of interstitial plates formed integrally with said pre-formed reflector, said interstitial plates comprising at least one of a tungsten material, a tantalum material, a molybdenum material, and a lead material. 16. A CT imaging system in accordance with claim 13 wherein said pre-formed reflector further comprises a plurality of collimators formed integrally with said pre-formed reflector. 17. A CT imaging system in accordance with claim 13 wherein said pre-formed reflector further comprises a plurality of collimators and a plurality of interstitial plates formed integrally with said pre-formed reflector.