Light guide array for pet detector fabrication methods and apparatus

The invention claimed is: 1. A method for assembling a photon detector, the photon detector including an optical light guide array located between an optical transparent plate and a photodiode array, the method comprising: depositing a non-wetting film on at least one opposing surfaces of at least one of the optical transparent plate and the photodiode array; altering the deposited non-wetting film in regions of photodiode elements; dispensing an optical coupler adhesive on to at least one of the optical transparent plate and the photodiode array to form optical coupler adhesive beads on the optical transparent plate or the photodiode elements; aligning the opposing surfaces of the optical transparent plate and the photodiode array; assembling the opposing surfaces of the optical transparent plate and the photodiode array so that the optical coupler adhesive beads contact the opposing surface; and curing the optical coupler adhesive beads, the cured optical coupler adhesive beads forming optical light guide elements of the optical light guide array, the optical light guide elements located between the optical transparent plate and individual photodiode elements; the curing of the optical coupler adhesive beads resulting in structurally merging the optical light guide array, the optical transparent plate, and the photodiode array into a structurally merged photon detector. 2. The method of claim 1 , the altering the deposited non-wetting film including at least one of removing and chemically modifying the non-wetting film. 3. The method of claim 1 , the altering the deposited non-wetting film is done at about the center of the photodiode elements. 4. The method of claim 1 , the depositing the non-wetting film including applying the non-wetting film utilizing a mask. 5. The method of claim 1 , wherein a surface tension force of the optical coupler adhesive beads can cause movement in the alignment of the optical transparent plate with respect to the photodiode array, the movement including at least one of translating and rotating either or both of the optical transparent plate and the photodiode array, as determined by the surface tension force. 6. The method of claim 1 , wherein the optical transparent plate is a scintillator. 7. The method of claim 6 , wherein the scintillator has elements, and the dispensing step includes dispensing the optical coupler adhesive to form optical coupler adhesive beads on corresponding scintillator elements and photodiode elements. 8. The method of claim 7 , the aligning the opposing surfaces including positioning corresponding beads of optical coupler adhesive to be opposite each other. 9. The method of claim 1 , wherein the optical transparent plate is a glass plate. 10. The method of claim 1 , including: forming optical coupler adhesive beads on the photodiode elements; and applying optical adhesive to the optical transparent plate to form a film of about uniform thickness. 11. A photon detector comprising: an optical transparent plate; a photodiode array having individual elements; an optical light guide array between the optical transparent plate and the photodiode array, the optical light guide array including individual optical light guide elements providing a transmission line between the optical transparent plate and individual elements of the photodiode array; the optical light guide array prepared by a process comprising the steps of: depositing a non-wetting film on at least one opposing surfaces of at least one of the optical transparent plate and the photodiode array; altering the deposited non-wetting film in regions of photodiode elements; dispensing an optical coupler adhesive on to at least one of the optical transparent plate and the photodiode array to form optical coupler adhesive beads on the optical transparent plate or the photodiode elements; aligning the opposing surfaces of the optical transparent plate and the photodiode array; assembling the opposing surfaces of the optical transparent plate and the photodiode array so that the optical coupler adhesive beads contact the opposing surface; and curing the optical coupler adhesive beads, the cured optical coupler adhesive beads forming optical light guide elements of the optical light guide array, the optical light guide elements located between the optical transparent plate and individual photodiode elements; the curing of the optical coupler adhesive beads resulting in structurally merging the optical light guide array, the optical transparent plate, and the photodiode array into a structurally merged photon detector. 12. The photon detector of claim 11 , including a distortion in position of one or more individual optical light guide elements, the position distortion of respective ones of the one or more individual optical light guide elements resulting from a respective miss-registration in a position of a respective photodiode individual element. 13. The photon detector of claim 11 , wherein the optical transparent plate is a scintillator. 14. The photon detector of claim 13 , the scintillator having individual elements, and optical coupler adhesive beads are positioned between corresponding scintillator elements and corresponding photodiode elements to form individual optical light guide elements. 15. The photon detector of claim 14 , including: the individual elements of the scintillator array being crystals configured to emit photons when excited by incident x-ray radiation; and the individual elements of the photodiode array being single photon avalanche diode pixels. 16. The photon detector of claim 11 , wherein the optical transparent plate is a glass plate.