Adjustable detector array for a nuclear medicine imaging system

The invention claimed is: 1. A detector array, comprising: a plurality of adjustable imaging detectors, each of the plurality of adjustable imaging detectors comprising one of a first detector unit and a second detector unit, each first detector unit having a plurality of rows of detector modules and each second detector unit having at least one row of detector modules, where each second detector unit has fewer rows of detector modules than each first detector unit; wherein the plurality of adjustable imaging detectors are arranged on an annular gantry, the annular gantry configured for rotation about a first axis of a cylindrical aperture of the annular gantry, the first axis extending a length of the cylindrical aperture, and wherein each of the plurality of adjustable imaging detectors is disposed within the cylindrical aperture and extends orthogonally toward the first axis. 2. The detector array of claim 1 , wherein the plurality of adjustable imaging detectors are affixed to an inner surface of the annular gantry. 3. The detector array of claim 1 , wherein the annular gantry comprises a track circumscribed by an inner surface of the annular gantry, and the plurality of adjustable imaging detectors are positioned partially within the track such that each of the plurality of adjustable imaging detectors is operable to move independently along the track with respect to each other adjustable imaging detector. 4. The detector array of claim 1 , wherein each of the plurality of adjustable imaging detectors comprises a telescoping detector carrier, where one of each first detector unit and each second detector unit is respectively positioned at an end of each telescoping detector carrier nearest the first axis and each telescoping detector carrier is configured to extend toward or retract from the first axis. 5. The detector array of claim 1 , wherein the first axis is located at a center of the cylindrical aperture, and the annular gantry is configured for full rotation about the first axis. 6. The detector array of claim 1 , wherein each first detector unit is configured to pivot about a second axis up to 60° from a default configuration, where each second axis is respectively located at a center of each first detector unit and each second axis is parallel with the first axis, and each second detector unit is configured to pivot about a third axis up to 90° from a default configuration, where each third axis is respectively located at a center of each second detector unit and each third axis is parallel with the first axis and each second axis. 7. The detector array of claim 1 , wherein each detector module is a cadmium zinc telluride module. 8. The detector array of claim 1 , wherein each first detector unit comprises three rows of detector modules, each of the three rows of detector modules comprising seven detector modules, and each second detector unit comprises only one row of detector modules, the only one row of detector modules comprising seven detector modules. 9. The detector array of claim 1 , wherein the plurality of adjustable imaging detectors comprise six first detector units alternatingly arranged with six second detector units. 10. The detector array of claim 1 , wherein each of the plurality of adjustable imaging detectors having the first detector unit has a same configuration as each other adjustable imaging detector having the first detector unit, and each of the plurality of adjustable imaging detectors having the second detector unit has a same configuration as each other adjustable imaging detector having the second detector unit. 11. The detector array of claim 1 , wherein each first detector unit comprises a pair of proximity detectors disposed opposite to one another, a first one of the pair of proximity detectors comprises a first optical sensor configured to project a light-emitting diode (LED) beam, a second one of the pair of proximity detectors comprises a second optical sensor configured to receive the LED beam, and upon interruption of the LED beam by an interfering object, the first detector unit is configured to retract and/or pivot away from the interfering object. 12. The detector array of claim 11 , wherein each of the pair of proximity detectors comprises a sliding-end contact sensor, and upon application of a threshold pressure to any sliding-end contact sensor by the interfering object, the LED beam is interrupted. 13. The detector array of claim 1 , wherein each first detector unit and second detector unit comprises an exchangeable collimator, the exchangeable collimator selected for a particular imaging application. 14. A medical imaging system, comprising: an annular gantry circumscribing a cylindrical aperture, the annular gantry configured to rotate about a central axis tracing a length of the cylindrical aperture; a detector array positioned on the annular gantry, the detector array comprising a plurality of larger detector units and a plurality of smaller detector units extending toward the central axis of the cylindrical aperture, each of the plurality of larger detector units comprising a plurality of rows of cadmium zinc telluride (CZT) modules and each of the plurality of smaller detector units comprising at least one row of CZT modules, where each smaller detector unit has fewer rows of CZT modules than each larger detector unit, and each of the CZT modules is registered with an exchangeable collimator for receiving incoming radiation from a subject positioned within the cylindrical aperture; and a processing unit configured with instructions in non-transitory memory that when executed cause the processing unit to: responsive to a size of the subject being larger than a threshold size: coordinate each of the plurality of larger detector units and the plurality of smaller detector units to move to a first position to receive the incoming radiation from the subject, and acquire medical imaging data from each of the plurality of larger detector units and the plurality of smaller detector units based on the incoming radiation; and responsive to the size of the subject being smaller than the threshold size: coordinate the plurality of smaller detector units to move to a second position to receive the incoming radiation from the subject, and acquire medical imaging data from the plurality of smaller detector units based on the incoming radiation. 15. The medical imaging system of claim 14 , wherein the processing unit is further configured to perform an automatic body contouring routine to estimate an outer perimeter of the subject, coordinating the plurality of larger detector units comprises translating and pivoting the plurality of larger detector units toward the estimated outer perimeter, and coordinating the plurality of smaller detector units comprises translating and pivoting the plurality of smaller detector units toward the estimated outer perimeter. 16. The medical imaging system of claim 14 , wherein each of the plurality of smaller detector units comprises only one row of CZT modules, and each of the plurality of larger detector units comprises a plurality of proximity detectors configured to, upon detecting the subject within a threshold distance of a corresponding larger detector unit, retract and/or pivot the corresponding larger detector unit away from the subject. 17. The medical imaging system of claim 14 , wherein the processing unit is further configured to: determine an angular resolution of the imaging data; responsive to an insufficient angular resoluti