Method to reduce radiation dose in multidetector CT while maintaining image quality

What is claimed is: 1. A method of reducing radiation dose for a selected organ on a patient in a computed tomography (CT) scan that uses an X-ray source that rotates around the patient as the patient is lying down on a patient bed being translated along a longitudinal axis through an X-ray gantry to scan the patient, the method comprising: providing a computer associated with the CT scan; determining a tube start angle relative to a direction of the patient lying down on the patient bed for the X-ray source of the CT scan, via the computer, based on a location of the selected organ along the longitudinal axis, a starting location of the X-ray source along the longitudinal axis, a beam width of the CT scan, and a pitch of the CT scan, wherein the tube start angle is defined by (i) a line between the X-ray source and the longitudinal axis and (ii) a reference line, and the line and the reference line lie in a plane perpendicular to the longitudinal axis; and setting the position of the X-ray source on the CT scan according to the determined tube start angle prior to performing the scan. 2. The method of claim 1 , wherein determining the tube start angle comprises the step of determining a number of tube rotations based on the location of the selected organ, the starting location of the X-ray source, the beam width of the CT scan, and the pitch of the CT scan, wherein the number of tube rotations is the number of tube rotations from the starting location of the X-ray source to the location of the selected organ. 3. The method of claim 2 , wherein the number of tube rotations is determined using the equation R=(OLoc−SLoc)/(pitch×N), wherein: R is the number of tube rotations from the starting location of the X-ray source to the location of the selected organ; OLoc is the location of the selected organ centroid along the longitudinal axis; SLoc is the starting location of the X-ray source along the longitudinal axis; pitch is the pitch of the CT scan; and N is the beam width of the CT scan. 4. The method of claim 1 , wherein the tube start angle is determined using a number of tube rotations, wherein the number of tube rotations is the number of tube rotations from the starting location of the X-ray source to the location of the selected organ. 5. The method of claim 4 , wherein the tube start angle is determined using the equation TSA=OCTA−(360×(R−floor(R))), wherein: TSA is the tube start angle; OCTA is the angle of the X-ray source of the CT scan as it crosses the longitudinal center of the selected organ along the longitudinal axis; R is the number of tube rotations from the starting location of the X-ray source to the location of the selected organ; and floor(R) is the integer part of R. 6. The method of claim 5 , further comprising determining the number of tube rotations R based on the location of the selected organ, the starting location of the X-ray source, the beam width of the CT scan, and the pitch of the CT scan. 7. The method of claim 6 , wherein the number of tube rotations R is determined using the equation R=(OLoc−SLoc)/(pitch×N), wherein: OLoc is the location of the selected organ centroid along the longitudinal axis; SLoc is the starting location of the X-ray source along the longitudinal axis; pitch is the pitch of the CT scan; and N is the beam width of the CT scan. 8. The method of claim 1 , wherein the location of the selected organ, the starting location of the X-ray source, the beam width of the CT scan, and the pitch of the CT scan are input into the computer using a graphical interface. 9. The method of claim 1 , wherein the location of the selected organ is determined using a planning radiograph of the patient. 10. A system for reducing radiation dose for a selected organ on a patient, comprising: a computed tomography (CT) scan using an X-ray source that rotates around the patient as the patient is lying down on a patient bed being translated along a longitudinal axis through an X-ray gantry to scan the patient; and a computer configured to: determine a tube start angle relative to an orientation of the patient bed for the X-ray source of the CT scan based on a location of the selected organ along the longitudinal axis, a starting location of the X-ray source along the longitudinal axis, a beam width of the CT scan, and a pitch of the CT scan, wherein the tube start angle is defined by (i) a line between the X-ray source and the longitudinal axis and (ii) a reference line, and the line and the reference line lie in a plane perpendicular to the longitudinal axis; and set the position of the X-ray source on the CT scan is set based on according to the determined tube start angle prior to performing the scan. 11. The system of claim 10 , wherein the computer is configured to determine the tube start angle by determining a number of tube rotations based on the location of the selected organ, the starting location of the X-ray source, the beam width of the CT scan, and the pitch of the CT scan, wherein the number of tube rotations is the number of tube rotations from the starting location of the X-ray source to the location of the selected organ. 12. The system of claim 11 , wherein the computer is configured to determine the number of tube rotations using the equation R=(OLoc−SLoc)/(pitch×N), wherein: R is the number of tube rotations from the starting location of the X-ray source to the location of the selected organ; OLoc is the location of the selected organ centroid along the longitudinal axis; SLoc is the starting location of the X-ray source along the longitudinal axis; pitch is the pitch of the CT scan; and N is the beam width of the CT scan. 13. The system of claim 10 , wherein the computer is configured to determine the tube start angle using a number of tube rotations, wherein the number of tube rotations is the number of tube rotations from the starting location of the X-ray source to the location of the selected organ. 14. The system of claim 13 , wherein the computer is configured to determine the tube start angle using the equation TSA=OCTA−(360×(R−floor(R))), wherein: TSA is the tube start angle; OCTA is the angle of the X-ray source of the CT scan as it crosses the longitudinal center of the selected organ along the longitudinal axis; R is the number of tube rotations from the starting location of the X-ray source to the location of the selected organ; and floor(R) is the integer part of R. 15. The system of claim 14 , wherein the computer is configured to determine the number of tube rotations R based on the location of the selected organ, the starting location of the X-ray source, the beam width of the CT scan, and the pitch of the CT scan. 16. The system of claim 15 , wherein the computer is configured to determine the number of tube rotations R using the equation R=(OLoc−SLoc)/(pitch×N), wherein: OLoc is the location of the selected organ centroid along the longitudinal axis; SLoc is the starting location of the X-ray source along the longitudinal axis; pitch is the pitch of the CT scan; and N is the beam width of the CT scan. 17. The system of claim 10 , wherein the CT scan is communicatively coupled to the computer. 18. The system of claim 10 , wherein the computer is configured to provide a graphical interface that enables a user to input the location of the selected organ, the starting location of the X-ray source, the beam width of the CT scan, and the pitch of the CT scan. 19. A program storage device readable by a machine, tangibly embodying a p