1. CT Multi-Slice CT
2. Third Generation CT�Single or Multislice
3. Single Slice Thickness Determined by Collimation
4. Single-Slice Detectors Many detectors rotate around patient
Single row in z-direction
Slice thickness determined by collimation
5. Single Slice CT: Slice Thickness
6. Multi-slice CT
7. What’s Different for Multislice CT?
8. Multislice CT Multiple rows of detectors
Open collimators in “Z” direction
9. Multi-slice CT Developed in late 1990’s
Detector array segmented in z-direction
Simultaneous acquisition of multiple slices
10. Single Slice vs. Multislice Detector
11. Multi-Slice Detectors Many detectors going around patient
Many detector rows in z-direction
Slice thickness determined by
Collimation
electronic detector selection
12. Multi-slice CT Size & distribution of detectors in non-axial direction similar to previous CT’s
Similar spatial & contrast resolution
13. Distribution of detectors in axial direction varies with manufacturer All detectors same width
14. Multi-slice CT�Uniform Detector Thickness Multiple detectors in axial direction
Size must accommodate thinnest slice
Detector signals can be used
Individually
In groups
15. Detectors vs. Channels # Physical Detectors not necessarily equal to # of possible Slices
Maximum # slices limited by Digital Acquisition System (DAS) channels
Electronic counters
Imaging speed bottleneck
How fast data can be received from�detector arrays
16. Detectors vs. Channels Example 16 detectors
4 channels
17. Multi-Slice Detector Example�16 Detector Rows, 4 Channels
18. Detectors vs. Channels�4 X 1.25 mm Beam collimated to 4 detector rows
1 detector row per DAS channel
19. Detectors vs. Channels�4 X 2.5 mm Beam collimated to 8 detector rows
2 detector rows per DAS channel
20. Detectors vs. Channels�4 X 3.75 mm Beam collimated to 12 detector rows
3 detector rows per DAS channel
21. Detectors vs. Channels�4 X 5 mm Beam collimated to 16 detector rows
4 detector rows per DAS channel
22. Capture Efficiency Fraction of detector area that is active detector
23. Equal-width Detectors Disadvantage Many gaps
Gaps are dead space
Reduce capture efficiency
24. Multi-slice CT�“Adaptive Array Detectors” Some scanners use detectors of various widths
Post-collimators used to partially block wider elements for thinner slices
25. Variable Width Detectors Center detectors thinner
Thicker detectors can function as thinner ones using collimation
Thinner detectors can function a thicker one by combining signals
26. Single Slice Pitch Definition table motion during one rotation �Slice Pitch = --------------------------------------- slice thickness
27. Beam Pitch�Defined only for Multi-slice scanners table motion during one rotation �Beam Pitch = --------------------------------------- Beam thickness
28. Beam Pitch�Defined only for Multi-slice scanners
29. CT Beam Pitch
30. Example
31. Beam Thickness
32. Table Speed
33. Slice Thickness Defined at Rotational Center
34. Detector Field must be Larger than Slice Thickness at Rotational Center
35. Beam Divergence More of a Problem for Multi-Slice
36. Multislice CT Doses Can be 10-30% higher than for single slice units (ICRP #47)
Cause
Divergent beam
Other considerations
Tendency to cover more volume (anatomy)
Better availability of equipment
37. Other Reasons for High CT Doses Repeat Exams
No adjustment of technique factors for different size patients
No adjustment for different areas of body
38. Multislice CT Advantage? Speed!
39. Single slice / Multislice Images about the same!
40. Speed = Power Speed enables new applications
41. How do we spend our new speed?
42. Multi-slice CT Imaging�Clinical Advantages Same acquisition in shorter time
Trauma
Peds
OR
Thinner slices for improved z-direction resolution�OR
Scan larger volumes in same time
43. Multi-slice CT Imaging�Clinical Advantages Thinner slices
Improvement in CTA of neck, aorta, renal vessels
Better reconstructions
Sagittal, coronal, oblique
3-D
Fundamental Trade-off
“z” axis resolution vs. image noise
44. Multi-slice CT Imaging�Clinical Advantages Better Contrast Utilization
Simplifies timing of contrast bolus
Continuous observation of target vessel
Can reduce amount of contrast required
Possible coverage from aorta to lower extremities
Runoff
45. Multi-slice CT Imaging�Clinical Advantages Improved x-ray tube utilization
Reduced x-ray tube loading
4 slices acquired with same tube loading previously used for 1
Less need to pause of tube cooling
Reduced wear & tear
Other anticipated benefits
CT endoscopy
Diagnosis of pulmonary embolism
46. Continuous CT Imaging�Interventional Procedures Biopsy & drainage
Neuro
Chest
Abdominal
Spine
Catheter and tube placement
Helps operator avoid critical structures near path of biopsy needle
Better visualizing of moving structures
Respiration
Functional CT
Brain perfusion
47. Multi-Slice Compared to �Single-slice helical
Much Faster
No significant image quality differences
Equivalent Patient Dose
Ref:
Willi Kalender, Ph.D�Institute of Medical Physics�University of Erlanger, Germany
48. Multi-slice challenges Much more raw data
More archival capacity
More thin slices possible
May make multi-image printing cumbersome
May require viewing on-line
Requires faster systems
Requires faster communications for remote viewing
Radiologist legally responsible for all images
49. Acknowledgement Many drawings obtained from www.impact.org website
50. The Future More detector channels
More speed
Flat panel area detectors
???
