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CT Scanner

CT Scanner. Presented by: Dr M A Oghabian Medical Physics Department, Tehran University of Medical Sciences. Computed Tomography. CT uses a rotating x-ray tube, with the beam in the form of a thin slice (about 1 - 10 mm)

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CT Scanner

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  1. CT Scanner Presented by: Dr M A Oghabian Medical Physics Department, Tehran University of Medical Sciences

  2. Computed Tomography • CT uses a rotating x-ray tube, with the beam in the form of a thin slice (about 1 - 10 mm) • The “image” is a simple array of x-ray intensity (Projections), and many hundreds of these are used to make the CT image, which is a “slice” through the patient

  3. First generation CT Scanner(Rotate/Translate Pencil beam) • 180 translational movement • 180 Rotary movement • 160 parallel rays across a 24 cm FOV • Each 2 slices=4.5 min. • Processing time=1.5min.

  4. Second generation CT scannersRotate/Translate Narrow fan beam~10 degree • Narrow fan beam~10 degree • Linear array of 30 detectors • 6 linear movement • 6 rotary movement • Scan time~ 18 Sec.

  5. Third generation CT Scanners(Rotate/Rotate , Wide fan beam) • Wide fan beam • More than 800 detectors • No translational motion • Scan time ~ 0.5 Sec.

  6. 4th Generation CT ScannersRotate/Stationary • Fan beam geometry • More than 4800 detectors

  7. Electron Beam Computed Tomography (EBCT) - x-ray source is not x-ray tube but a focused, steered, microwave-accelerated EB incident on a tungsten target. - It has no moving parts . - Target covers one-half of the imaging circle; detector array covers the other half. - Images in less than 50ms.

  8. EBCT(CONT’D) • There are 4 targets and 4 detector arrays resulting in 4 contiguous images simultaneously. • The detector array may consists of two separate rings • Each solid -state detector consists of a luminescent crystal and cadmium tungstate coupled with silicon photodiodes. • Heat dissipation is no problem in EBCT. • Developed for fast imaging. • Used for cardiac imaging

  9. A look inside a rotate/rotate CT Detector Array and Collimator X-Ray Tube

  10. Comparison of data acquisition for axial and helical technologies.

  11. Reciprocating rotation (A) versus fast continuous rotation using slip-ring technology (B)

  12. A Look Inside a Slip Ring CT Note: how most of the electronics is placed on the rotating gantry X-Ray Tube Detector Array Slip Ring

  13. (A) Pitch =1 (B) Pitch = 2

  14. Comparison of the accuracy of 3D reconstruction for conventional (A) and spiral/helical (B) CT scanning.

  15. More New CT Features:Multislice Scanning

  16. Multislice CT, where up to 64 variable thickness slices can be collected simultaneously • CT fluoroscopy, where the patient is stationary, but the tube continues to rotate • 3-dimensional CT and CT endoscopy

  17. Clinical Benefits Of Multi-Slice Multi-phase Organ Studies • Liver – Pancreas Arterial, Renal Nephrogram Arterial Phase Scanning • Hypervascular Tumors CT Angiography • Multi-Plane Reconstructions, Contrast Enhancement New CT Applications • CT fluoroscopy • CT Colonography • Cardiac: morphology, function • Advanced Lung Analysis

  18. Detector Configurations X-ray Tube Focal Spot X-ray Beam Collimator a • 4 x 1.25 mm Detector Configuration 16-row Mosaic Detector Flex Connector A Flex Connector B Diode FET Switching Array

  19. Detector Configurations X-ray Tube Focal Spot X-ray Beam Collimator 4 x 2.5 mm Detector Configuration 16-row Mosaic Detector Flex Connector A Flex Connector B Diode FET Switching Array

  20. Detector Configurations X-ray Tube Focal Spot X-ray Beam Collimator 4 x 3.75 mm Detector Configuration 16-row Mosaic Detector Flex Connector A Flex Connector B Diode FET Switching Array

  21. Detector Configurations X-ray Tube Focal Spot X-ray Beam Collimator 4 x 5.0 mm Detector Configuration 16-row Mosaic Detector Flex Connector A Flex Connector B Diode FET Switching Array

  22. Multi slice CT collimation 5mm 2,5mm 1mm 0,5mm

  23. Speed: Single vs. 4 Slice Single Slice 235 mm 5 mm 31 240 255 mm 5 mm 34 300 65 17,720 4 slice Chest Coverage Thickness Time (s) mA Abdomen/Pelvis Coverage Thickness Time (s) mA Scan Time (s) Tube Load (mAs) 235 mm 5 mm 8 240 255 mm 5 mm 9 300 17 4,725

  24. MULTISLICE SPIRAL CT • Introduced at the 1998. • They are based multiple detector. rows ranging between 8, 16, 24, 32 and 64 depending on the manufacturer. • The overall goal is to improve the volume coverage speed performance. • Complete x-ray tube/detector array rotation in less than 1s. • Partial scan images can be obtained in approximately 100ms.

  25. MULTISLICE IMAGING(CONT’D) ADVANTAGES • Improved spatial resolution this advantage improved MPR,3D images. • Reduction of radiation exposure. • Motion artifacts are greatly reduced. • Patient breathhold is much less demanding. • Imaging larger z-axis volume in less time is possible with MI. • Less contrast medium required. • Because of imaging speed, coronary artery is comparable with EBCT. • Improved accuracy in needle placement CT fluoroscopy.

  26. CT Fluoroscopy • Real Time Guidance • Great Image Quality • Low Risk • Faster Procedures

  27. REAL-TIME CT FLUOLOROSCOPY • CT fluoroscopy acquire dynamic images in real time. • Fast continuous imaging, fast image reconstruction & continuous image display. • Patient movement is low during Tube rotation. • Fast image Reconstruction algorithm is required.

  28. CT ANGIOGRAPHY (CTA) • CTA allows maximum visualization of the pulmonary artery and its segmental braches. • CTA requires low kVp and MA, for example 90Kvp/100mA. • CTA employs MIP and MPR to maximum advantage.

  29. 3D Stereo Imaging

  30. Enhanced 3D

  31. CT Endoscopy

  32. CT VIRTUAL REALITY IAMAGING • The use of virtual reality is the creation the inner views of tubular structures. • Offers both endoluminal and extra luminal information. • It reduces complication (eg. infection and perforation). • Four requirements: • data acquisition • image processing • 3D rendering • image display and analysis.

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