Multiplanar reformatting allows the user to control object reorientation in any desired plane. Axial, sagittal, coronal, oblique and curved reformats can be generated in seconds. The maximum intensity projection algorithm, or MIP image, is generated by depicting the highest pixel value along a ray or projection. Multiple projections are generated and displayed in a cine loop.
3D visualization can be enhanced using 3D Surface and Volume Rendering techniques.
Shaded Surface Display (SSD) relies on a threshold value to eliminate pixels above or below the threshold. The remaining pixels are then given equal values and the computer generates a surface illuminated by an imaginary point source. SSD provides depth information and is quite useful in the depiction of overlapping and tortuous vessels. Additionally, it is useful to demonstrate relationships of vessels relative to other anatomy. SSD does not, however, retain attenuation information and calcified plaque cannot be differentiated from intraluminal contrast. Occlusions can be artificially rendered in areas of stenosis where partial volume averaging results in pixels being below the threshold.
Volume Rendering, unlike Shaded Surface Display which reduces the original data to a surface model, incorporates all the data contained in the volume into the displayed image. Each pixel is assigned a transparency factor and an opacity factor based on its density value. This enables visualization of anatomic details "above and beneath the surface." The major drawback to Volume Rendering relates to the large computational requirements of this technique.
