Examples and different variations of these methods are presented in the literature [7] and [8]. These models create continuous contours, which may get trapped by false edges. Statistical shape models [9] and [10] or active shape models incorporate statistically extracted variations in the shape. Their deformation toward the boundary of an object is constrained by the characteristics of the object Lumacaftor clinical trial they
represent. The anatomy of the prostate suggests fitting ellipses, ellipsoids, superellipses, and similar geometries. In deformable superellipses (11), ellipses with additional squareness, tapering, and bending parameters are used. Their automatic segmentation results on 125 prostate ultrasound images showed a mean error of less than 2 mm between computer-generated and manual contours. this website However, their method generated 2D segmentation of the prostate, which may suffer
from the inability to segment low quality images, especially at the base and apex. By comparison, a 3D segmentation algorithm can produce contours even for the poor images at the prostate’s superior (anterior base) and inferior (apical) zones by using the higher quality midgland images. Furthermore, in 3D segmentation, axial continuity is easily maintained. This is achieved during manual segmentation by visually comparing contours of various image depths. The 3D segmentation method provided in the literature (12) requires 90 s to create the prostate surface model and generate the solid models necessary for high-intensity focused ultrasound therapy planning. Manual tracing of approximately five transverse
and three sagittal images of the prostate is needed to initialize this algorithm. This adds to the total segmentation duration and introduces an observer variability that has not been quantified. Other 3D methods have been proposed in the literature [9], [10] and [13]. These methods either require extensive user interaction (e.g., manual delineation of several images for initialization of the algorithm) or require a long processing time or modifications to the conventional imaging system. Moreover, rarely has the intra- and interobserver Bay 11-7085 variability of the resulting contours been evaluated and compared with that of manual contouring [12] and [13]. The ellipsoid fitting method in the report by Badiei et al. (14) is fast and produces symmetric and smooth 3D volumes. This method assumes an ellipsoidal shape of the prostate anatomy, whereas tapering is usually observed in both the transverse plane and along the main axis of the prostate. We have gradually resolved this problem in our earlier work [15] and [16] to produce a 3D semiautomatic segmentation method.